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EX-31.1 - CERTIFICATION - Lightwave Logic, Inc.lwlg_ex31z1.htm
EX-31.2 - CERTIFICATION - Lightwave Logic, Inc.lwlg_ex31z2.htm
EX-32.1 - CERTIFICATION PURSUANT TO SECTION 906 OF THE SARBANES-OXLEY ACT OF 2002 18 U.S.C. SECTION 1350 - Lightwave Logic, Inc.lwlg_ex32z1.htm
EX-32.2 - CERTIFICATION PURSUANT TO SECTION 906 OF THE SARBANES-OXLEY ACT OF 2002 18 U.S.C. SECTION 1350 - Lightwave Logic, Inc.lwlg_ex32z2.htm

 



 

 

UNITED STATES

SECURITIES AND EXCHANGE COMMISSION

Washington, D.C.  20549


FORM 10-K


þ

ANNUAL REPORT PURSUANT TO SECTION 13 OR 15(d) OF THE SECURITIES EXCHANGE ACT OF 1934

  

  

For the fiscal year ended December 31, 2015

  

  

¨

TRANSITION REPORT PURSUANT TO SECTION 13 OR 15 (D) OF THE SECURITIES EXCHANGE ACT OF 1934


For the transition period from ________________________to________________________


Commission file number: 0-52567


Lightwave Logic, Inc.

(Exact name of registrant as specified in its charter)


Nevada

  

82-049-7368

(State or other jurisdiction of

incorporation or organization)

  

(I.R.S. Employer

Identification No.)


1831 Lefthand Circle, Suite C, Longmont, CO

  

80501

(Address of principal executive offices)

  

(Zip Code)


(Registrant’s Telephone Number, including Area Code): 720-340-4949

 

Securities registered pursuant to Section 12(b) of the Act


Title of each class registered

  

Name of each exchange

on which registered

  

  

  


Securities registered pursuant to section 12(g) of the Act:


Common Stock, Par Value $0.001

(Title of class)


Indicate by check mark if the Registrant is a well-known seasoned issuer, as defined in Rule 405 of the Securities Act.  Yes ¨  No þ


Indicate by check mark if the Registrant is not required to file reports pursuant to Section 13 or 15(d) of the Act.  Yes ¨  No þ


Indicate by check mark whether the registrant (1) has filed all reports required to be filed by Section 13 or 15(d) of the Securities Exchange Act of 1934 during the preceding 12 months (or for such shorter period that the registrant was required to file such reports), and (2) has been subject to such filing requirements for the past 90 days.  Yes þ  No ¨


Indicate by check mark whether the registrant has submitted electronically and posted on its corporate Website, if any, every Interactive Data File required to be submitted and posted pursuant to Rule 405 of Regulation S-T (§232.405 of this chapter) during the preceding 12 months (or for such shorter period that the registrant was required to submit and post such files).  Yes þ  No ¨


Indicate by check mark if disclosure of delinquent filers pursuant to Item 405 of Regulation S-K is not contained herein, and will not be contained, to the best of the registrants knowledge, in definitive proxy or information statements incorporated by reference in Part III of this Form 10-K or any amendment to this Form 10-K.  ¨

 

 





 


Indicate by check mark whether the registrant is a large accelerated filer, an accelerated filer, a non-accelerated filer or a smaller reporting company. See definitions of “large accelerated filer,” “accelerated filer” and “smaller reporting company” in Rule 12b-2 of the Exchange Act. (Check one):


Large Accelerated Filer

¨

Accelerated Filer

¨

Non-Accelerated filer

¨

Smaller reporting company

þ


Indicate by check mark whether the registrant is a shell company (as defined in Rule 12b-2 of the Exchange Act of 1934).  Yes ¨  No þ


The aggregate market value of the voting and non-voting common equity held by non-affiliates of the registrant was approximately $37,763,197 as of June 30, 2015.


As of March 17, 2016, there were 65,591,629 shares outstanding of the registrant’s common stock, $.001 par value.

 







 


Table of Contents

 

  

  

  

Page

  

  

  

  

PART I

  

  

  

  

Item 1.

Business

1

  

Item 1A.

Risk Factors

19

  

Item 1B.

Unsolved Staff Comments

29

  

Item 2.

Properties

29

  

Item 3.

Legal Proceedings

29

  

Item 4.

Mine Safety Disclosures

29

  

  

  

 

PART II

  

  

 

  

Item 5.

Market for Registrant’s Common Equity, Related Stockholder Matters and Issuer Purchases of Equity Securities

30

  

Item 6.

Selected Financial Data

32

  

Item 7.

Management’s Discussion and Analysis of Financial Condition and Results of Operations

32

  

Item 7A.

Quantitative and Qualitative Disclosures About Market Risk

41

  

Item 8.

Financial Statements and Supplementary Data

41

  

Item 9.

Changes in and Disagreements with Accountants on Accounting and Financial Disclosure

41

  

Item 9A.

Controls and Procedures

41

  

Item 9B.

Other Information

42

  

  

  

 

PART III

  

  

 

  

Item 10.

Directors, Executive Officers and Corporate Governance

43

  

Item 11.

Executive Compensation

46

  

Item 12

Security Ownership of Certain Beneficial Owners and Management and Related Stockholder Matters

51

  

Item 13.

Certain Relationships and Related Transactions, and Director Independence

52

  

Item 14.

Principal Accounting Fees and Services

53

  

  

  

 

PART IV

  

  

 

  

Item 15.

Exhibits, Financial Statement Schedules

54


 

  


i



 


Forward-Looking Statements


This report on Form 10-K contains forward-looking statements. Forward-looking statements involve risks and uncertainties, such as statements about our plans, objectives, expectations, assumptions or future events. In some cases, you can identify forward-looking statements by terminology such as “anticipate,” “estimate,” “plan,” “project,” “continuing,” “ongoing,” “expect,” “we believe,” “we intend,” “may,” “should,” “will,” “could” and similar expressions denoting uncertainty or an action that may, will or is expected to occur in the future. These statements involve estimates, assumptions, known and unknown risks, uncertainties and other factors that could cause actual results to differ materially from any future results, performances or achievements expressed or implied by the forward-looking statements. You should not place undue reliance on these forward-looking statements.


Factors that are known to us that could cause a different result than projected by the forward-looking statement, include, but are not limited to:


  

·

lack of available funding

  

·

general economic and business conditions

  

·

competition from third parties

  

·

intellectual property rights of third parties

  

·

regulatory constraints

  

·

changes in technology and methods of marketing

  

·

delays in completing various engineering and manufacturing programs

  

·

changes in customer order patterns

  

·

changes in product mix

  

·

success in technological advances and delivering technological innovations

  

·

shortages in components

  

·

production delays due to performance quality issues with outsourced components

  

·

those events and factors described by us in Item 1.A Risk Factors

  

·

other risks to which our Company is subject

  

·

other factors beyond the Company's control.


Any forward-looking statement made by us in this report on Form 10-K is based only on information currently available to us and speaks only as of the date on which it is made. We undertake no obligation to publicly update any forward-looking statement, whether written or oral, that may be made from time to time, whether as a result of new information, future developments or otherwise.

 

  




ii





PART I


Item 1.

Business.


Our Business Development

 

We were incorporated under the laws of the State of Nevada on June 24, 1997 and in July 2004 we acquired PSI-TEC Corporation (“PSI-TEC”) as a wholly owned subsidiary. PSI-TEC was founded in 1991 and incorporated under the laws of the State of Delaware on September 12, 1995. Dr. Frederick J. Goetz founded PSI-TEC in Upland, Pennsylvania where he established a laboratory with a small amount of private funding.  PSI-TEC subsequently moved its operations to laboratory space provided by the U.S. Army on the Aberdeen Proving Grounds in cooperation with a division of the Department of Defense for the advancement of ultra wide-bandwidth satellite telecommunications. Thereafter, PSI-TEC commenced operations of its own organic synthesis and thin-films laboratory in Wilmington, Delaware.


On October 2006, in order to consolidate our operations, we merged with PSI-TEC Corp. and changed our name to Third-Order Nanotechnologies, Inc. In March 2008 we changed our name to Lightwave Logic, Inc. to better suit our strategic business plan and to facilitate stockholder recognition of our Company and our business.


Unless the context otherwise requires, all references to the “Company,” “we,” “our” or “us” and other similar terms means Lightwave Logic, Inc., a Nevada corporation.


Our principal executive office is located at 1831 Lefthand Circle, Suite C, Longmont, CO 80501, and our telephone number is (720) 340-4949. Our website address is www.lightwavelogic.com. No information found on our website is part of this report. Also, this report includes the names of various government agencies and the trade names of other companies. Unless specifically stated otherwise, the use or display by us of such other parties' names and trade names in this report is not intended to and does not imply a relationship with, or endorsement or sponsorship of us by, any of these other parties.

 

Overview


We are a development stage, electro-optical device and organic nonlinear materials company. Our primary area of expertise is the chemical synthesis of chromophore dyes used in the development of organic Application Specific Electro-Optic Polymers (ASEOP) and Organic Non-Linear All-Optical Polymers (NLAOP) that have high electro-optic and optical activity. Our family of materials is thermally and photo-chemically stable, which we believe could have utility across a broad range of applications in devices that address markets like, telecommunication, data communications, high-speed computing and photovoltaic cells. Secondarily, the company is developing proprietary electro-optical and all-optical devices utilizing the advanced capabilities of our materials for the application in the fields mentioned above.


Electro-optic devices convert data from electric signals into optical signals for use in communications systems and in optical interconnects for high-speed data transfer. We expect our patented and patent-pending optical materials, when completed and tested, to be the core of the future generations of optical devices, modules, sub-systems and systems that we will develop or be licensed by electro-optic device manufacturers, such as telecommunications component and systems manufacturers, networking and switching suppliers, semiconductor companies, aerospace companies and government agencies.


Our optical polymers (polymers) are property-engineered at the molecular level (nanotechnology level) to meet the exacting thermal, environmental and performance specifications demanded by electro-optic devices. We believe that our patented and patent pending technologies will enable us to design optical polymers that are free from the numerous diverse and inherent flaws that plague competitive polymer technologies employed by other companies and research groups. We engineer our polymers with the intent to have temporal, thermal, chemical and photochemical stability within our patented and patent pending molecular architectures.


Our non-linear all optical polymers have demonstrated resonantly enhanced third-order properties approximately 2,630 times larger than fused silica, which means that they are highly photo-optically active in the absence of an RF layer. In this way they differ from other optical polymers and are considered more advanced next-generation materials.


Our patented and patent pending molecular architectures are based on a well-understood chemical and quantum mechanical occurrence known as aromaticity. Aromaticity provides a high degree of molecular stability. Aromaticity is what will enable our core molecular structures to maintain stability under a broad range of polymerization conditions that otherwise appear to affect other current polymer molecular designs. Polymers, polymer-based devices, hybrid devices and the processes used to create them are often patentable, which can provide the developers of such technology with a significant competitive advantage. We consider our proprietary intellectual property to be unique.




1





Glossary of Select Technology Terms Used Herein


All-optical devices

All-optical devices convert data in the form of input light signals to a secondary light data stream. The future market of all-optical devices and switches is expected to include all-optical switches.


Electro-optic devices

Electro-optic devices convert data from electric signals into optical signals for use in communications systems and in optical interconnects for high-speed data transfer.


Electro-optic material

Electro-optic material is the core active ingredient in high-speed fiber-optic telecommunication systems. Electro-optic materials are materials that are engineered at the molecular level. Molecular level engineering is commonly referred to as “nanotechnology.”


Electro-optic modulators

Electro-optic modulators are electro-optic devices that perform electric-to-optic conversions within the infrastructure of the Internet.  Data centers may also benefit from this technology through devices that could significantly increase bandwidth and speed while decreasing costs.


Photonic Devices

Photonic devices are components for creating, manipulating or detecting light. This can include modulators, laser diodes, light-emitting diodes, solar and photovoltaic cells, displays and optical amplifiers. Other examples are devices for modulating a beam of light and for combining and separating beams of light of different wavelength.


Polymers

Polymers, also known as plastics, are large carbon-based molecules that bond many small molecules together to form a long chain. Polymer materials can be engineered and optimized using nanotechnology to create a system in which unique surface, electrical, chemical and electro-optic characteristics can be controlled. Materials based on polymers are used in a multitude of industrial and consumer products, from automotive parts to home appliances and furniture, as well as scientific and medical equipment.


Our Business


Lightwave Logic, Inc. is developing a new generation of advanced organic nonlinear chromophores to be used to make electro-optic polymer material systems and non-linear all-optical polymer material systems. We are developing a new generation of photonic devices that utilize our unique polymer based material systems. These polymer based material systems, when used in modulators or waveguide structures, can convert high-speed electronic signals into optical (light) signals for use in communications systems, high-speed data transfer or advanced high speed computing. Our Company is developing proprietary all-optical devices utilizing the advanced capabilities of our materials for the application mentioned above. These all-optical devices use light waves to switch other light waves meaning these material systems have third-order properties.


Inorganic material with electro-optic characteristics is the core active ingredient in high-speed fiber-optic telecommunication systems. Utilizing our proprietary technology, we are in the process of engineering advanced organic electro-optic polymer material systems that we believe may lead to significant performance advancements, component size and cost reduction, ease of processing, and thermal and temporal stability. We believe that our electro-optic polymer material systems engineered at the molecular level may have a significant role in the future development of commercially significant electro-optic related products.


Our organic electro-optic polymer material systems work by affecting the optical properties of light in the presence of an electric field at extremely high frequencies (wide bandwidths), but possess inherent advantages to inorganic materials.




2





Currently, the core electro-optic material contained in most modulators is a crystalline material, such as lithium niobate, indium phosphide and gallium arsenide. The following chart describes some of the characteristics of crystalline materials and electro-optical polymers.


Crystalline Materials

Electro-optical Polymers

 

 

Must be manufactured in strict dust-free conditions since even slight contamination can render them inoperable

Capable of being manufactured in less stringent environmental conditions. Capable of being tailored at the molecular level for optimal performance characteristics

More expensive to manufacture

Less expensive to manufacture

Limited to telecommunication speeds that are less than 40Gb/s (40 billion digital bits of data per second)

Demonstrated the ability to perform at speeds that are greater than 100Gb/s (100 billion digital bits of data per second)

Lithium niobate devices require large power levels (modulation voltages) to operate and are large in size -- typically measuring about four inches long (considering that most integrated circuits are literally invisible to the naked eye, these devices are enormous)

Require significantly lower power levels, up to 60% less (modulation voltages) to operate and are capable of miniaturization

Requires more elaborate, expensive mechanical packaging (housings) generally comprised of materials, such as gold-plated Kovar, in order to assure operational integrity over required time and operating temperature ranges

Initial tests indicate no requirement for more elaborate, expensive packaging (housings)


We consider organic polymers with electro-optic qualities to be the most feasible technology for future high-speed (wide bandwidth) electronic-optical conversion. Due to the ease of processing afforded by electro-optic polymers, as well as their capacity to foster component size reduction, we believe electro-optic polymers have the potential to replace more expensive, lower-performance materials and devices used in fiber-optic ground, wireless and satellite communication networks that are used today in commercial and military telecommunications and advanced computational systems.


We also believe potential future applications may include: (i) cloud computing and data centers; (ii) telecommunications/data communications; (iii) backplane optical interconnects; (iv) photovoltaic cells; (v) medical applications; (vi) satellite reconnaissance; (vii) navigation systems; (viii) radar applications; (ix) optical filters; (x) spatial light modulators; and (xi) all-optical switches.


Our Electro-Optic Technology Approach


Our proposed solution to produce high-performance, high-stability electro-optic polymers for high-speed (wide bandwidth) telecommunication applications lies in a less mainstream, yet firmly established, scientific phenomenon called aromaticity. Aromaticity causes a high degree of molecular stability. It is a molecular arrangement wherein atoms combine into multi-membered rings and share their electrons among each other. Aromatic compounds are stable because the electronic charge distributes evenly over a great area preventing hostile moieties, such as oxygen and free radicals, from finding an opening to attack.


For the past two decades, diverse corporate interests, including, to our knowledge, IBM, Lockheed Martin, DuPont, AT&T Bell Labs, Honeywell and 3M, as well as numerous universities and U.S. Government Agencies, have been attempting to produce high-performance, high-stability electro-optic polymers for high-speed (wide bandwidth) telecommunication applications. These efforts have largely been unsuccessful due, in our opinion, to the industry's singular adherence to an industry pervasive engineering model known as the Bond Length Alternation ("BLA") theory model. The BLA model, like all other current industry-standard molecular designs, consists of molecular designs containing long strings of atoms called polyene chains. Longer polyene chains provide higher electro-optic performance, but are also more susceptible to environmental threats, which result in unacceptably low-performing, thermally unstable electro-optic polymers.




3





As a result, high frequency modulators engineered with electro-optic polymers designed on the BLA model or any other polyene chain design models are unstable over typical operating temperature ranges, and often exhibit performance degradation within days, hours or even minutes. Similarly, lower frequency modulators exhibit comparable failings, but to a lesser extent. These flaws, in most cases, have prevented commercial quality polymer-based modulators operating at 10-40Gb/s from entering the commercial marketplace. The thermal stability of these devices does not generally meet the minimum Telcordia GR-468 operating temperature range (-40 degrees Celsius to +85 degrees Celsius) much less the more harsh MILSPEC 883D (military specification) range of -55 degrees Celsius to 150 degrees Celsius.


None of our patented molecular designs rely on the BLA polyene chain design model.


Our Intellectual Property


Issued U.S. Patents:

 

 

·

Heterocyclical Chromophore Architectures (Granted April 5, 2011)

·

Tricyclic Spacer Systems for Nonlinear Optical Devices (Granted February 22, 2011)

·

Heterocyclical Chromophore Architectures (Granted September 18, 2012)

·

Tricyclic Spacer Systems for Nonlinear Optical Devices (Granted- October 30, 2012)


Issued Australian Patents:

 

 

·

Heterocyclical Chromophore Architectures (Granted November 29, 2012)


Allowed Japanese Patents:

 

 

·

Heterocyclical Chromophore Architectures (Granted March 19, 2013)


We have twenty-four pending patent applications (including six patent families with applications in Australia, Canada, China, European Patent Office, Japan and the U.S. based on the PCT and U.S. applications below) in the field of nonlinear optic chromophore design as follows:

 

 

·

Stable Free Radical Chromophores, processes for preparing the same

·

Stable Free Radical Chromophores, processes for preparing the same

·

Tricyclic Spacer Systems for Nonlinear Optical Devices

·

Anti-Aromatic Chromophore Architectures

·

Heterocyclical Anti-Aromatic Chromophore Architectures

·

Heterocyclical Chromophore Architectures

·

Heterocyclical Chromophore Architectures with Novel Electronic Acceptor Systems


Heterocyclical Anti-Aromatic Systems Two of our provisional patents cover heterocyclical anti-aromatic electronic conductive pathways, which are the heart of our high-performance, high-stability molecular designs. The completely heterocyclical nature of our molecular designs "lock" conductive atomic orbitals into a planar (flat) configuration, which provides improved electronic conduction and a significantly lower reaction to environmental threats (e.g. thermal, chemical, photochemical, etc.) than the BLA design paradigm employed by other competitive electro-optic polymers.


The anti-aromatic nature of these structures dramatically improves the "zwitterionic-aromatic push-pull" of the systems, providing for low energy charge transfer. Low energy charge transfer is important for the production of extremely high electro-optic character.


Heterocyclical Steric Hindering System This patent describes a nitrogenous heterocyclical structure for the integration of steric hindering groups that are necessary for the nanoscale material integration. Due to the [pi]-orbital configuration of the nitrogen bridge, this structure has been demonstrated not to interfere with the conductive nature of the electronic conductive pathway and thus is non-disruptive to the electro-optic character of the core molecular construction. The quantum mechanical design of the system is designed to establish complete molecular planarity (flatness) for optimal performance.




4





Totally Integrated Material Engineering System This patent covers material integration structures under a design strategy known as Totally Integrated Material Engineering. These integration structures provide for the "wrapping" of the core molecule in sterically hindering groups that maximally protect the molecule from environmental threats and maximally protect it from microscopic aggregation (which is a major cause of performance degradation and optical loss) within a minimal molecular volume. These structures also provide for the integration of polymerizable groups for integration of materials into a highly stable cross-linked material matrix.


Historic Breakthroughs and Results


During 2004, independent quantum mechanical calculations performed on our electro-optic polymer designs at government laboratories located at the Naval Air Warfare Center Weapons Division in China Lake, California suggested that our initial aromatic molecules perform two and a half (2.5) to three and three-tenths (3.3) times more efficiently than currently available telecom grade electro-optic polymers. Our conclusion was that performance improvements of this magnitude indicate a significant breakthrough in the field of fiber-optic telecommunication.


In May and June of 2006, performance evaluations of one of our first extremely high-performance electro-optic materials were performed by electro-optic expert, Dr. C.C. Teng, co-inventor of the renowned Teng-Man test, and subsequently confirmed by the University of Arizona's College of Optical Sciences. Under identical laboratory conditions at low molecular loadings, one of our molecular designs outperformed one of the industry's highest performance electro-optic systems by a factor as high as 650%. Our conclusion was that the Teng-Man test established the validity of our novel, patent pending molecular design paradigm known as CSC (Cyclical Surface Conduction) theory; and that the success of CSC theory has the potential to establish the fundamental blueprint of electro-optic material design for decades to come, and to have broad application in commercial and military telecommunication and advanced computational systems.


On September 25, 2006 we obtained independent laboratory results that confirmed the thermal stability of our Perkinamine™ electro-optic materials. Thermal stability as high as 350 degrees Celsius was confirmed, significantly exceeding many other then commercially available high performance electro-optic materials, such as CLD-1 that exhibits thermal degradation in the range of 250 degrees Celsius to 275 degrees Celsius. This high temperature stability of our materials eliminates a major obstacle to vertical integration of electro-optic polymers into standard microelectronic manufacturing processes (e.g. wave/vapor-phase soldering) where thermal stability of at least 300 degrees Celsius is required. In independent laboratory tests, ten-percent material degradation, a common evaluation of overall thermal stability, did not occur until our Perkinamine™ materials base was exposed to temperatures as high as 350 degrees Celsius, as determined by Thermo-Gravimetric Analysis (TGA). The test results supported our Company's progress to introduce our materials into commercial applications such as optical interconnections, high-speed telecom and datacom modulators, and military/aerospace components.


On September 26, 2006, we were awarded the 2006 Electro-Optic Materials Technology Innovation of the Year Award by Frost & Sullivan. Frost & Sullivan's Technology Innovation of the Year Award is bestowed upon candidates whose original research has resulted in innovations that have, or are expected to bring, significant contributions to multiple industries in terms of adoption, change, and competitive posture. This award recognizes the quality and depth of our Company's research and development program as well as the vision and risk-taking that enabled us to undertake such an endeavor.


In July 2007, our Company developed an innovative process to integrate our unique architecture into our anticipated commercial devices, whereby dendritic spacer systems are attached to its core chromophore. In the event we are successful in developing a commercially viable product, we believe these dendrimers will reduce the cost of manufacturing materials and reduce the cost and complexity of tailoring the material to specific customer requirements.


In March 2008, we commenced production of our first prototype photonic chip, which we delivered to Photon-X, LLC to fabricate a prototype polymer optical modulator and measure its technical properties. In June 2009 we released test results conducted by Dr. C.C. Teng that re-confirmed our previous test results.




5





In August 2009, Photon-X, LLC commenced a compatibility study, process sequences, and fabricated wafers/chips containing arrays of phase modulators. The first one hundred plus modulators (bench top devices) were completed at the end of October 2009, and were successfully characterized for insertion loss, Vpi, modulation dynamic range and initial frequency response in March 2010. The multi-step manufacturing process we utilized to fabricate our modulators involved exposing our proprietary Perkinamine™ materials to extreme conditions that are typically found in standard commercial manufacturing settings. Our step-by-step analysis throughout the fabrication process demonstrated to us that our Perkinamine™ materials could successfully withstand each step of the fabrication process without damage.


In August 2009, we retained Perdix, Inc. in Boulder, Colorado to help us identify and build prototype products for high growth potential target markets in fiber optic telecommunications systems. During October 2009, we initiated the development and production of our prototype amplitude modulator, which can ultimately be assembled into 1- and 2-dimensional arrays that are useful for optical computing applications, such as encryption and pattern recognition. We expected our initial prototype amplitude modulator to be completed by the end of the second quarter 2010. We continued to work on this device throughout 2010 and discovered its design had limitations so we terminated the program to take a different design approach. We embarked on the new design approach in 2011 with another partner, Boulder Nonlinear Systems (BNS). A feasibility study with our new design partner was started in late 2011. This research and development program continued through 2013, and was completed the end of the third quarter of 2013. The results of this study gave us a guide on how to move forward with the design of our prototype spatial light modulator. The second phase of the program is under review and we expected to start the second phase sometime the second half of 2014; but funding for phase two of this program was delayed. We hope to reengage our work on this program after funding is approved.


In March 2010 we successfully concluded initial electrical and optical performance testing of our prototype phase modulator and began Application Engineering of our technology in customer design environments and working directly with interested large system suppliers to attempt to engineer specific individual product materials and device designs for sale to or by these suppliers.  Those programs were subsequently put on hold by the system suppliers.


In October of 2010, we completed the concept stage of a novel design for an advanced optical computing application and moved forward into the design stage with Celestech, Inc. of Chantilly, Virginia. Several projects with Celestech are currently on hold. If these projects move forward, they will incorporate one or more of our Company’s advanced electro-optical polymer materials.


In October of 2010 we announced the results of testing performed by Lehigh University that demonstrated the third-order non-linear properties of our proprietary molecules in the PerkinamineNR™ chromophore class. Lehigh University determined that the material was 100 times stronger than the highest off-resonance small molecule currently known. They also determined that it was 2,600 times more powerful than fused silica and demonstrated extremely fast (less than 1 picosecond) photo-induced non-linear response that would be capable of modulation at rates of 1 THz (terahertz). Additional testing at Lehigh University of the Company’s other Perkinamine™ class of materials demonstrated third-order non-linear properties, which may have utility in all optical switches.


In March 2011 we entered into a research and development agreement with the City University of New York’s Laboratory for Nano Micro Photonics (LaNMP) to develop third-order non-linear devices. The combination of LaNMP’s device capabilities together with our materials expertise should accelerate the development of all-optical devices. This effort, starting with an all-optical switch, was continued at the University of Colorado, Boulder through an agreement entered into in January 2013. This research and development effort continued through 2014, but not at the pace we expected. In the future we hope to engage a product development partner, which should accelerate the product development program.


In March 2011, we entered into a research and development agreement with the City University of New York’s (“CUNY”) Laboratory for Nano Micro Photonics (LaNMP) to develop third-order non-linear devices. The combination of LaNMP’s device capabilities together with our materials expertise showed promise for the development of all-optical devices. The agreement ran through the end of 2011. The goal of the project was to fabricate and test slot waveguides embedded with two types of nonlinear optical polymers obtained from our Company. These two polymers were Perkinamine™ and PerkinamineNR™. In CUNY’s final report it showed they successfully demonstrated that the Perkinamine™ and PerkinamineNR™ survived their 170 degrees C processing temperature without degradation. According to their report, they were successful in one processing run wherein they showed the possibility to realize waveguides with very smooth sidewalls. Reflectivity measurements carried out under optical pumping showed phase shift in the Perkinamine™ material.




6





In March 2011 we announced a two-year research and development collaboration with the University of Alabama to explore the advanced energy capture properties of our Perkinamine™ class of chromophores. Our material absorbs light across a wide range of wavelengths from near infrared into the near ultraviolet. We have subsequently ended our relationship with the University.


In December 2011, we announced the discovery of a new material named Perkinamine Indigo™. We believed this represented a major advancement in the field of organic nonlinear optical materials. We have much to learn about how to harness full potential of Perkinamine Indigo™. The material demonstrated an unusually high electro-optical effect of greater than 250 picometers per volt at 1550 nanometers with excellent thermal and photo stability. Independent research laboratories at Micron Inc., Photon-X and The University of Colorado confirmed these characteristics. Subsequent measurements showed electro-optical effects closer to 100 picometers per volt in a 500 nm thin films. We continued the development work to better understand these results. In January 2014 we created a new methodology to combine multiple chromophores into a single polymer host that significantly improved our ability to create more powerful organic, nonlinear electro-optical polymer systems. The new synthetic chemistry process can enable multiple chromophores (dyes) to work in concert with each other within a single polymer host. This proprietary process has created two new material systems, which have demonstrated outstanding electro-optic values. In addition, initial thermal stability results exceed any commercially available organic nonlinear polymer material systems.


In June 2012 we opened a new internal research laboratory facility in Newark, Delaware in the Delaware Technology Park, near the University of Delaware. This new lab facility enables us to synthesize and test our materials in the same facility and will help us accelerate our development efforts. It is equipped with state of the art equipment necessary to expand our ability to conduct synthetic chemistry in much more tightly controlled conditions. Additionally, we equipped a separate advanced optical laboratory at the same location where the necessary testing of material candidates will be performed as they emerge from our new synthesis laboratory.  The optical laboratory has subsequently been moved to Longmont, CO.


In July 2012 we entered into an agreement with The University of Colorado, Boulder, Guided Wave Optics Laboratory (GWOL) to conduct analytical testing and to carry out studies that will give a better understanding of the properties of a new class of composite organic electro-optic materials. This class of materials was our Perkinamine Indigo™. The processing and measurements were carried out primarily at the university’s GWOL. The work was completed in close collaboration with Company personnel. It was determined a new synthetic chemistry and material process methodology was needed for consistent and repeatable results. That methodology was announced in January 2014.


In February 2013 we delivered to a potential large system supplier customer prototype devices that were coated with our advanced organic nonlinear electro-optical polymer, Perkinamine Indigo™. Tests conducted by the University of Colorado, Boulder on coupons coated with the material demonstrated R33 measurements from 100-125 picometers per volt, as measured by the University of Colorado which exceeded the potential large system supplier customer's stated electro-optical requirements.


In March 2013 we entered into a product development contractor agreement with EM Photonics (EMP) of Newark, Delaware to fabricate and test waveguides and phase modulators during an initial development phase using existing EMP polymer modulator design and processes. In June 2013 we consolidated the EMP design program into our University of Colorado, Boulder (UCB) program after we fabricated structures with UCB that will be used as the basic building blocks of our Integrated Optical Device effort for the construction of both our advanced telecom modulator and data communications transceiver. In August 2013 in a combined effort of the Company’s chemists, the University of Colorado, Boulder, and a third party research group, we successfully fabricated Silicon Organic Hybrid (SOH) slot waveguide modulators. The devices utilized an existing modulator structure with one of our proprietary electro-optic polymer material systems as the enabling material layer. In October 2013, we confirmed the functionality of the SOH slot waveguide modulators as operating devices.


In April 2013 our potential large system supplier customer informed us that their preliminary testing results on the prototype devices coated with Perkinamine Indigo™ that we delivered to them in February 2013 demonstrated several of the key performance parameters that they desired. There were additional tests that need to be completed. We worked with our potential customer utilizing our Perkinamine™ family of chromophores in a number of host polymers to evaluate these polymers in conjunction with our chromophores for a specific performance attributes for their application. Currently, this customer’s program is on hold, and we do not know when or if this program will restart. We are currently talking to other potential new development partners.




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In August 2013 in a combined effort of the Company’s chemists, the University of Colorado, Boulder, and a third party research group we successfully fabricated Silicon Organic Hybrid (SOH) slot waveguide modulators. The devices utilized an existing modulator structure with one of our proprietary electro-optic polymer material systems as the enabling material layer. In October 2013, we confirmed the functionality of the SOH slot waveguide modulators as operating prototype devices. These first-generation devices have achieved greater electro-optical activity and dramatically lower drive voltage than industry standard modulators based on inorganic materials. We continued this effort in 2014 and have signed an agreement with the third party research group to continue our collaboration through 2016.


In November 2013, preliminary testing and initial data on our SOH slot waveguide modulators demonstrated several promising characteristics. The tested SOH chip had a 1-millimeter square footprint, enabling the possibility of sophisticated integrated optical circuits on a single silicon substrate. In addition, the waveguide structure was approximately 1/20 the length of a typical inorganic-based silicon photonics modulator waveguide. With the combination of our proprietary electro-optic polymer material and the extremely high optical field concentration in the slot waveguide modulator, the test modulators demonstrated less than 2.2 volts to operate. Initial speeds exceeded 30-35 GhZ in the telecom, 1550 nanometer frequency band. This is equivalent to four, 10Gb/sec, inorganic, lithium niobate modulators that would require approximately 12-16 volts to move the same amount of information. Our material also operates in the 1310 nanometer frequency band, which is suitable for data communications applications.


In January 2014 we created a new methodology to combine multiple chromophores into a single polymer host that significantly improves their ability to generate more powerful organic, nonlinear electro-optical polymer systems. The new synthetic chemistry process can enable multiple chromophores (dyes) to work in concert with each other within a single polymer host. This proprietary process has created two new material systems, which have demonstrated outstanding electro-optic values. In addition, we now have a significant amount of data on the thermal aging of our materials. We have demonstrated that our materials can withstand more than 2,000 hours at 110 degrees C with little to no change in electro-optic activity in our materials, which is a significant milestone. To our knowledge, this is something that has not been achieved before in any polymer. We are also concurrently coating prototype waveguides with our proprietary material system.


In February 2014 we received our first purchase order for our advanced organic nonlinear electro-optic polymer from Boulder Nonlinear Systems (BNS) of Boulder, Colorado in connection with the development of a next generation LADAR system. A LADAR system is a radar system that utilizes a pulse laser to calculate the distance to a target, but is also capable of rendering a 3-D image. In the event BNS continues to move forward with the development of this LADAR system, we expect to receive additional purchase orders from BNS.


In March 2014 we began the process of manufacturing an advanced design Silicon Organic Hybrid Transceiver prototype and we released the completed chip design to the OpSIS Center at the University of Delaware who contracted with a third party to produce the initial silicon chips, which were delivered to us in December 2014 and January 2015. We are currently qualifying and testing these chips for utilization in our Silicon Organic Transceiver. The initial application will target inter-data center interconnections of more than 10 kilometers. Our next design will utilize a different frequency and address the current bottleneck in the rack-to-server layer at distances greater than 500 meters.


In April 2014 we entered into a sole worldwide license agreement with Corning Incorporated enabling us to integrate Corning's organic electro-optical chromophores into our portfolio of electro-optic polymer materials. The agreement allows us to use the licensed patents within a defined license field that includes communications, computing, power, and power storage applications utilizing the nonlinear optical properties of their materials.


In August 2014 the University of Colorado successfully fabricated and tested a bleached electro-optic waveguide modulator designed and fabricated through a sponsored collaborative research agreement. The results of this initial bleached waveguide modulator correlated well with previous electro-optic thin film properties. These initial results of our first in-house device were significant to our entire device program and were an important starting point for our current modulators that are being developed for target markets. We have multiple generations of new materials that we are optimizing for this specific design.




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In October 2014 we submitted an order with Reynard Corporation to produce gold-layered fused silica substrates for our bleached waveguide modulators to be coated with several of our organic electro-optical polymers, which we received in early November and performance tested throughout December. In May, 2015, we subsequently decided to eliminate this product from our commercial development plans due to its limited commercial value, low speed characteristics, difficulty to mass-produce and limited ability to integrate with existing architectures.  In lieu of this development program, a commercially viable prototype ridge waveguide modulator program was started to replace the bleached waveguide development.  We believe that the ridge waveguide modulator represents a viable telecom device opportunity for the Company that does not have the inherent limitations seen in bleached waveguide structures.


In May 2015 we achieved operating capability of our in-house Class 100 Clean Room where we expect to do thin film processing and complete the development of prototype photonic devices enabled by our advanced organic electro-optic polymer material systems in a timelier manner. Additionally, the Joint Institute for Laboratory Astrophysics (JILA) certified three of our employees, which allows us access to JILA’s world-class semiconductor facility located at the University of Colorado, Boulder. Access to this facility provides us with better control over the quality of our development work and the speed at which it progresses.


In August 2015 we completed 2,000+ hours of thermal aging tests of several blends of materials created by our multi-chromophore process, which included lengthy exposure to high temperatures (850C and 1100C). The data collected indicated minimal loss of electro-optical activity (R33) of our materials, which means that our organic polymers are expected to provide decades of operational performance. These results exceed previously published efforts for other organic polymers and are an important part of our commercialization effort as we begin to implement these material systems into advanced photonic devices for the telecom and datacom markets.


Additionally, in August 2015, we completed 500+ hours of photochemical stability testing of our material candidates by exposing them to the visible light spectrum. The data collected indicated no discernible change in the chemical structures in an oxygen free environment.  This stability testing was begun to help us understand more clearly the processing and manufacturing requirements of our future commercial products, and provide initial assurances to expect the same results as we move these materials into an actual photonic device structures. This, in turn, has enabled us to begin initial device testing on devices that utilize our silicon photonic chips.


In October 2015, we successfully surpassed 2000 hours of photochemical stability testing of our material candidates with little to no change in the electro-optic characteristics (R33) of our material; and, in January 2016, we successfully surpassed 4000 hours of photochemical stability testing of our material candidates with little to no change in the electro-optic characteristics (R33) of our material.  These photochemical stability test results, along with the thermal stability at 110°C, should enable the Company to demonstrate that organic polymers can compete head-to-head with inorganic crystalline legacy telecom and datacom devices which currently provide the backbone for the entire infrastructure that converts almost incalculable amounts of electronic (binary) data into pulses of light and back on a daily basis.


In November of 2015, we successfully fabricated ridge waveguide structures from our core material system. At the same time we successfully developed a proprietary methodology to segment individual chips from our silicon wafers that contain our ridge waveguide devices.  These critical steps in our process provide us with a clear path towards a commercial telecommunication device. These same processes can be used for the fabrication of modulators to be used in data centers.  The individual chips are now being analyzed and passively tested in our Longmont, CO optical test facility.


In February 2016, we successfully guided laser single-mode light through 16 of our passive ridge waveguides made entirely out of our advanced organic polymer systems, which are the building block of waveguide modulators that can achieve high modulator performance. As a result, our commercialization effort has entered the next phases of development:  passive-waveguide loss measurements, followed by the development and active testing of electro-optic modulators.  Utilizing continuous-wave input laser light, electro-optic modulators convert digital (binary) electrical data into output pulses of light that can be transported across fiber optic communication networks. Active testing is accomplished by applying an electrical signal to a modulator and evaluating the resulting output optical signal.


Presently, we are continuing to move towards completion of our operating organic polymer-enabled ridge waveguide modulator prototype using our new multi-chromophore material systems.




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We ultimately intend to use our next-generation electro-optic polymer material systems and non-linear all-optical polymer material systems for future applications vital to the following industries. We expect to create specific materials for each of these applications as appropriate:

 

·

Cloud computing and data centers

·

Telecommunications/data communications

·

Backplane optical interconnects

·

Photovoltaic cells

·

Medical applications

·

Satellite reconnaissance

·

Navigation systems

·

Radar applications

·

Optical filters

·

Spatial light modulators

·

All-optical switches


In an effort to maximize our future revenue stream from our electro-optic polymer material systems and non-linear all-optical polymer material systems, our business model anticipates that our revenue stream will be derived from one or some combination of the following: (i) technology licensing for specific product applications; (ii) joint venture relationships with significant industry leaders; or (iii) the production and direct sale of our own photonic device components. Our objective is to be a leading provider of proprietary technology and know-how in the photonic device markets. In order to meet this objective, subject to successful testing of our technology and having available financial resources, we intend to:

 

·

Develop electro-optic polymer material systems and non-linear all-optical polymer material systems and photonic devices

·

Continue to develop proprietary intellectual property

·

Streamline our product development process

·

Develop a comprehensive marketing plan

·

Maintain/develop strategic relationships with government agencies, private firms, and academic institutions

·

Continue to attract and retain high level science and technology personnel to our Company


The Electro-Optic Device Market


General


Electro-optic devices such as fiber-optic modulators translate electric signals into optical signals. Such devices are used in communication systems to transfer data over fiber-optic networks. Optical data transfer is significantly faster and more efficient than transfer technologies using only electric signals, permitting more cost-effective use of bandwidth for broadband Internet and voice services.


Two distinct technologies currently exist for the fabrication of fiber-optic devices, such as fiber-optic modulators. The first, which is the more traditional technology, utilizes an electro-optically active inorganic core crystalline material (e.g. lithium niobate). The second, which is the focus of the Company’s research and development, involves the exploitation of electro-optic polymers.


Traditional Technology - Inorganic Crystals


Traditional technology translates electric signals into optical signals generally relying upon electro-optic materials, such as lithium niobate, indium phosphide and gallium arsenide. Five of the largest inorganic fiber-optic component manufactures hold approximately 85% of the electro-optic modulator component market. They are JDSU, Sumitomo, Oclaro, Fujitsu and ThorLabs. These companies are heavily invested in the production of crystalline-based electro-optic modulator technologies, as well as the development of novel manufacturing techniques and integrated laser/modulator designs. While each company possesses their own modulator design and processing patents, the underlying core constituents (lithium niobate, indium phosphide, gallium arsenide) occur in nature and as such cannot be patented.




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New Technology - Organic Polymers


Our developing technology that translates electric signals into optical signals relies upon organic electro-optic materials, such as electro-optic polymers. Electro-optic polymers involve the material integration of specifically engineered organic (carbon-based) compounds. The molecular designs of these compounds are precise and do not occur naturally; thus they may be protected under patent law.


Polymer-based electro-optic modulators may provide considerable advantages over traditional inorganic fiber-optic technology in terms of:


 

·

Cost

 

·

Size and versatility

 

·

Modulating/switching speed

 

·

Optical transmission properties

 

·

Lower operating voltages

 

·

Generate less heat


Our Company holds an extensive amount of internally developed intellectual property in the field of electro-optic molecular design that, as a whole, attempts to fundamentally solve these and other problems associated with these molecular structures. We believe our provisional patents describe broad, highly unique techniques for novel paradigms in molecular design.


Our innovative solution lies in a very well known scientific phenomenon called aromaticity, which causes a high degree of molecular stability. Aromaticity is a molecular arrangement wherein atoms combine into multi-membered rings and share their electrons among each other. Aromatic compounds are extremely stable because the electronic charge distributes evenly over a great area preventing hostile moieties, such as oxygen and free radicals, from finding an opening to attack. Until now, to our knowledge, no one has been able to propose molecular designs that could effectively exploit aromaticity in the design of a high-performance electro-optic polymer.


We believe now that we have fabricated electro-optic molecular architectures that do in fact exhibit extremely high thermal stability, our technologies may soon replace inorganic electro-optic materials in the marketplace due to their considerable advantages over traditional inorganic fiber-optic materials.


Our Target Markets


Our proprietary electro-optic polymers are designed at the molecular level for potentially superior performance, stability and cost-efficiency and we believe may have the potential to replace more expensive, lower-performance materials and devices used in fiber-optic ground, wireless and satellite communication networks. We believe our organic electro-optic polymers may have broad applications in civilian and military telecommunications and advanced computational systems. Potential future applications may include: (i) cloud computing and data centers; (ii) telecommunications/data communications; (iii) backplane optical interconnects; (iv) photovoltaic cells; (v) medical applications; (vi) satellite reconnaissance; (vii) navigation systems; (viii) radar applications; (ix) optical filters; (x) spatial light modulators; and (xi) all-optical switches.


Cloud computing and data centers


Big data is a general term used to describe the voluminous amount of unstructured and semi-structured data a company creates -- data that would take too much time and cost too much money to load into a relational database for analysis. Companies are looking to cloud computing in their data centers to access all the data. Inherent speed and bandwidth limits of traditional solutions and the potential of organic polymer devices offer an opportunity to increase the bandwidth, reduce costs and improve speed of access.




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Telecommunications/Data Communications


Telecommunications is one of the primary initial target applications for electro-optic polymers. Telecommunication companies are currently faced with the enormous challenge to keep up with the tremendous explosion in demand for bandwidth due to the popularity of Internet enabled devices accessing all forms of streaming media, along with voice messaging, text messaging and cloud based data access.


The challenge for these companies is converting digital information in the form of electric signals into optical information and back. Their networks rely upon optical modulators based around inorganic materials, such as lithium niobate, to accomplish this task. These existing legacy modulators have inherent limitations in terms of maximum data rates, error correction, and costs associated with their manufacture and other operating costs related to drive voltage and heat dissipation due to the complexities of producing single crystalline ingots of sufficient diameter (3 to 5 inches). Also, strict environmental controls must be enforced during the growth of the core crystalline material.


Replacing these inorganic materials with organic polymer materials made with the Perkinamine™ family of chromophores would offer significant improvements in data rates; reduce form factor; require less error correction along with a significant reduction in drive voltage leading to less heat dissipation and hence reduce the overall cost of operation with regard to site cooling. Polymers are not inherently costly to produce nor do they require such strict environmental conditions. Due to their material flexibility (e.g. ability to more easily mold into specific topologies) they are expected to enable smaller, faster, less expensive, and more integrated network components. In many laboratory tests, electro-optic polymers have demonstrated substantial (3-10x) transmission data speed improvements over crystalline technologies (lithium niobate, gallium arsenide, indium phosphide).


Backplane Optical Interconnects


Organic nonlinear polymer based devices offer advantages in Active Optical cables that are used in data communications in computer-to-computer or server-to-server applications. It is reported that backplane optical interconnects are envisioned by members within leading corporations (including IBM, Intel and Agilent Technologies) as the future of high-speed computation. These components can potentially replace copper circuitry with photons carrying digital information over fiber optic cable in CPU architecture to manage CPU-to-graphics, CPU–to-memory and CPU-to-I/O device interactions that have previously operated over an internal electrical bus. On-Chip optical buses can increase performance and decrease cost. They could speed the transmission of information within an integrated circuit, among integrated circuit chips in a module, and across circuit boards at speeds unattainable with traditional metallic interconnections and bus structures. Additionally, our organic polymer material possesses the thermal stability necessary to survive Complementary Metal Oxide Semiconductor (CMOS) processing temperatures that gives it the ability to be spin-coated directly on silicon substrates. In the future, all-optical (light-switching-light) signal processing could become possible using an advanced version of our chemistry.


Photovoltaic Cells


A solar cell (also called a photovoltaic cell) is an electrical device that converts the energy of light directly into electricity by the photovoltaic effect. It is a form of photoelectric cell (in that its electrical characteristics—e.g. current, voltage, or resistance—vary when light is incident upon it) which, when exposed to light, can generate and support an electric current without being attached to any external voltage source. These cells are very inefficient. Organic nonlinear polymers offer potential increases in the efficiency of photovoltaic cells that could be orders of magnitude greater than LCD technology.


Medical Applications


Medical Applications for electro-optic polymers have been proposed for many varied applications, including dentistry, oncology and protein identification. Although experimental, it is believed that the successful fabrication of high-stability electro-optic polymers could open up many future applications such as these. Other medical applications such as the higher-speed transmission of medical records, X-ray and MRI scans over the Internet would be improved by the broadening of Internet bandwidth.




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Satellite Reconnaissance


Satellite reconnaissance applications include a specific target market within the Department of Defense, the 14-member Intelligence Community and their contractors. Electro-optic polymers have historically been seen as attractive for potential application in this market due to the constant need for the fastest bandwidth transmission to meet the needs of national security.


Navigation Systems


Navigation systems for both advanced aerial and missile guidance require the use of electro-optic gyroscopes. These devices are currently fabricated out of lithium niobate or similar electro-optic materials; the application of electro-optic polymers would facilitate the development of more accurate and architecturally simple device designs.


Radar Applications


Radar Applications, specifically phased array radar, has been traditionally understood as a potential application for successful electro-optic material designs, along with electronic counter measure systems (ECM) systems, ultra-fast analog-to-digital conversion, LADAR, land mine detection, radio frequency photonics and spatial light modulation.


Optical Filters


Optical filters are devices that utilize optical waveguides and various other structures like ring resonators that can be made with organic nonlinear materials that can filter out a specific wavelengths from one waveguide and redirect them to a different waveguide.


Spatial Light Modulators


Spatial Light Modulators (SLMs) are optical computing devices that can be used in various recognition applications by collecting and correlating optical input to stored images in a database using complex mathematical computations based around calculated light intensity at various point on an image. Existing Liquid Crystal display technology that is accurate, but too slow for widespread adoption has hampered proliferation of these devices.


All-Optical Switches


All-optical switches are expected to be included in the future market of all-optic devices. All-optical devices convert data in the form of input light signals to a secondary light data stream. Some experts anticipate that all-optical switches will replace traditional switches used today in microprocessors. All-optical switches are expected to enable the fabrication of an entirely new high-speed generation of "polymer" based computers that operate on light instead of electricity, which in turn should significantly improve computation speeds.


Our Business Strategy


The Company revised its business strategy from a materials only approach into a dual path strategy that also includes developing devices, components and potentially sub-systems. Our economic model anticipates that our revenue stream will be derived from one or some combination of the following: (i) technology licensing for specific product application; (ii) joint venture relationships with significant industry leaders; or (iii) the production and direct sale of our own electro-optic device components. Our objective is to be a leading provider of proprietary technology and know-how in the electro-optic device market. In order to meet this objective, we intend, subject to successful testing of our technology and having available financial resources, to:


 

·

Develop electro-optic polymer material systems and non-linear all-optical polymer material systems and photonic devices

 

·

Continue to develop proprietary intellectual property

 

·

Streamline our product development process

 

·

Develop a comprehensive marketing plan

 

·

Maintain/develop strategic relationships with government agencies, private firms, and academic institutions

 

·

Continue to attract and retain high level science and technology personnel to our Company




13





Develop Electro-Optic Product Devices


We intend to utilize our proprietary optical polymer technology to create an initial portfolio of commercially feasible electro-optic polymer product devices and applications for various markets, including telecommunications and government. We expect our initial product device line to include high-speed 40Gb/s and 100Gb/s modulators and system applications.

Continue to Develop Proprietary Intellectual Property


We plan to advance our core competence in electro-optic polymer technology by continuing to develop proprietary materials, processes, designs and devices. We also plan to protect our technology by filing patent applications where appropriate, obtaining exclusive technology rights where available, and taking other appropriate steps to secure and protect our intellectual property.


Streamline Our Product Development Process


We intend to streamline our development process and to design, fabricate and test proprietary materials and potential electro-optic polymer devices in order to position our Company to take advantage of emerging market opportunities.


In 2011 we retained the services of EOvation Advisors LLC, a technology and business advisory firm founded by Dr. Frederick Leonberger, former chief technology officer at JDS Uniphase Corporation, a leading provider of communications test and measurement solutions, and optical products. Dr. Leonberger is presently a senior advisor to the Company and its Board of Directors in assisting our Company with strategic planning and the design of optical modulators that we intend to develop.


Develop a Comprehensive Marketing Plan


We are developing sales and marketing plans for our devices for implementation once we produce multiple prototype devices for the optical market. We plan to aggressively pursue sales of our potential products through the use of industry-specific sales organizations, such as electro-optic component representatives and distributors. In addition, we plan to target market leaders as initial customers and to leverage relationships with these market leaders to obtain future contracts and sales references.


Maintain/Develop Strategic Relationships with Government Agencies, Private Firms, and Academic Institutions


Since the formation of our Company, we have had numerous strategic relationships with government agencies that have provided us with funding and access to important technology. We intend to establish, re-establish or maintain our relationships with:


 

1.

DARPA, the Defense Advance Research Project Agency by sharing the technical data and test results on our aromatic molecular materials.

 

2.

Strategic partners ranging from micro-electronic component firms to large-scale computer companies. We believe strategic alliances and/or technology licensing will be a crucial step in commercializing our novel technologies and achieving competitive advantages.

 

3.

The National Science Foundation, an independent federal agency created by Congress to promote the progress of science; to advance the national health, prosperity, welfare and to secure the national defense through advanced and promising new technologies.


Continue to attract and retain high-level science and technology personnel to our Company


In May 2007, we retained Dr. David F. Eaton as our Interim Chief Technology Officer and in January 2008, Dr. Eaton became our permanent Chief Technology Officer until his resignation as such in November 2011. Dr. Eaton now serves as our scientific advisor, a non-executive position. Previously, Dr. Eaton spent thirty years with DuPont where he worked in research & development, research & development management and business leadership positions. Dr. Eaton spearheaded DuPont’s entry into polymer-based components for fiber optic telecommunication by founding DuPont Photonics Technology, a wholly owned subsidiary of DuPont.




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In March 2008, we retained Terry Turpin as our Optical Computing expert. Mr. Turpin began his engineering career developing computing engines for the National Security Agency (NSA) where he served as Chief of the Advanced Processing Technologies Division, representing the NSA on the Tri-Service Optical Processing Committee organized by the Under Secretary of Defense for Research and Engineering.


In November 2008, we retained Howard E. Simmons, III, PhD to our technology team. Dr. Simmons is a graduate of MIT and Harvard, who spent 25 years with DuPont engaged in research & development at the corporate and business unit level. Mr. Simmons has contributed to programs in organic light emitting diodes (OLEDS), printable electronics, graphic arts, optical recording materials and fundamental polymer research and holds 26 patents.


In February 2009, we retained Anthony J. Cocuzza, PhD to our technology team. Dr. Cocuzza worked for 30 years in medicinal chemistry and brings a highly developed set of synthetic and analytical skills to our Company. A graduate of Princeton, Dr. Cocuzza spent 24 years with DuPont engaged in corporate research & development and with DuPont’s joint venture with Merck.


In November 2011 we retained Louis C. Glasgow, PhD as our Chief Technology Officer. For seven years Dr. Glasgow worked at Corning, Inc. as the Director of Organic Technology. Prior to that, Dr. Glasgow spent 28 years working at DuPont in various capacities, his last being Director of Innovation. In May 2013 Dr. Glasgow resigned as Chief Technology Officer and now serves as Senior Technical Advisor to the Company, a non-executive position.


In December 2011, we retained Dr. Frederick Leonberger, PhD as our Senior Advisor. Dr Leonberger is the former Chief Technology Officer of JDS Uniphase, Inc. We previously retained EOvation Advisors LLC, a technology and business advisory firm founded by Dr. Frederick Leonberger, as a consultant to the Company. Dr. Leonberger is presently assisting our Company with strategic planning and the design of optical modulators that we intend to develop. Starting January 2013, Dr. Leonberger also serves as an advisor to our Board of Directors.


In February 2014 we retained Ashok Shenvi, PhD as part of our technology team as Senior Principal Investigator. Dr. Shenvi received his Ph.D. from Stanford University and a M.Sc. from the Indian Institute of Technology in Bombay, India. Dr. Shenvi has over 30 years of experience working in medicinal and organic chemistry at Astra Zeneca Pharmaceuticals and central research at E. I. DuPont Company. Dr. Shenvi has authored 37 scientific publications and presentations, and has been granted 20 patents.


Our Research and Development Process


Our research and development process consists of the following steps:


 

·

We develop novel polymer materials utilizing our patented and patent pending technology to meet certain performance specifications. We then develop methods to synthesize larger quantities of such material.

 

·

We conduct a full battery of tests at the completion of the synthesis of each new polymer material to evaluate its characteristics. We also create development strategies to optimize materials to meet specifications for specific applications.

 

·

We integrate data from the material characterization and test results to fabricate devices. We analyze device-testing results to refine and improve fabrication processes and methods. In addition, we investigate alternative material and design variations to possibly create more efficient fabrication processes.

 

·

We create an initial device design using simulation software. Following device fabrication, we run a series of optical and electronic tests on the device.


We have and expect to continue to make significant operating and capital expenditures for research and development. Our operating expenses were $1,929,924 and $1,160,723 for the three months ended September 30, 2015 and 2014, respectively, for an increase of $769,201.


Our Proprietary Products in Development


As part of a two-pronged marketing strategy, our Company is developing several optical devices, which are in various stages of development and that utilize our organic nonlinear optical materials. They include:




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Ridge Waveguide Modulator


Our ridge electro-optic waveguide modulator was designed and fabricated in our Longmont, Colorado lab. The fabrication of our first in-house device is significant to our entire device program and is an important starting point for modulators that are being developed for target markets. We have multiple generations of new materials that we will soon be optimizing for this specific design. The ridge waveguide modulator represents our first commercially viable device, and targets metro networks (< 10Km) within large scale telecommunications and data communications networks and represents approximately a $300MM per year market opportunity for us.


Slot Waveguide Modulator


Our functional Silicon Organic Hybrid (SOH) slot waveguide modulator utilizes an existing modulator structure with one of our proprietary electro-optic polymer material systems as the enabling material layer, and is functional as an operating prototype device. Preliminary testing and initial data on our SOH slot waveguide modulators demonstrated several promising characteristics. The tested SOH chip had a 1-millimeter square footprint, enabling the possibility of sophisticated integrated optical circuits on a single silicon substrate. In addition, the waveguide structure was approximately 1/20 the length of a typical inorganic-based silicon photonics modulator waveguide. With the combination of our proprietary electro-optic polymer material and the extremely high optical field concentration in the slot waveguide modulator, the test modulators demonstrated less than 2.2 volts to operate. Initial speeds exceeded 30-35 GhZ in the telecom, 1550 nanometer frequency band. This is equivalent to four, 10Gb/sec, inorganic, lithium niobate modulators that would require approximately 12-16 volts to move the same amount of information. Our material also operates in the 1310 nanometer frequency band, which is suitable for data communications applications. We continued with our collaborative development of our SOH slot waveguide modulator in 2014 and have signed an agreement with the associated third party research group to continue our collaboration through 2016.


Spatial Light Modulator


We have a development program to develop a Spatial Light Modulator with an outside manufacturer, Boulder Nonlinear Systems (BNS) utilizing certain Perkinamine™ chromophores. A spatial modulator is a form of optical computer that can perform various advanced tasks, such as object and facial recognition, by using advanced mathematical calculations known as Fourier Transforms. Our organic nonlinear optical materials can potentially produce update rates of more than a million times per second, which is a significant improvement in processing speed over existing Liquid Crystal Display technology that updates at only 30 to 60 times per second.


100 Gbps Telecommunications Modulator


We have recently begun a second-generation design of a unique telecommunications modulator incorporating our newly developed materials in the Perkinamine™ family. We anticipate this modulator will be able to exceed the performance of existing legacy modulators by an order of magnitude, and will allow for improvements in the form of reduced power consumption and reduced device cost.


200 Gbps Datacomm/Telecomm Photonic Transceiver


We propose to develop multichannel integrated nanophotonic transceivers for application in data communications. The transceiver consists of a silicon photonic chip fabricated with nonlinear polymer infused modulators (SOH), multiplexers, demultiplexers, detectors and grating fiber couplers to an external light source. The CMOS-compatible optical modulators are key components for future silicon-based photonic transceivers. Our solution, the silicon-organic hybrid (SOH) platform has been proposed and is being prototyped. In the SOH approach, the optical signal is guided by a silicon waveguide while an organic cladding provides the electro-optic effect.




16





Other Potential Applications For Our Products


Optical Filters


We are in preliminary design and fabrication phases of development of an optical filter using our proprietary Perkinamine™ and PerkinamineNR™ materials within a SiNx photonics platform. Initial work has been done in collaboration with City University of New York, but limitations in their process capabilities have led us to seek alternate fabrication facilities, which are underway at this time.


All-Optical Switches


An all-optical switch is one that enables signals in optical fibers or networks to be selectively switched from one fiber or circuit to another. Many device designs have been developed and commercialized in today’s telecom networks to effect optical switching by using mechanical or electrical control elements to accomplish the switching event. Future networks will require all-optical switches that can be more rapidly activated with a low energy and short duration optical (light) control pulse.


Multi-Channel Optical Modem


The availability of low cost electro-optic modulators will enable low cost multichannel optical modems that will use many wavelengths in parallel and employ high efficiency modulation techniques such as QAM (quadrature amplitude modulation). Such modems would enable an order of magnitude increase in the Internet capacity of legacy fiber. Lightwave Logic is in the early feasibility stage of such a multichannel optical modem.


Our Current Strategic Partners


Boulder Non-Linear Systems


Boulder Nonlinear Systems, Inc. is a Colorado company that designs, manufactures and sells liquid crystal based photonics devices and systems. BNS builds unique analog liquid crystal on silicon modulators used in applications ranging from holographic storage to microscopic cell manipulation. Its advanced liquid crystal technology is used in telecommunications, medical instruments, defense, and manufacturing.


Our Past Government Program Participation


Our Company has been a participant in several vital government sponsored research and development programs with various government agencies that protect the interests of our country. The following is a list of some of the various divisions of government agencies that have provided us with advisory, financial and/or materials support in the pursuit of high-speed electro-optic materials. We are not partnered with, strategically related to, or financially supported by any governmental agency at this time. Our previous relationships included:


 

·

National Reconnaissance Office (NRO)

 

·

Properties Branch of the Army Research Laboratory on the Aberdeen Proving Grounds in Aberdeen, Maryland.

 

·

Defense Advance Research Project Agency (DARPA)

 

·

Naval Air Warfare Center Weapons Division in China Lake, California

 

·

Air Force Research Laboratory at Wright-Patterson Air Force Base in Dayton, Ohio


Our Competition


The markets we are targeting for our electro-optic polymer technology are intensely competitive. Among the largest fiber-optic component manufactures are Finisar, JDSU, Oclaro, NeoPhotonics, OpLink, CyOptics. Additionally, the five largest inorganic modulator component manufacturers hold approximately 85% of the electro-optic modulator component market. They are JDSU, Sumitomo, Oclaro, Fujitsu and ThorLabs. These companies are heavily invested in the production of crystalline-based electro-optic modulator technologies, as well as the development of novel manufacturing techniques and modulator designs.




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We considered GigOptix, Inc., as our primary polymer competitor. They designed and patented potentially commercially feasible electro-optic polymers and hold an exclusive license to all electro-optic polymeric technology developed at the University of Washington. GigOptix presently has a joint venture with CPqD.  Subsequently, GigOptix sold a majority interest of their polymer IP to BrPhotonics based in Brazil.


We believe that through the commercialization of our technology, we will be poised to obtain a significant portion of the component manufacturing market. Electro-optic polymers demonstrate several advantages over other technologies, such as inorganic-based technologies, due to their reduced manufacturing and processing costs, higher performance and lower power requirements. Our patented organic polymers and future electro-optic devices have demonstrated significant stability advantages over our known competitor's materials.


We believe the principal competitive factors in our target markets are:


 

·

The ability to develop and commercialize highly stable optical polymer-based materials and optical devices, including obtaining appropriate patent and proprietary rights protection.

 

·

Lower cost, high production yield for these products.

 

·

The ability to enable integration and implement advanced technologies.

 

·

Strong sales and marketing, and distribution channels for access to products.


We believe that our current business planning will position our Company to compete adequately with respect to these factors. Our future success is difficult to predict because we are an early stage company with all of our potential products still in development.


Many of our existing and potential competitors have substantially greater research and product development capabilities and financial, scientific, marketing and human resources than we do. As a result, these competitors may:


 

·

Succeed in developing products that are equal to or superior to our potential products or that achieve greater market acceptance than our potential products.

 

·

Devote greater resources to developing, marketing or selling their products.

 

·

Respond quickly to new or emerging technologies or scientific advances and changes in customer requirements, which could render our technologies or potential products obsolete.

 

·

Introduce products that make the continued development of our potential products uneconomical.

 

·

Obtain patents that block or otherwise inhibit our ability to develop and commercialize our potential products.

 

·

Withstand price competition more successfully than we can.

 

·

Establish cooperative relationships among themselves or with third parties that enhance their ability to address the needs of our prospective customers.

 

·

Take advantage of acquisition or other opportunities more readily than we can.


Our Laboratory Facilities


In June 2012 we opened an internal research laboratory facility in Newark, Delaware in the Delaware Technology Park, near the University of Delaware. This lab facility enables us to synthesize and test our materials in the same facility and to accelerate our development efforts. It is equipped with state of the art equipment necessary to conduct synthetic chemistry in much more tightly controlled conditions.


In January of 2014 we moved our Corporate Headquarters, as well as our advanced optical laboratory at the same location where the necessary testing of material candidates will be performed as they emerge from our synthesis laboratory.  We commenced construction of clean room at this facility during the fourth quarter of 2014, which became fully operational and functional in April 2015. This clean room enables us to expand our in-house prototype development capabilities.  


Employees


We currently have 9 full-time employees and 7 part-time employees, and we retain several independent contractors on an as-needed basis. We believe that we have good relations with our employees.




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Properties


Our executive and business office headquarters are located at 1831 Lefthand Circle, Suite C, Longmont, CO 80501. We coordinate our operations, optical device design, optical laboratory, thin films laboratory and clean room, and market our services from this space. Our annual base rent for this space is $47,578.


We also lease approximately 2,000 square feet of laboratory space at 1 Innovation Way, Newark, Delaware 19711, which we utilize to operate an organic synthesis and thin-films laboratory. Our annual rent for this space is approximately $71,662. We vacated our 1,400 square feet of laboratory space at 41A Germay Drive, Wilmington, Delaware during 2015.


Legal Proceedings


We are not currently a party to or engaged in any material legal proceedings and we are not aware of any litigation or threatened litigation of a material nature. However, we may be subject to various claims and legal actions arising in the ordinary course of business from time to time.


Item 1A.

Risk Factors.


Investing in our common stock is risky. In addition to the other information contained in this annual report, you should consider carefully the following risk factors in evaluating our business and us. If any of the following events actually occur, our business, operating results, prospects or financial condition could be materially and adversely affected. This could cause the trading price of our common stock to decline and you may lose all or part of your investment. The risks described below are not the only ones that we face. Additional risks not presently known to us or that we currently deem immaterial may also significantly impair our business operations and could result in a complete loss of your investment.


We have incurred substantial operating losses since our inception and will continue to incur substantial operating losses for the foreseeable future.


Since our inception, we have been engaged primarily in the research and development of our electro-optic polymer materials technologies and potential products. As a result of these activities, we incurred significant losses and experienced negative cash flow since our inception. We incurred a net loss of $4,845,432 for the year ended December 31, 2015 and $4,409,797 for the year ended December 31, 2014. We anticipate that we will continue to incur operating losses through at least 2016.

 

 

We may not be able to generate significant revenue either through development contracts from the U.S. government or government subcontractors or through customer contracts for our potential products or technologies. We expect to continue to make significant operating and capital expenditures for research and development and to improve and expand production, sales, marketing and administrative systems and processes. As a result, we will need to generate significant additional revenue to achieve profitability. We cannot assure you that we will ever achieve profitability.


We are subject to the risks frequently experienced by early stage companies.


The likelihood of our success must be considered in light of the risks frequently encountered by early stage companies, especially those formed to develop and market new technologies. These risks include our potential inability to:


  

·

Establish product sales and marketing capabilities;

  

·

Establish and maintain markets for our potential products;

  

·

Identify, attract, retain and motivate qualified personnel;

  

·

Continue to develop and upgrade our technologies to keep pace with changes in technology and the growth of markets using polymer based materials;

  

·

Develop expanded product production facilities and outside contractor relationships;

  

·

Maintain our reputation and build trust with customers;

  

·

Scale up from small pilot or prototype quantities to large quantities of product on a consistent basis;

  

·

Contract for or develop the internal skills needed to master large volume production of our products; and

  

·

Fund the capital expenditures required to develop volume production due to the limits of our available financial resources.

 



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If we fail to effectively manage our growth, and effectively transition from our focus on research and development activities to commercially successful products, our business could suffer.


Failure to manage growth of operations could harm our business. To date, a large number of our activities and resources have been directed at the research and development of our technologies and development of potential related products. The transition from a focus on research and development to being a vendor of products requires effective planning and management. Additionally, growth arising from the expected synergies from future acquisitions will require effective planning and management. Future expansion will be expensive and will likely strain management and other resources.


In order to effectively manage growth, we must:

 

  

·

Continue to develop an effective planning and management process to implement our business strategy;

  

·

Hire, train and integrate new personnel in all areas of our business; and

  

·

Expand our facilities and increase capital investments.

 

We cannot assure you that we will be able to accomplish these tasks effectively or otherwise effectively manage our growth.


We will require additional capital to continue to fund our operations and if we do not obtain additional capital, we may be required to substantially limit our operations.


Our business does not presently generate the cash needed to finance our current and anticipated operations. Based on our current operating plan and budgeted cash requirements, we believe that we have sufficient funds to finance our operations through January 2017; however, we will need to obtain additional future financing after that time to finance our operations until such time that we can conduct profitable revenue-generating activities. We expect that we will need to seek additional funding through public or private financings, including equity financings, and through other arrangements, including collaborative arrangements. Poor financial results, unanticipated expenses or unanticipated opportunities could require additional financing sooner than we expect. Other than with respect to the purchase agreement (the “Purchase Agreement”) we entered into with Lincoln Park Capital Fund, LLC (“Lincoln Park”), we have no plans or arrangements with respect to the possible acquisition of additional financing, and such financing may be unavailable when we need it or may not be available on acceptable terms.


Our forecast of the period of time through which our financial resources will be adequate to support our operations is a forward-looking statement and involves risks and uncertainties, and actual results could vary as a result of a number of factors, including the factors discussed elsewhere in this annual report. We have based this estimate on assumptions that may prove to be wrong, and we could use our available capital resources sooner than we currently expect.


Additional financing may not be available to us, due to, among other things, our Company not having a sufficient credit history, income stream, profit level, asset base eligible to be collateralized, or market for its securities. If we raise additional funds by issuing equity or convertible debt securities, the percentage ownership of our existing shareholders may be reduced, and these securities may have rights superior to those of our common stock. If adequate funds are not available to satisfy our long-term capital requirements, or if planned revenues are not generated, we may be required to substantially limit our operations.


We are entering new markets, and if we fail to accurately predict growth in these new markets, we may suffer substantial losses.


We are devoting significant resources to engineer next-generation organic nonlinear optical materials and devices for future applications to be utilized by electro-optic device manufacturers, such as telecommunications component and systems manufacturers, networking and switching suppliers, semiconductor companies, aerospace companies and government agencies as well as the our proprietary photonic devices. We expect to continue to develop products for these markets and to seek to identify new markets. These markets change rapidly and we cannot assure you that they will grow or that we will be able to accurately forecast market demand, or lack thereof, in time to respond appropriately. Our investment of resources to develop products for these markets may either be insufficient to meet actual demand or result in expenses that are excessive in light of actual sales volumes. Failure to predict growth and demand accurately in new markets may cause us to suffer substantial losses. In addition, as we enter new markets, there is a significant risk that:

 

  

·

The market may not accept the price and/or performance of our products;

  

·

There may be issued patents we are not aware of that could block our entry into the market or could result in excessive litigation; and

  

·

The time required for us to achieve market acceptance of our products may exceed our capital resources that would require additional investment.




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Our plan to develop relationships with strategic partners may not be successful.


Part of our business strategy is to maintain and develop strategic relationships with government agencies, private firms, and academic institutions to conduct research and development of technologies and products. For these efforts to be successful, we must identify partners whose competencies complement ours. We must also successfully enter into agreements with them on terms attractive to us, and integrate and coordinate their resources and capabilities with our own. We may be unsuccessful in entering into agreements with acceptable partners or negotiating favorable terms in these agreements. Also, we may be unsuccessful in integrating the resources or capabilities of these partners. In addition, our strategic partners may prove difficult to work with or less skilled than we originally expected. If we are unsuccessful in our collaborative efforts, our ability to develop and market products could be severely limited.


The failure to establish and maintain collaborative relationships may have a materially adverse affect on our business.


We plan to sell many of our products directly to commercial customers or through potential industry partners. For example, we expect to sell our electro-optic polymer products to electro-optic device manufacturers, such as telecommunications component and systems manufacturers, networking and switching suppliers, semiconductor companies, aerospace companies and government agencies. Our ability to generate revenues depends significantly on the extent to which potential customers and other potential industry partners develop, promote and sell systems that incorporate our products, which, of course, we cannot control. Any failure by potential customers and other potential industry partners to successfully develop and market systems that incorporate our products could adversely affect our sales. The extent to which potential customers and other industry partners develop, promote and sell systems incorporating our products is based on a number of factors that are largely beyond our ability to control.

 

We may participate in joint ventures that expose us to operational and financial risk.


We may participate in one or more joint ventures for the purpose of assisting us in carrying out our business expansion, especially with respect to new product and/or market development. We may experience with our joint venture partner(s) issues relating to disparate communication, culture, strategy, and resources. Further, our joint venture partner(s) may have economic or business interests or goals that are inconsistent with ours, exercise their rights in a way that prohibits us from acting in a manner which we would like or they may be unable or unwilling to fulfill their obligations under the joint venture or other agreements. We cannot assure you that the actions or decisions of our joint venture partners will not affect our operations in a way that hinders our corporate objectives or reduces any anticipated cost savings or revenue enhancement resulting from these ventures.


If we fail to develop and introduce new or enhanced products on a timely basis, our ability to attract and retain customers could be impaired and our competitive position could be harmed.


We plan to operate in a dynamic environment characterized by rapidly changing technologies and industry standards and technological obsolescence. To compete successfully, we must design, develop, market and sell products that provide increasingly higher levels of performance and reliability and meet the cost expectations of our customers. The introduction of new products by our competitors, the market acceptance of products based on new or alternative technologies, or the emergence of new industry standards could render our anticipated products obsolete. Our failure to anticipate or timely develop products or technologies in response to technological shifts could adversely affect our operations. In particular, we may experience difficulties with product design, manufacturing, marketing or certification that could delay or prevent our development, introduction or marketing of products. If we fail to introduce products that meet the needs of our customers or penetrate new markets in a timely fashion our Company will be adversely affected.


Our future growth will suffer if we do not achieve sufficient market acceptance of our organic nonlinear optical material products or our proprietary photonic devices.


We are developing our organic nonlinear optical material products to be utilized by electro-optic device manufacturers, such as telecommunications component and systems manufacturers, networking and switching suppliers, semiconductor companies, aerospace companies and government agencies as well as the our proprietary photonic devices. All of our potential products are still in the development stage, and we do not know when a market for these products will develop, if at all. Our success depends, in part, upon our ability to gain market acceptance of our products. To be accepted, our products must meet the technical and performance requirements of our potential customers. OEMs, suppliers or government agencies may not accept polymer-based products. In addition, even if we achieve some degree of market acceptance for our potential products in one industry, we may not achieve market acceptance in other industries for which we are developing products.



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Achieving market acceptance for our products will require marketing efforts and the expenditure of financial and other resources to create product awareness and demand by customers. We may be unable to offer products that compete effectively due to our limited resources and operating history. Also, certain large corporations may be predisposed against doing business with a company of our limited size and operating history. Failure to achieve broad acceptance of our products by customers and to compete effectively would harm our operating results.

 

Our potential customers require our products to undergo a lengthy and expensive qualification process, which does not assure product sales.


Prior to purchasing our products, our potential customers require that both our products undergo extensive qualification processes. These qualification processes may continue for several months or more. However, qualification of a product by a customer does not assure any sales of the product to that customer. Even after successful qualification and sales of a product to a customer, a subsequent revision to the product, changes in our customer’s manufacturing process or our selection of a new supplier may require a new qualification process, which may result in additional delays. Also, once one of our products is qualified, it could take several additional months or more before a customer commences volume production of components or devices that incorporate our products. Despite these uncertainties, we are devoting substantial resources, including design, engineering, sales, marketing and management efforts, to qualifying our products with customers in anticipation of sales. If we are unsuccessful or delayed in qualifying any of our products with a customer, sales of our products to a customer may be precluded or delayed, which may impede our growth and cause our business to suffer.


Obtaining a sales contract with a potential customer does not guarantee that a potential customer will not decide to cancel or change its product plans, which could cause us to generate no revenue from a product and adversely affect our results of operations.


Even after we secure a sales contract with a potential customer, we may experience delays in generating revenue from our products as a result of a lengthy development cycle that may be required. Potential customers will likely take a considerable amount of time to evaluate our products; it could take 12 to 24 months from early engagement by our sales team to actual product sales. The delays inherent in these lengthy sales cycles increase the risk that a customer will decide to cancel, curtail, reduce or delay its product plans, causing us to lose anticipated sales. In addition, any delay or cancellation of a customer’s plans could materially and adversely affect our financial results, as we may have incurred significant expense and generated no revenue. Finally, our customers’ failure to successfully market and sell their products could reduce demand for our products and materially and adversely affect our business, financial condition and results of operations. If we were unable to generate revenue after incurring substantial expenses to develop any of our products, our business would suffer.


Many of our products will have long sales cycles, which may cause us to expend resources without an acceptable financial return and which makes it difficult to plan our expenses and forecast our revenue.


Many of our products will have long sales cycles that involve numerous steps, including initial customer contacts, specification writing, engineering design, prototype fabrication, pilot testing, regulatory approvals (if needed), sales and marketing and commercial manufacture. During this time, we may expend substantial financial resources and management time and effort without any assurance that product sales will result. The anticipated long sales cycle for some of our products makes it difficult to predict the quarter in which sales may occur. Delays in sales may cause us to expend resources without an acceptable financial return and make it difficult to plan expenses and forecast revenues.


Successful commercialization of our current and future products will require us to maintain a high level of technical expertise.


Technology in our target markets is undergoing rapid change. To succeed in our target markets, we will have to establish and maintain a leadership position in the technology supporting those markets. Accordingly, our success will depend on our ability to:


  

·

Accurately predict the needs of our target customers and develop, in a timely manner, the technology required to support those needs;

  

·

Provide products that are not only technologically sophisticated but are also available at a price acceptable to customers and competitive with comparable products;

  

·

Establish and effectively defend our intellectual property; and

  

·

Enter into relationships with other companies that have developed complementary technology into which our products may be integrated.




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We cannot assure you that we will be able to achieve any of these objectives.


Two of our significant target markets are the telecommunications and networking markets, which are subject to slow growth and overcapacity.


Two of our significant target markets are the telecommunications and networking markets, and developments that adversely affect the telecommunications or networking markets, including delays in traffic growth and changes in U.S. government regulation, could slow down, or even halt our efforts to enter into these markets. Reduced spending and technology investment by telecommunications companies may make it more difficult for our products to gain market acceptance. Such companies may be less willing to purchase new technology such as ours or invest in new technology development when they have reduced capital expenditure budgets.


Our inability to successfully acquire and integrate other businesses, assets, products or technologies could harm our business and cause us to fail at achieving our anticipated growth.

 

It is our intent to continue to grow our business through strategic acquisitions and investments and we are actively evaluating acquisitions and strategic investments in businesses, products or technologies that we believe could complement or expand our product offering, create and/or expand a client base, enhance our technical capabilities or otherwise offer growth or cost-saving opportunities. From time to time, we may enter into letters of intent with companies with which we are negotiating potential acquisitions or investments or as to which we are conducting due diligence. Although we are currently not a party to any binding definitive agreement with respect to potential investments in, or acquisitions of, complementary businesses, products or technologies, we may enter into these types of arrangements in the future, which could materially decrease the amount of our available cash or require us to seek additional equity or debt financing. We have limited experience in successfully acquiring and integrating businesses, products and technologies. We may not be successful in negotiating the terms of any potential acquisition, conducting thorough due diligence, financing the acquisition or effectively integrating the acquired business, product or technology into our existing business and operations. Our due diligence may fail to identify all of the problems, liabilities or other shortcomings or challenges of an acquired business, product or technology, including issues related to intellectual property, product quality or product architecture, regulatory compliance practices, revenue recognition or other accounting practices, or employee or customer issues.


Additionally, in connection with any acquisitions we complete, we may not achieve the synergies or other benefits we expected to achieve, and we may incur write-downs, impairment charges or unforeseen liabilities that could negatively affect our operating results or financial position or could otherwise harm our business. If we finance acquisitions using existing cash, the reduction of our available cash could cause us to face liquidity issues or cause other unanticipated problems in the future. If we finance acquisitions by issuing convertible debt or equity securities, the ownership interest of our existing stockholders may be diluted, which could adversely affect the market price of our stock. Further, contemplating or completing an acquisition and integrating an acquired business, product or technology could divert management and employee time and resources from other matters, which could harm our business, financial condition and operating results.


We may not be able to access the full amounts available under the Lincoln Park Purchase Agreement, which could prevent us from accessing the capital we need to continue our operations that could have an adverse affect on our business.


Under the purchase agreement (the “Purchase Agreement”) we entered into with Lincoln Park Capital Fund, LLC (“Lincoln Park”), we may direct Lincoln Park to purchase up to $20,000,000 worth of shares of our common stock over a 36-month period. On any trading day selected by us, we may sell shares of common stock to Lincoln Park in amounts up to 100,000 shares per regular sale (Regular Purchases), which may be increased to up to 200,000 shares depending on certain conditions as set forth in the Purchase Agreement, up to the aggregate commitment of $20,000,000. If the market price of our common stock is not below $1.00 per share on the purchase date, then the Regular Purchase amount may be increased to 150,000 shares. If the market price is not below $1.50 per share on the purchase date, then the Regular Purchase amount may be increased to 200,000 shares. Although there are no upper limits on the per share price Lincoln Park may pay to purchase our common stock, the Company may not sell more than $500,000 in shares of common stock to Lincoln Park per Regular Purchase.


In addition to Regular Purchases, we may in our sole discretion direct Lincoln Park on each purchase date to make “accelerated purchases” on the following business day up to the lesser of (i) two (2) times the number of shares purchased pursuant to such Regular Purchase or (ii) 30% of the trading volume on the accelerated purchase date at a purchase price equal to the lesser of (i) the closing sale price on the accelerated purchase date and (ii) 95% of the accelerated purchase date’s volume weighted average price.



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The purchase price of the shares related to the Purchase Agreement will be based on the prevailing market prices of the Company’s shares of common stock, which shall be equal to the lesser of the lowest sale price of the common shares during the purchase date and the average of the three (3) lowest closing sale prices of the common shares during the twelve (12) business days prior to the purchase date without any fixed discount.


Depending on the prevailing market price of our common stock, we may not be able to sell shares to Lincoln Park for the maximum $20,000,000 over the term of the Purchase Agreement.


The sale of shares of our common stock to Lincoln Park under the Purchase Agreement may cause substantial dilution to our existing stockholders and could cause the price of our common stock to decline.


Under the Purchase Agreement, we may sell to Lincoln Park, from time to time and under certain circumstances, up to $20,000,000 of our common stock over approximately 36 months subsequent to the effective date of the registration statement that covers the resale by Lincoln Park of up to 5,000,000 shares of our common stock. We may be required to file and have declared effective one or more additional registration statements to cover the resale by Lincoln Park of additional shares of our common stock that we may sell and issue to Lincoln Park. Generally, with respect to the Purchase Agreement, we have the right, but no obligation, to direct Lincoln Park to periodically purchase up to $20,000,000 of our common stock in specific amounts under certain conditions, which periodic purchase amounts can be increased under specified circumstances.


We also agreed to issue to Lincoln Park up to an aggregate of 1,000,000 shares of common stock as a fee for Lincoln Park’s commitment to purchase our shares under the Purchase Agreement. Of these commitment shares, we issued 350,000 shares upon entering into the Purchase Agreement. The remaining 650,000 commitment shares are issuable to Lincoln Park on a pro rata basis as additional purchases are made under the Purchase Agreement.


Depending upon market liquidity at the time, sales of shares of our common stock to Lincoln Park may cause the trading price of our common stock to decline. Lincoln Park may ultimately purchase all, some or none of the $20,000,000 of common stock under the Purchase Agreement, and after it has acquired shares, Lincoln Park may sell all, some or none of those shares. Therefore, sales to Lincoln Park by us could result in substantial dilution to the interests of other holders of our common stock. The sale of a substantial number of shares of our common stock to Lincoln Park, or the anticipation of such sales, could make it more difficult for us to sell equity or equity-related securities in the future at a time and at a price that we might otherwise wish to effect sales. However, we have the right to control the timing and amount of any sales of our shares to Lincoln Park, and the Purchase Agreement may be terminated by us at any time at our discretion without any cost to us.


The exercise of options and warrants and other issuances of shares of common stock or securities convertible into common stock will dilute your interest.

 

As of December 31, 2015, we have outstanding options and warrants to purchase an aggregate of 18,006,488 shares of our common stock at exercise prices ranging from $0.63 - $1.69 per share with a weighted average exercise price of $0.92 per share. The exercise of options and warrants at prices below the market price of our common stock could adversely affect the price of shares of our common stock. Additional dilution may result from the issuance of shares of our capital stock in connection with any collaboration (although none are contemplated at this time) or in connection with other financing efforts, including pursuant to the Purchase Agreement with Lincoln Park.  

 

Any issuance of our common stock that is not made solely to then-existing stockholders proportionate to their interests, such as in the case of a stock dividend or stock split, will result in dilution to each stockholder by reducing his, her or its percentage ownership of the total outstanding shares. Moreover, if we issue options or warrants to purchase our common stock in the future and those options or warrants are exercised or we issue restricted stock, stockholders may experience further dilution. Holders of shares of our common stock have no preemptive rights that entitle them to purchase their pro rata share of any offering of shares of any class or series.


We may incur debt in the future that might be secured with our intellectual property as collateral, which could subject our Company to the risk of loss of all of our intellectual property.

 

If we incur debt in the future, we may be required to secure the debt with our intellectual property, including all of our patents and patents pending. In the event we default on the debt, we could incur the loss of all of our intellectual property, which would materially and adversely affect our Company and cause you to lose your entire investment in our Company.




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Our quarter-to-quarter performance may vary substantially, and this variance, as well as general market conditions, may cause our stock price to fluctuate greatly and even potentially expose us to litigation.

 

We have generated no significant sales to date and we cannot accurately estimate future quarterly revenue and operating expenses based on historical performance. Our quarterly operating results may vary significantly based on many factors, including:

 

  

·

Fluctuating demand for our potential products and technologies;

  

·

Announcements or implementation by our competitors of technological innovations or new products;

  

·

Amount and timing of our costs related to our marketing efforts or other initiatives;

  

·

The status of particular development programs and the timing of performance under specific development agreements;

  

·

Timing and amounts relating to the expansion of our operations;

  

·

Product shortages requiring suppliers to allocate minimum quantities;

  

·

Announcements or implementation by our competitors of technological innovations or new products;

  

·

The status of particular development programs and the timing of performance under specific development agreements;

  

·

Our ability to enter into, renegotiate or renew key agreements;

  

·

Timing and amounts relating to the expansion of our operations;

  

·

Costs related to possible future acquisitions of technologies or businesses; or

  

·

Economic conditions specific to our industry, as well as general economic conditions.


Our current and future expense estimates are based, in large part, on estimates of future revenue, which is difficult to predict. We expect to continue to make significant operating and capital expenditures in the area of research and development and to invest in and expand production, sales, marketing and administrative systems and processes. We may be unable to, or may elect not to, adjust spending quickly enough to offset any unexpected revenue shortfall. If our increased expenses were not accompanied by increased revenue in the same quarter, our quarterly operating results would be harmed.


Our failure to compete successfully could harm our business.


The markets that we are targeting for our organic nonlinear optical material technology are intensely competitive. Most of our present and potential competitors have or may have substantially greater research and product development capabilities, financial, scientific, marketing, manufacturing and human resources, name recognition and experience than we have. As a result, these competitors may:


  

·

Succeed in developing products that are equal to or superior to our potential products or that will achieve greater market acceptance than our potential products;

  

·

Devote greater resources to developing, marketing or selling their products;

  

·

Respond more quickly to new or emerging technologies or scientific advances and changes in customer requirements, which could render our technologies or potential products obsolete;

  

·

Introduce products that make the continued development of our potential products uneconomical;

  

·

Obtain patents that block or otherwise inhibit our ability to develop and commercialize our potential products;

  

·

Withstand price competition more successfully than we can;

  

·

Establish cooperative relationships among themselves or with third parties that enhance their ability to address the needs of our prospective customers.


The failure to compete successfully against these existing or future competitors could harm our business.


We may be unable to obtain effective intellectual property protection for our potential products and technology.


Our intellectual property, or any intellectual property that we have or may acquire, license or develop in the future, may not provide meaningful competitive advantages. Our patents and patent applications, including those we license, may be challenged by competitors, and the rights granted under such patents or patent applications may not provide meaningful proprietary protection. For example, numerous patents held by third parties relate to polymer materials and electro-optic devices. These patents could be used as a basis to challenge the validity or limit the scope of our patents or patent applications. A successful challenge to the validity or limitation of the scope of our patents or patent applications could limit our ability to commercialize our polymer materials technology and, consequently, reduce our revenues.




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Moreover, competitors may infringe our patents or those that we license, or successfully avoid these patents through design innovation. To combat infringement or unauthorized use, we may need to resort to litigation, which can be expensive and time-consuming and may not succeed in protecting our proprietary rights. In addition, in an infringement proceeding a court may decide that our patents or other intellectual property rights are not valid or are unenforceable, or may refuse to stop the other party from using the intellectual property at issue on the ground that it is non-infringing. Policing unauthorized use of our intellectual property is difficult and expensive, and we may not be able to, or have the resources to, prevent misappropriation of our proprietary rights, particularly in countries where the laws may not protect these rights as fully as the laws of the United States.


We also rely on the law of trade secrets to protect unpatented technology and know-how. We try to protect this technology and know-how by limiting access to those employees, contractors and strategic partners with a need to know this information and by entering into confidentiality agreements with these parties. Any of these parties could breach the agreements and disclose our trade secrets or confidential information to our competitors, or these competitors might learn of the information in other ways. Disclosure of any trade secret not protected by a patent could materially harm our business.


We may be subject to patent infringement claims, which could result in substantial costs and liability and prevent us from commercializing our potential products.


Third parties may claim that our potential products or related technologies infringe their patents. Any patent infringement claims brought against us may cause us to incur significant expenses, divert the attention of our management and key personnel from other business concerns and, if successfully asserted against us, require us to pay substantial damages. In addition, as a result of a patent infringement suit, we may be forced to stop or delay developing, manufacturing or selling potential products that are claimed to infringe a patent covering a third party's intellectual property unless that party grants us rights to use its intellectual property. We may be unable to obtain these rights on terms acceptable to us, if at all. Even if we are able to obtain rights to a third party's patented intellectual property, these rights may be non-exclusive, and therefore our competitors may obtain access to the same intellectual property. Ultimately, we may be unable to commercialize our potential products or may have to cease some of our business operations as a result of patent infringement claims, which could severely harm our business.


If our potential products infringe the intellectual property rights of others, we may be required to indemnify customers for any damages they suffer. Third parties may assert infringement claims against our current or potential customers. These claims may require us to initiate or defend protracted and costly litigation on behalf of customers, regardless of the merits of these claims. If any of these claims succeed, we may be forced to pay damages on behalf of these customers or may be required to obtain licenses for the products they use. If we cannot obtain all necessary licenses on commercially reasonable terms, we may be unable to continue selling such products.


Our technology may be subject to government rights and retained research institution rights.


We may have obligations to government agencies or universities in connection with the technology that we have developed, including the right to require that a compulsory license be granted to one or more third parties selected by certain government agencies. In addition, academic research partners often retain certain rights, including the right to use the technology for noncommercial academic and research use, to publish general scientific findings from research related to the technology, and to make customary scientific and scholarly disclosures of information relating to the technology. It is difficult to monitor whether our partners will limit their use of the technology to these uses, and we could incur substantial expenses to enforce our rights to our licensed technology in the event of misuse.


The loss of certain of our key personnel, or any inability to attract and retain additional personnel, could impair our ability to attain our business objectives.


Our future success depends to a significant extent on the continued service of our key management personnel, particularly Thomas E. Zelibor, our Chief Executive Officer and James S. Marcelli our President and Chief Operating Officer. Accordingly, the loss of the services of either of these persons would adversely affect our business and our ability to timely commercialize our products, and impede the attainment of our business objectives.


Our future success will also depend on our ability to attract, retain and motivate highly skilled personnel to assist us with product development and commercialization. Competition for highly educated qualified personnel in the polymer industry is intense. If we fail to hire and retain a sufficient number of qualified management, engineering, sales and technical personnel, we will not be able to attain our business objectives.




26





If we fail to develop and maintain the quality of our manufacturing processes, our operating results would be harmed.


The manufacture of our potential products is a multi-stage process that requires the use of high-quality materials and advanced manufacturing technologies. Also, polymer-related device development and manufacturing must occur in a highly controlled, clean environment to minimize particles and other yield and quality-limiting contaminants. In spite of stringent quality controls, weaknesses in process control or minute impurities in materials may cause a substantial percentage of a product in a lot to be defective. If we are not able to develop and continue to improve on our manufacturing processes or to maintain stringent quality controls, or if contamination problems arise, our operating results would be harmed.


The complexity of our anticipated products may lead to errors, defects and bugs, which could result in the necessity to redesign products and could negatively, impact our reputation with customers.


Products as complex as those we intend to market might contain errors, defects and bugs when first introduced or as new versions are released. Delivery of products with production defects or reliability, quality or compatibility problems could significantly delay or hinder market acceptance of our products or result in a costly recall and could damage our reputation and adversely affect our ability to sell our products. If our products experience defects, we may need to undertake a redesign of the product, a process that may result in significant additional expenses.


We may also be required to make significant expenditures of capital and resources to resolve such problems. There is no assurance that problems will not be found in new products after commencement of commercial production, despite testing by our suppliers, our customers and us.


If we decide to make commercial quantities of products at our facilities, we will be required to make significant capital expenditures to increase capacity.


We lack the internal ability to manufacture products at a level beyond the stage of early commercial introduction. To the extent we do not have an outside vendor to manufacture our products, we will have to increase our internal production capacity and we will be required to expand our existing facilities or to lease new facilities or to acquire entities with additional production capacities. These activities would require us to make significant capital investments and may require us to seek additional equity or debt financing. We cannot assure you that such financing would be available to us when needed on acceptable terms, or at all. Further, we cannot assure you that any increased demand for our potential products would continue for a sufficient period of time to recoup our capital investments associated with increasing our internal production capacity.


In addition, we do not have experience manufacturing our potential products in large quantities. In the event of significant demand for our potential products, large-scale production might prove more difficult or costly than we anticipate and lead to quality control issues and production delays.


We may not be able to manufacture products at competitive prices.


To date, we have produced limited quantities of products for research, development, demonstration and prototype purposes. The cost per unit for these products currently exceeds the price at which we could expect to profitably sell them. If we cannot substantially lower our cost of production as we move into sales of products in commercial quantities, our financial results will be harmed.


We conduct significantly all of our research and development activities at a limited number of facilities, and circumstances beyond our control may result in considerable interruptions.


We conduct significantly all of our research and development activities at a limited number of facilities. A disaster such as a fire, flood or severe storm at or near one of our facilities could prevent us from further developing our technologies or manufacturing our potential products, which would harm our business.


We are subject to regulatory compliance related to our operations.


We are subject to various U.S. governmental regulations related to occupational safety and health, labor and business practices. Failure to comply with current or future regulations could result in the imposition of substantial fines, suspension of production, alterations of our production processes, cessation of operations, or other actions, which could harm our business.




27





We may be unable to export our potential products or technology to other countries, convey information about our technology to citizens of other countries or sell certain products commercially, if the products or technology are subject to United States export or other regulations.


We are developing certain polymer-based products that we believe the United States government and other governments may be interested in using for military and information gathering or antiterrorism activities. United States government export regulations may restrict us from selling or exporting these potential products into other countries, exporting our technology to those countries, conveying information about our technology to citizens of other countries or selling these potential products to commercial customers. We may be unable to obtain export licenses for products or technology if necessary. We currently cannot assess whether national security concerns would affect our potential products and, if so, what procedures and policies we would have to adopt to comply with applicable existing or future regulations.


We may incur liability arising from the use of hazardous materials.


Our business and our facilities are subject to a number of federal, state and local laws and regulations relating to the generation, handling, treatment, storage and disposal of certain toxic or hazardous materials and waste products that we use or generate in our operations. Many of these environmental laws and regulations subject current or previous owners or occupiers of land to liability for the costs of investigation, removal or remediation of hazardous materials. In addition, these laws and regulations typically impose liability regardless of whether the owner or occupier knew of, or was responsible for, the presence of any hazardous materials and regardless of whether the actions that led to the presence were taken in compliance with the law. In our business, we use hazardous materials that are stored on site. We use various chemicals in our manufacturing process that may be toxic and covered by various environmental controls. An unaffiliated waste hauler transports the waste created by use of these materials off-site. Many environmental laws and regulations require generators of waste to take remedial actions at an off-site disposal location even if the disposal was conducted lawfully. The requirements of these laws and regulations are complex, change frequently and could become more stringent in the future. Failure to comply with current or future environmental laws and regulations could result in the imposition of substantial fines, suspension of production, alteration of our production processes, cessation of operations or other actions, which could severely harm our business.


A material weakness in internal controls may remain undetected for a longer period because of our Company's exemption from the auditor attestation requirements under Section 404(b) of Sarbanes-Oxley.


Our annual report does not include an attestation report of the Company’s independent registered public accounting firm regarding internal control over financial reporting. Management’s report was not subject to attestation by the Company’s registered public accounting firm pursuant to rules of the Securities and Exchange Commission that permit the Company to provide only management’s attestation in this annual report. As a result, a material weakness in our internal controls may remain undetected for a longer period.


Shares Eligible for Future Sale May Adversely Affect the Market.


From time to time, certain of the Company’s shareholders may be eligible to sell all or some of their shares of common stock by means of ordinary brokerage transactions in the open market pursuant to Rule 144, promulgated under the Securities Act, subject to certain limitations.  In general, a non-affiliate stockholder who has satisfied a six-month holding period may, under certain circumstances, sell its shares, without limitation. Any substantial sale of the Company’s common stock pursuant to Rule 144 or pursuant to any resale prospectus may have a material adverse effect on the market price of our common stock.


There Is A Limited Market For Our Common Stock, Which May Make It More Difficult For You To Sell Your Stock.


Our Company’s common stock is quoted on the OTC Market (OTCQB) under the symbol "LWLG." The trading market for our common stock is limited, accordingly, there can be no assurance as to the liquidity of any markets that may develop for our common stock, your ability to sell our common stock, or the prices at which you may be able to sell our common stock.




28





We are subject to the “penny stock” rules and brokers cannot generally solicit the purchase of our common stock, which adversely affects its liquidity and market price.


The SEC has adopted regulations that generally define “penny stock” to be an equity security that has a market price of less than $5.00 per share, subject to specific exemptions.  The market price of our common stock on the over-the-counter market has been substantially less than $5.00 per share and therefore we are currently considered a “penny stock” according to SEC rules.  This designation requires any broker-dealer selling these securities to disclose certain information concerning the transaction, obtain a written agreement from the purchaser and determine that the purchaser is reasonably suitable to purchase the securities.  These rules limit the ability of broker-dealers to solicit purchases of our common stock and therefore reduce the liquidity of the public market for our shares.


Our Company’s Stock Price May Be Volatile.


The market price of our Company’s common stock is likely to be highly volatile and could fluctuate widely in price in response to various factors, many of which are beyond our control, including:


  

·

Technological innovations or new products and services by our Company or our competitors;

  

·

Additions or departures of key personnel;

  

·

Sales of our Companys common stock;

  

·

Our Companys ability to integrate operations, technology, products and services;

  

·

Our Companys ability to execute our business plan;

  

·

Operating results below expectations;

  

·

Loss of any strategic relationship;

  

·

Industry developments

  

·

Economic and other external factors; and

  

·

Period-to-period fluctuations in our Companys financial results.

 

Because we have a limited operating history, you may consider any one of these factors to be material. Our stock price may fluctuate widely as a result of any of the above listed factors.


In addition, the securities markets have from time to time experienced significant price and volume fluctuations that are unrelated to the operating performance of particular companies. These market fluctuations may also materially and adversely affect the market price of our Company’s common stock.

 

Item 1B.

Unresolved Staff Comments.

 

Not Applicable


Item 2.

Properties.


Our executive and business office headquarters are located at 1831 Lefthand Circle, Suite C, Longmont, CO 80501. We coordinate our operations, optical device design, optical laboratory, thin films laboratory and clean room, and market our services from this space. Our annual base rent for this space is $46,208.

 

We also lease approximately 2,000 square feet of laboratory space at 1 Innovation Way, Newark, Delaware 19711, which we utilize to operate an organic synthesis and thin-films laboratory.  Our annual rent for this space is approximately $71,662. We also lease approximately 1,400 square feet of laboratory space at 41A Germay Drive, Wilmington, Delaware 19804-1100. Our annual rent for this space is $9,869.


Item 3.

Legal Proceedings.


We are not aware of any litigation or threatened litigation of a material nature.


Item 4.

Mine Safety Disclosures.


Not Applicable.


29





PART II

 

Item 5.

Market For Registrant’s Common Equity, Related Stockholder Matters and Issuer Purchases Of Equity Securities.

 

Market Information


Our common stock is traded on the OTCQB under the symbol “LWLG”. The following table set forth below lists the range of high and low bids for our common stock for our two most recent fiscal years. The prices in the table reflect inter-dealer prices, without retail markup, markdown or commission and may not represent actual transactions or a liquid trading market. 


  

  

High

  

Low

  

  

  

  

  

2014

1st Quarter

$1.03

  

$0.68

  

2nd Quarter

$0.94

  

$0.70

  

3rd Quarter

$1.19

  

$0.87

  

4th Quarter

$0.91

  

$0.74

  

  

  

  

  

2015

1st Quarter

$1.02

  

$0.73

  

2nd Quarter

$0.97

  

$0.68

  

3rd Quarter

$0.79

  

$0.60

  

4th Quarter

$0.87

  

$0.48


As of March 17, 2016, we have a total of 65,591,629 shares of common stock outstanding, held by approximately 147 record shareholders. We do not have any shares of preferred stock outstanding.


Dividends


No cash dividends have been declared or paid on our common stock to date. No restrictions limit our ability to pay dividends on our common stock. The payment of cash dividends in the future, if any, will be contingent upon our Company's revenues and earnings, if any, capital requirements and general financial condition. The payment of any dividends is within the discretion of our board of directors. Our board of director's present intention is to retain all earnings, if any, for use in our business operations and, accordingly, the board of directors does not anticipate paying any cash dividends in the foreseeable future.

 

Securities Authorized for Issuance under Equity Compensation Plans


Equity Compensation Plans as of December 31, 2015.


Equity Compensation Plan Information

 

Plan category

Number of securities to be issued upon exercise of outstanding options, warrants and rights

 

(a)

Weighted-average exercise price of outstanding options, warrants and rights

 

(b)

Number of securities remaining available for future issuance under equity compensation plans (excluding securities reflected in column (a))

 

(c)

Equity compensation plans approved by security holders (1)

6,389,500

$0.83

2,266,600

Equity compensation plans not approved by security holders (2)

1,137,500

$0.99

0

Total

7,527,000

$0.86

2,266,600


1.

Reflects our 2007 Employee Stock Plan for the benefit of our directors, officers, employees and consultants. We have reserved 10,000,000 shares of common stock for such persons pursuant to that plan.

2.

Comprised of common stock purchase warrants we issued for services.



30





Penny Stock Regulations and Restrictions on Marketability


The SEC has adopted rules that regulate broker-dealer practices in connection with transactions in penny stocks. Penny stocks are generally equity securities with a market price of less than $5.00, other than securities registered on certain national securities exchanges or quoted on the NASDAQ system, provided that current price and volume information with respect to transactions in such securities is provided by the exchange or system. The penny stock rules require a broker-dealer, prior to a transaction in a penny stock, to deliver a standardized risk disclosure document prepared by the SEC, that: (a) contains a description of the nature and level of risk in the market for penny stocks in both public offerings and secondary trading; (b) contains a description of the broker's or dealer's duties to the customer and of the rights and remedies available to the customer with respect to a violation of such duties or other requirements of the securities laws; (c) contains a brief, clear, narrative description of a dealer market, including bid and ask prices for penny stocks and the significance of the spread between the bid and ask price; (d) contains a toll-free telephone number for inquiries on disciplinary actions; (e) defines significant terms in the disclosure document or in the conduct of trading in penny stocks; and (f) contains such other information and is in such form, including language, type size and format, as the SEC shall require by rule or regulation.


The broker-dealer also must provide, prior to effecting any transaction in a penny stock, the customer with (a) bid and offer quotations for the penny stock; (b) the compensation of the broker-dealer and its salesperson in the transaction; (c) the number of shares to which such bid and ask prices apply, or other comparable information relating to the depth and liquidity of the market for such stock; and (d) a monthly account statement showing the market value of each penny stock held in the customer's account.


In addition, the penny stock rules require that prior to a transaction in a penny stock not otherwise exempt from those rules, the broker-dealer must make a special written determination that the penny stock is a suitable investment for the purchaser and receive the purchaser's written acknowledgment of the receipt of a risk disclosure statement, a written agreement as to transactions involving penny stocks, and a signed and dated copy of a written suitability statement.


These disclosure requirements may have the effect of reducing the trading activity for our common stock. Therefore, stockholders may have difficulty selling our securities.


Recent Sales of Unregistered Securities


During the period covered by this report, our Company has sold the following securities without registering the securities under the Securities Act:


Securities issued for cash


Date

  

Security

  

  

  

May - June 2015

  

Units – 2,816,199 shares of common stock and warrants to purchase 2,816,199 shares of common stock contained in units for total proceeds of $1,915,000.

 

  

 

Nov. - Dec. 2015

  

Units – 3,977,568 shares of common stock and warrants to purchase 3,977,568 shares of common stock contained in units for total proceeds of $2,400,000.

  

  

  

Securities issued for services


Date

  

Security

  

  

  

During 2015

  

Common Stock – 12,040 shares of common stock at $0.83 per share.    

  

  

  

During 2015

  

Common Stock – 37,500 shares of common stock at $0.81 per share.    

  

  

  

During 2015

 

Common Stock – 12,718 shares of common stock at $0.66 per share.  

 

  

  

January 2015

  

Warrants – right to buy 115,000 shares of common stock at $0.77 per share.  

 

 

 

July 2015

 

Warrants – right to buy 125,000 shares of common stock at $0.70 per share.  





31





Securities issued pursuant to our Employee Stock Plan


Date

  

Security

 

 

 

March 2015

  

Stock Options –252,000 shares of common stock at $0.80 per share.  

  

  

  

July 2015

  

Stock Options – 2,100,000 shares of common stock at $0.70 per share.

 

 

 

August 2015

  

Stock Options – 50,000 shares of common stock at $$0.67 per share.  

  

  

  

August 2015

  

Stock Options – 275,000 shares of common stock at $0.69 per share.

  

  

  

October 2015

  

Stock Options – 35,000 shares of common stock at $0.74 per share.

  

  

  

November 2015

  

Stock Options – 100,000 shares of common stock at $0.86 per share.


No underwriters were utilized and no commissions or fees were paid with respect to any of the above transactions. These persons were the only offerees in connection with these transactions. We relied on Section 4(a)(2), 4(a)5) and Rule 506 of Regulation D of the Securities Act since the transaction does not involve any public offering.


Item 6.

Selected Financial Data.


Not Applicable.

 

Item 7.

MANAGEMENT’S DISCUSSION AND ANALYSIS OF FINANCIAL CONDITION AND RESULTS OF OPERATIONS.

 

The following management's discussion and analysis of financial condition and results of operations provides information that management believes is relevant to an assessment and understanding of our plans and financial condition. The following selected financial information is derived from our historical financial statements and should be read in conjunction with such financial statements and notes thereto set forth elsewhere herein and the "Forward-Looking Statements" explanation included herein.


Overview


We are a development stage, electro-optical device and organic nonlinear materials company. Our primary area of expertise is the chemical synthesis of chromophore dyes used in the development of organic Application Specific Electro-Optic Polymers (ASEOP) and organic Non-Linear All-Optical Polymers (NLAOP) that have high electro-optic and optical activity. Our family of materials are thermally and photo-chemically stable, which we believe could have utility across a broad range of applications in devices that address markets such as telecommunication, data communications, high-speed computing and photovoltaic cells. Secondarily, our Company is developing proprietary electro-optical and all-optical devices utilizing the advanced capabilities of our materials for applications in the fields mentioned above.


Electro-optic devices convert data from electric signals into optical signals for use in communications systems and in optical interconnects for high-speed data transfer. We expect our patented and patent-pending optical materials (chromophores), when combined with selected polymers to make ASEOP and NLAOP material systems and when completed and tested, to be the core of the future generations of optical devices, modules, sub-systems and systems that we will develop or be licensed by electro-optic device manufacturers, such as telecommunications component and systems manufacturers, networking and switching suppliers, semiconductor companies, aerospace companies and government agencies.


Our ASEOP material systems are property-engineered at the molecular level (nanotechnology level) to meet the exacting thermal, environmental and performance specifications demanded by electro-optic devices. We believe that our patented and patent pending technologies will enable us to design polymer based material systems that are free from the numerous diverse and inherent flaws that plague competitive polymer technologies employed by other companies and research groups. We engineer our polymer based material systems with the intent to have temporal, thermal, chemical and photochemical stability within our patented and patent pending molecular chromophore architectures.




32





Our non-linear all optical NLAOP material systems have demonstrated resonantly enhanced third-order properties approximately 2,630 times larger than fused silica, which means that they are highly photo-optically active in the absence of an RF circuit. In this way they differ from other polymer technologies and are considered more advanced next-generation materials.


Our revenue model relies substantially on the assumption that we will be able to successfully develop our polymer based material systems and photonic device products, which will use our polymer based material systems, for applications within the industries named below. When appropriate, we intend to create specific materials for each of these applications and use our proprietary knowledge base to continue to enhance its discoveries.


 

·

cloud computing and data centers

 

·

telecommunications/data communications

 

·

backplane optical interconnects

 

·

photovoltaic cells

 

·

medical applications

 

·

satellite reconnaissance

 

·

navigation systems

 

·

radar applications

 

·

optical filters

 

·

spatial light modulators

 

·

all-optical switches


To be successful, we must, among other things:


 

·

Develop and maintain collaborative relationships with strategic partners;

 

·

Continue to expand our research and development efforts for our products;

 

·

Develop and continue to improve on our manufacturing processes and maintain stringent quality controls;

 

·

Produce commercial quantities of our products at commercially acceptable prices;

 

·

Rapidly respond to technological advancements;

 

·

Attract, retain and motivate qualified personnel; and

 

·

Obtain and retain effective intellectual property protection for our products and technology.

 


We believe that Moore's Law (a principle which states the number of transistors on a silicon chip doubles approximately every eighteen months) will create markets for our high-performance electro-optic materials and photonic device products.


Plan of Operation


Since inception, we have been engaged primarily in the research and development of our polymer based material systems and photonic device products. We are devoting significant resources to engineer next-generation polymer based material systems for future applications to be utilized by electro-optic device manufacturers, such as telecommunications component and systems manufacturers, networking and switching suppliers, semiconductor companies, aerospace companies, government agencies and internal device development. We expect to continue to develop products that we intend to introduce to these rapidly changing markets and to seek to identify new markets. We expect to continue to make significant operating and capital expenditures for research and development activities.


As we move from a development stage company to a product supplier, we expect that our financial condition and results of operations will undergo substantial change. In particular, we expect to record both revenue and expense from product sales, to incur increased costs for sales and marketing and to increase general and administrative expense. Accordingly, the financial condition and results of operations reflected in our historical financial statements are not expected to be indicative of our future financial condition and results of operations.




33





Some of our more significant milestones that we achieved during 2014-2015 include:


In January 2014 we created a new methodology to combine multiple chromophores into a single polymer host that significantly improves their ability to generate more powerful organic, nonlinear electro-optical polymer systems. The new synthetic chemistry process can enable multiple chromophores (dyes) to work in concert with each other within a single polymer host. This proprietary process has created two new material systems, which have demonstrated outstanding electro-optic values. In addition, we now have a significant amount of data on the thermal aging of our materials. We have demonstrated that our materials can withstand more than 2,000 hours at 110 degrees C with little to no change in electro-optic activity in our materials, which is a significant milestone. To our knowledge, this is something that has not been achieved before in any polymer. We are also concurrently coating prototype waveguides with our proprietary material system.


In February 2014 we received our first purchase order for our advanced organic nonlinear electro-optic polymer from Boulder Nonlinear Systems (BNS) of Boulder, Colorado in connection with the development of a next generation LADAR system. A LADAR system is a radar system that utilizes a pulse laser to calculate the distance to a target, but is also capable of rendering a 3-D image. In the event BNS continues to move forward with the development of this LADAR system, we expect to receive additional purchase orders from BNS.


In March 2014 we began the process of manufacturing an advanced design Silicon Organic Hybrid Transceiver prototype and we released the completed chip design to the OpSIS Center at the University of Delaware who contracted with a third party to produce the initial silicon chips, which were delivered to us in December 2014 and January 2015. We are currently qualifying and testing these chips for utilization in our Silicon Organic Transceiver. The initial application will target inter-data center interconnections of more than 10 kilometers. Our next design will utilize a different frequency and address the current bottleneck in the rack-to-server layer at distances greater than 500 meters.


In April 2014 we entered into a sole worldwide license agreement with Corning Incorporated enabling us to integrate Corning's organic electro-optical chromophores into our portfolio of electro-optic polymer materials. The agreement allows us to use the licensed patents within a defined license field that includes communications, computing, power, and power storage applications utilizing the nonlinear optical properties of their materials.


In August 2014 the University of Colorado successfully fabricated and tested a bleached electro-optic waveguide modulator designed and fabricated through a sponsored collaborative research agreement. The results of this initial bleached waveguide modulator correlated well with previous electro-optic thin film properties. These initial results of our first in-house device were significant to our entire device program and were an important starting point for our current modulators that are being developed for target markets. We have multiple generations of new materials that we are optimizing for this specific design.


In October 2014 we submitted an order with Reynard Corporation to produce gold-layered fused silica substrates for our bleached waveguide modulators to be coated with several of our organic electro-optical polymers, which we received in early November and performance tested throughout December. In May, 2015, we subsequently decided to eliminate this product from our commercial development plans due to its limited commercial value, low speed characteristics, difficulty to mass-produce and limited ability to integrate with existing architectures.  In lieu of this development program, a commercially viable prototype ridge waveguide modulator program was started to replace the bleached waveguide development.  We believe that the ridge waveguide modulator represents a viable telecom device opportunity for the Company that does not have the inherent limitations seen in bleached waveguide structures.


In May 2015 we achieved operating capability of our in-house Class 100 Clean Room where we do thin film processing and expect to complete the development of prototype photonic devices enabled by our advanced organic electro-optic polymer material systems in a timelier manner.  Additionally, the Joint Institute for Laboratory Astrophysics (JILA) certified three of our employees, which allows us access to JILA’s world-class semiconductor facility located at the University of Colorado, Boulder. Access to this facility provides us with better control over the quality of our development work and the speed at which it progresses.




34





In August 2015 we completed 2,000+ hours of thermal aging tests of several blends of materials created by our multi-chromophore process, which included lengthy exposure to high temperatures (850C and 1100C). The data collected indicated minimal loss of electro-optical activity (R33) of our materials, which means that our organic polymers are expected to provide decades of operational performance. These results exceed previously published efforts for other organic polymers and are an important part of our commercialization effort as we begin to implement these material systems into advanced photonic devices for the telecom and datacom markets.


Additionally, in August 2015, we completed 500+ hours of photochemical stability testing of our material candidates by exposing them to the visible light spectrum. The data collected indicated no discernible change in the chemical structures in an oxygen free environment.  An accepted industry standard is 2,000 hours. This stability testing was begun to help us understand more clearly the processing and manufacturing requirements of our future commercial products, and provide initial assurances to expect the same results as we move these materials into an actual photonic device structures.


In October 2015, we successfully surpassed 2000 hours of photochemical stability testing of our material candidates with little to no change in the electro-optic characteristics (R33) of our material; and, in January 2016, we successfully surpassed 4000 hours of photochemical stability testing of our material candidates with little to no change in the electro-optic characteristics (R33) of our material.  These photochemical stability test results, along with the thermal stability at 110°C, should enable the Company to demonstrate that organic polymers can compete head-to-head with inorganic crystalline legacy telecom and datacom devices which currently provide the backbone for the entire infrastructure that converts almost incalculable amounts of electronic (binary) data into pulses of light and back on a daily basis.


In November of 2015, we successfully fabricated ridge waveguide structures from our core material system. At the same time we successfully developed a proprietary methodology to segment individual chips from our silicon wafers that contain our ridge waveguide devices.  These critical steps in our process provide us with a clear path towards a commercial telecommunication device. These same processes can be used for the fabrication of modulators to be used in data centers.  The individual chips are now being analyzed and passively tested in our Longmont, CO optical test facility. We continue to move towards completion of an operating organic polymer-enabled ridge waveguide modulator prototype using our new multi-chromophore material systems.


In February 2016, we successfully guided laser single-mode light through 16 of our passive single-mode ridge waveguides made entirely out of our advanced organic polymer systems, which are the building block of waveguide modulators that achieve high modulator performance. As a result, our commercialization effort has entered the next phases of development:  passive-waveguide loss measurements, followed by the development and active testing of electro-optic modulators.  Utilizing continuous-wave input laser light, electro-optic modulators convert digital (binary) electrical data into output pulses of light that can be transported across fiber optical communication networks. Active testing is accomplished by applying an electrical signal to a modulator and evaluating the resulting output optical signal.


Presently, we are continuing to move towards completion of our operating organic polymer-enabled ridge waveguide modulator prototype using our new multi-chromophore material systems.


We ultimately intend to use our next-generation electro-optic polymer material systems and non-linear all-optical polymer material systems for future applications vital to the following industries. We expect to create specific materials for each of these applications as appropriate:


 

·

Cloud computing and data centers

 

·

Telecommunications/data communications

 

·

Backplane optical interconnects

 

·

Photovoltaic cells

 

·

Medical applications

 

·

Satellite reconnaissance

 

·

Navigation systems

 

·

Radar applications

 

·

Optical filters

 

·

Spatial light modulators

 

·

All-optical switches




35





In an effort to maximize our future revenue stream from our electro-optic polymer material systems and non-linear all-optical polymer material systems, our business model anticipates that our revenue stream will be derived from one or some combination of the following: (i) technology licensing for specific product applications; (ii) joint venture relationships with significant industry leaders; (iii) the production and direct sale of our own photonic device components; or (iv) the vertical integration of our modulator into a transceiver device . Our objective is to be a leading provider of proprietary technology and know-how in the photonic device markets. In order to meet this objective, subject to successful testing of our technology and having available financial resources, we intend to:


 

·

Develop electro-optic polymer material systems and non-linear all-optical polymer material systems and photonic devices

 

·

Continue to develop proprietary intellectual property

 

·

Streamline our product development process

 

·

Develop a comprehensive marketing plan

 

·

Maintain/develop strategic relationships with government agencies, private firms, and academic institutions

 

·

Continue to attract and retain high level science and technology personnel to our Company

 

Our Proprietary Products in Development


As part of a two-pronged marketing strategy, our Company is developing several devices, which are in various stages of development that utilize our organic nonlinear optical materials.


They include:


·

Ridge waveguide modulator

·

Slot waveguide modulator

·

Spatial light modulator

·

100 Gbps telecommunications modulator

·

200 Gbps datacomm/telecomm photonic transceiver

·

Integrated photonic system


Additionally, we must continue to create and maintain an infrastructure, including operational and financial systems, and related internal controls, and recruit qualified personnel. Failure to do so could adversely affect our ability to support our operations.


Capital Requirements


As a development stage company, we do not generate revenues. We have incurred substantial net losses since inception. We have satisfied our capital requirements since inception primarily through the issuance and sale of our common stock. During 2014 we received $4,329,978 in cash proceeds from the issuance and sale of our common stock. On June 15, 2015, we completed a private placement of our securities where we raised $1,915,000 in total proceeds. On December 30, 2015, we completed a private placement of our securities where we raised $2,400,000 in total proceeds.


Results of Operations


Comparison of fiscal 2015 to fiscal 2014


Revenues   


As a development stage company, we had revenues of $0 during for the year ended December 31, 2015 and $2,500 for the year ended December 31, 2014.  The Company is in various stages of material and photonic device development and evaluation.  We expect the next revenue stream to be in product development agreements, prototype devices and sale of nonlinear optical polymer materials prior to moving into production.




36





Operating Expenses


Our operating expenses were $4,845,681 and $4,395,684 for the years ended December 31, 2015 and 2014, respectively, for an increase of $449,997. This increase in operating expenses was due primarily to increases in non-cash amortization of options and warrants, salaries and wages, investor relation expenses, laboratory materials and supplies, disposal of obsolete material and equipment, research and development rent and utility expenses, depreciation, research and development consulting fees and annual shareholder meeting expenses offset by decreases in outsourced testing and product development expenses, license fees, general and administrative office expenses, accounting fees, travel expenses, legal expenses and general and administrative consulting fees.


Included in our operating expenses for the year ended December 31, 2015 was $2,825,099 for research and development expenses compared to $2,849,620 for the year ended December 31, 2014, for a decrease of $24,521.   Outsourced testing and prototype development were brought in-house with the completion of the Company’s clean room and optical testing operations.  The decrease in research and development expenses  is primarily due to decreases in outsourced testing and product development expenses and license fees offset by increases in salaries and wages, laboratory materials and supplies, disposal of obsolete material and equipment, research and development rent and utilities, depreciation expense, consulting fees and non-cash stock option and warrant amortization.


Research and development expenses currently consist primarily of compensation for employees engaged in internal research, product development activities; laboratory operations, internal material and device testing and prototype electro-optic device design, development and prototype device processing; costs; and related operating expenses.  


We expect to continue to incur substantial research and development expense to develop and commercialize our photonic devices and electro-optic materials platform. These expenses will increase as a result of accelerated development effort to support commercialization of our non-linear optical polymer materials technology; to build photonic device prototypes in our in-house laboratories; hiring additional technical and support personnel; engaging a senior technical advisor; pursuing other potential business opportunities and collaborations; customer testing and evaluation; and incurring related operating expenses.


Laboratory material testing expense and photonic device development decreased $230,764 from $526,531 for the year ended December 31, 2014 to $295,767 for the year ended December 31, 2015.     


Wages and salaries and benefits increased $90,243 from $942,728 for the year ended December 31, 2014 to $1,032,971 for the year ended December 31, 2015.  


Laboratory materials and supplies increased $63,176 from $140,939 for the year ended December 31, 2014 to $204,115 for the year ended December 31, 2015.


License fees decreased $30,000 to $0 for the year ended December 31, 2015 from $30,000 for the year ended December 31, 2014 for the license fee paid to Corning in accordance with a license agreement.


Consulting expenses increased $10,590 from $71,834 for the year ended December 31, 2014 to $82,424 for the year ended December 31, 2015.


Disposal of obsolete material and equipment increased $20,860 from $3,981 for the year ended December 31, 2014 to $24,841 for the year ended December 31, 2015.


Non-cash stock compensation and stock option and warrant amortization increased $9,390 from $750,729 for the year ended December 31, 2014 to $760,119 for the year ended December 31, 2015.  


Rent expense increased $14,666 from $109,659 for the year ended December 31, 2014 to $124,325 for the year ended December 31, 2015 the optical lab and clean room facility in Colorado.


Depreciation expense increased $22,763 from $130,498 for the year ended December 31, 2014 to $153,261 for the year ended December 31, 2015 primarily due to the additional equipment purchased for the Company’s Delaware and Colorado laboratory facilities.




37





General and administrative expense consists primarily of compensation and support costs for management staff, and for other general and administrative costs, including executive, sales and marketing, investor relations, accounting and finance, legal, consulting and other operating expenses.


General and administrative expenses increased $474,518 to $2,020,582 for the year ended December 31, 2015 from $1,546,064 for the year ended December 31, 2014. The increase is due primarily to increases in non-cash amortization of options and warrants, investor relations expenses, salaries and wages and annual shareholder meeting expenses offset by a decrease in office expenses, accounting fees, travel expenses, legal expenses and consulting fees.


Non-cash stock compensation and stock option amortization increased $448,158 from $222,678 for the year ended December 31, 2014 to $670,836 for the year ended December 31, 2015.


Investor relations expenses increased by $51,592 from $40,546 for the year ended December 31, 2014 to $92,138 for the year ended December 31, 2015.


Wages and salaries and benefits increased $28,276 from $543,820 for the year ended December 31, 2014 to $572,096 for the year ended December 31, 2015.


Expenses for the annual shareholder meeting increased $13,843 from $37,310 for the year ended December 31, 2014 to $51,153 for the year ended December 31, 2015.


Office expenses including administrative and receptionist expenses decreased $26,889 from $56,720 for the year ended December 31, 2014 to $29,831 for the year ended December 31, 2015 for expenses related to the Company’s new headquarter and optical lab in Colorado.  


Accounting fees decreased $10,930 from $99,453 for the year ended December 31, 2014 to $88,523 for the year ended December 31, 2015.


Travel expenses decreased $10,691 from and $61,826 for the year ended December 31, 2014 to $51,135 for the year ended December 31, 2015.


Legal fees decreased $8,329 to $171,728 for the year ended December 31, 2015 from $180,057 for the year ended December 31, 2014.


Consulting fees decreased $10,711 from $20,565 for the year ended December 31, 2014 to $9,854 for the year ended December 31, 2015.  


We expect general and administrative expense to increase in future periods as we increase the level of corporate and administrative activity, including increases associated with our operation as a public company; and significantly increase expenditures related to the future production and sales of our products.


Other Income (Expense)


Other income (expense) increased $16,862 to $249 for the year ending December 31, 2015 from ($16,613) for the year ending December 31, 2014, relating primarily to the commitment fee associated with the purchase of shares by an institutional investor for sale under a stock purchase agreement during 2014.  


Net Loss


Net loss was $4,845,432 and $4,409,797 for the years ended December 31, 2015 and 2014, respectively, for an increase of $435,635 due primarily to increases in non-cash amortization of options and warrants, salaries and wages, investor relation expenses, laboratory materials and supplies, disposal of obsolete material and equipment, research and development rent and utility expenses, depreciation, research and development consulting fees and annual shareholder meeting expenses offset by decreases in outsourced testing and product development expenses, license fees, general and administrative office expenses, accounting fees, travel expenses, legal expenses and general and administrative consulting fees.




38





Significant Accounting Policies


Our Company's accounting policies are more fully described in Note 1 of Notes to Financial Statements. As disclosed in Note 1 of Notes to Financial Statements, the preparation of financial statements in conformity with accounting principles generally accepted in the United States requires management to make estimates and assumptions that affect the amounts reported in the financial statements and accompanying disclosures.  Although these estimates are based on our management’s best knowledge of current events and actions our Company may undertake in the future, actual results could differ from the estimates.


Stock Based Compensation


Our Company uses the Black-Scholes option pricing model to calculate the grant-date fair value of an award, with the following assumptions for 2015 and 2014: no dividend yield in both years, expected volatility, based on the Company’s historical volatility, 75% to 79% in 2015 and between 70.25% to 109% in 2014, risk-free interest rate between 1.44% to 1.70% in 2015 and between 0.58% to 2.08% in 2014 and expected option life of 5 to 5.75 years in 2015 and 2.13 to 7.25 years in 2014.


As of December 31, 2015, there was $209,618 of unrecognized compensation expense related to non-vested market-based share awards that is expected to be recognized through August 2018.  


Liquidity and Capital Resources


During the year ended December 31, 2015, net cash used in operating activities was $3,440,755 and net cash used in investing activities was $309,480, which was due primarily to the Company’s research and development activities and general and administrative expenditures.  Net cash provided by financing activities for the year ended December 31, 2015 was $4,315,000.  At December 31, 2015, our cash and cash equivalents totaled $3,730,705, our assets totaled $5,110,025, our liabilities totaled $102,957, and we had stockholders’ equity of $5,007,068.


During the year ended December 31, 2014, net cash used in operating activities was $3,140,203 and net cash used in investing activities was $294,539, which was due primarily to the Company’s research and development activities and general and administrative expenditures.  Net cash provided by financing activities for the year ended December 31, 2014 was $4,329,978.  At December 31, 2014, our cash and cash equivalents totaled $3,165,940, our assets totaled $4,279,423, our liabilities totaled $221,841, and we had stockholders’ equity of $4,057,582.


Sources and Uses of Cash


Our future expenditures and capital requirements will depend on numerous factors, including: the progress of our research and development efforts; the rate at which we can, directly or through arrangements with original equipment manufacturers, introduce and sell products incorporating our polymer materials technology; the costs of filing, prosecuting, defending and enforcing any patent claims and other intellectual property rights; market acceptance of our products and competing technological developments; and our ability to establish cooperative development, joint venture and licensing arrangements. We expect that we will incur approximately $3,540,000 of expenditures over the next 12 months. Our cash requirements are expected to increase at a rate consistent with the Company’s path to revenue growth as we expand our activities and operations with the objective of commercializing our electro-optic polymer technology during 2016.


Our business does not presently generate the cash needed to finance our current and anticipated operations. We believe we have raised sufficient capital to finance our operations through January 2017; however, we will need to obtain additional future financing after that time to finance our operations until such time that we can conduct profitable revenue-generating activities. Such future sources of financing may include cash from equity offerings, exercise of stock options, warrants and proceeds from debt instruments; but we cannot assure you that such equity or borrowings will be available or, if available, will be at rates or prices acceptable to us.




39





On January 29, 2016, we signed a Purchase Agreement with Lincoln Park Capital Fund, LLC (“Lincoln Park”) to sell up to $20,000,000 of common stock whereby subject to certain conditions and at our sole discretion, Lincoln Park has committed to purchase up to $20,000,000 of our common stock over a 36-month period. We are registering for resale by Lincoln Park under the Purchase Agreement 5,000,000 shares of our common stock in this prospectus, 350,000 of which have already been issued as a commitment fee and 4,650,000 of which may be sold by us to Lincoln Park during the term of the Purchase Agreement. Pursuant to the Purchase Agreement, Lincoln Park is obligated to make purchases as the Company directs in accordance with the Purchase Agreement, which may be terminated by the Company at any time, without cost or penalty. Sales of shares will be made in specified amounts and at prices that are based upon the market prices of our common stock immediately preceding the sales to Lincoln Park. We expect this financing to provide us with sufficient funds to maintain our operations for the foreseeable future. With the additional capital, we expect to achieve a level of revenues attractive enough to fulfill our development activities and adequate enough to support our business model for the foreseeable future. We cannot assure you that we will meet the conditions of the Purchase Agreement with Lincoln Park in order to obligate Lincoln Park to purchase our shares of common stock. In the event we fail to do so, and other adequate funds are not available to satisfy long-term capital requirements, or if planned revenues are not generated, we may be required to substantially limit our operations. This limitation of operations may include reductions in capital expenditures and reductions in staff and discretionary costs.

 

There are no trading volume requirements or restrictions under the Purchase Agreement and we will control the timing and amount of any sales of our common stock to Lincoln Park. Lincoln Park has no right to require any sales by us, but is obligated to make purchases from us as we direct in accordance with the purchase agreement. We can also accelerate the amount of common stock to be purchased under certain circumstances. There are no limitations on use of proceeds, financial or business covenants, restrictions on future funding, rights of first refusal, participation rights, penalties or liquidated damages in the purchase agreement. Lincoln Park may not assign or transfer its rights and obligations under stock the purchase agreement.


We expect that our cash used in operations will increase during 2016 and beyond as a result of the following planned activities:


·

The addition of management, sales, marketing, technical and other staff to our workforce;

·

Increased spending for the expansion of our research and development efforts, including purchases of additional laboratory and production equipment;

·

Increased spending in marketing as our products are introduced into the marketplace;

·

Developing and maintaining collaborative relationships with strategic partners;

·

Developing and improving our manufacturing processes and quality controls; and

·

Increases in our general and administrative activities related to our operations as a reporting public company and related corporate compliance requirements.


Analysis of Cash Flows


For the year ended December 31, 2015


Net cash used in operating activities was $3,440,755 for the year ended December 31, 2015, primarily attributable to the net loss of $4,845,432 adjusted by $91,263 in warrants issued for services, $1,339,692 in options issued for services, $48,963 in common stock issued for services, $179,907 in depreciation expenses and patent amortization expenses, ($136,264) in prepaid expenses and other current assets and ($118,884) in accounts payable and accrued expenses.  Net cash used in operating activities consisted of payments for research and development, legal, professional and consulting expenses, rent and other expenditures necessary to develop our business infrastructure.


Net cash used by investing activities was $309,480 for the year ended December 31, 2015, consisting of $29,577 in cost for intangibles and $279,903 in asset additions primarily for the new lab facility.


Net cash provided by financing activities was $4,315,000 for the year ended December 31, 2015 and consisted of $4,315,000 proceeds from private placement.




40





For the year ended December 31, 2014


Net cash used in operating activities was $3,140,203 for the year ended December 31, 2014, primarily attributable to the net loss of $4,409,797 adjusted by $148,681 in warrants issued for services, $824,726 in options issued for services, $41,362 in common stock issued for services, $151,183 in depreciation expenses and patent amortization expenses, $3,977 in prepaid expenses and $99,665 in accounts payable and accrued expenses.  Net cash used in operating activities consisted of payments for research and development, legal, professional and consulting expenses, rent and other expenditures necessary to develop our business infrastructure.


Net cash used in investing activities was $294,539 for the year ended December 31, 2014, consisting of $81,350 in cost for intangibles and $213,189 in asset additions primarily for the new lab facility.


Net cash provided by financing activities was $4,329,978 for the year ended December 31, 2014 and consisted of $3,140,000 proceeds from private placement, $1,036,148 in proceeds from sale of common stock to an institutional investor and $153,830 from the exercise of options and warrants.


Item 7A.

Quantitative and Qualitative Disclosures About Market Risk

 

Not Applicable

 

Item 8.

Financial Statements and Supplementary Data


Our Financial Statements of are attached as Appendix A (following Exhibits) and included as part of this Form 10-K Report.  A list of our Financial Statements is provided in response to Item 15 of this Form 10-K Report.

 

Item 9.

Changes In And Disagreements With Accountants On Accounting and Financial Disclosure

 

Not Applicable.

 

Item 9A.

Controls and Procedures.


Evaluation of Disclosure Controls and Procedures


As of the end of the period covered by this report, our Company evaluated the effectiveness and design and operation of its disclosure controls and procedures. Our Company’s disclosure controls and procedures are the controls and other procedures that we designed to ensure that our Company records, processes, summarizes, and reports in a timely manner the information that it must disclose in reports that our Company files with or submits to the Securities and Exchange Commission. Our principal executive officer and principal financial officer reviewed and participated in this evaluation. Based on this evaluation, our Company made the determination that its disclosure controls and procedures were effective.



Management's Report on Internal Control Over Financial Reporting


Our management is responsible for establishing and maintaining adequate internal control over financial reporting, as such term is defined in Exchange Act Rules 13a-15(f) and 15d-15(f). Under the supervision and with the participation of management, including our principal executive officer and principal financial officer, we conducted an evaluation of the effectiveness of our internal controls over financial reporting based on the framework in Internal Control -Integrated Framework issued by the Committee of Sponsoring Organizations of the Treadway Commission ("COSO"). Based on this evaluation, management has concluded that our internal control over financial reporting was effective as of December 31, 2015.


The Company's internal control over financial reporting includes policies and procedures that (1) pertain to maintenance of records that, in reasonable detail, accurately and fairly reflect transactions and dispositions of the assets of the Company; (2) provide reasonable assurance that transactions are recorded as necessary to permit preparation of financial statements in accordance with generally accepted accounting principles, and that receipts and expenditures of the Company are being made only in accordance with authorizations of management and directors of the Company; and (3) provide reasonable assurance regarding prevention or timely detection of unauthorized acquisition, use, or disposition of the Company's assets that could have a material effect on the financial statements.




41





Our management, including our principal executive officer and principal financial officer, does not expect that our disclosure controls or our internal control over financial reporting will prevent or detect all errors and all fraud. A control system, no matter how well designed and operated, can provide only reasonable, not absolute, assurance that the control system's objectives will be met. Internal control over financial reporting is a process that involves human diligence and compliance and is subject to lapses in judgment and breakdowns resulting from human failures. In addition, the design of any system of controls is based in part on certain assumptions about the likelihood of future events, and controls may become inadequate if conditions change. There can be no assurance that any design will succeed in achieving its stated goals under all potential future conditions.


This annual report does not include an attestation report of the Company’s independent registered public accounting firm regarding internal control over financial reporting. Management’s report was not subject to attestation by the Company’s registered public accounting firm pursuant to rules of the Securities and Exchange Commission that permit the Company to provide only management’s attestation in this annual report.


Changes in Company Internal Controls


No change in our Company’s internal control over financial reporting occurred during our fourth fiscal quarter that has materially affected, or is reasonably likely to materially affect, our internal control over financial reporting.


Item 9B.

Other Information


Not Applicable.










42






PART III


Item 10.

Directors, Executive Officers and Corporate Governance


Identity of directors, executive officers and significant employees


Name

Age

Position

  

  

  

Thomas E. Zelibor

61

Chair of the Board of Directors; Chief Executive Officer

James S. Marcelli

68

Director; President; Chief Operating Officer

Andrew J. Ashton

42

Director; Senior Vice President; Secretary

Terry Turpin

73

Optical Computing Expert(1)

William C. Pickett, III

72

Director

Joseph A. Miller

74

Director

Ronald A Bucchi

61

Director

Siraj Nour El-Ahmadi

51

Director

George L. Lauro

57

Director

Michael Lebby

54

Director


(1)

Our Optical Computing and signal processing expert is not an executive officer position, but our Company anticipates that Mr. Turpin’s expertise in optical computing and his respect in the optical computing community will significantly contribute to the development of our Company.


Business experience of directors, executive officers, and significant employees


Thomas E. Zelibor, Rear Admiral, USN (Ret). RADM Zelibor has served as our Chief Executive Officer and Chair of the Board of Directors (executive) since May 2012. RADM Zelibor previously served as Non-Executive Chair of the Board of Directors of our Company since October 2011, and has served as a director of our Company since July 2008. He also previously served on our Operation Committee. RADM Zelibor is in charge of the overall general management of the Company and supervision of Company policies, setting the Company’s strategies, formulating and overseeing the Company’s business plan, raising capital, expanding the Company’s management team and the general promotion of the Company. RADM Zelibor has over twenty years of strategic planning and senior leadership experience. Since April 2011 Mr. Zelibor served as the Chief Executive Officer and President of Zelibor & Associates, LLC, a management-consulting firm. From July 2008 to April 2011, Mr. Zelibor served as the Chief Executive Officer and President of Flatirons Solutions Corp., a professional services firm that provides consulting, systems integration, systems & software engineering, and program management expertise to corporate and government clients. Prior to that time, RADM Zelibor served in the U.S. Navy in a number of positions, including as the Dean of the College of Operational and Strategic Leadership at the United States Naval War College where he was responsible for the adoption of a corporate approach to leadership development; Director of Global Operations, United States Strategic Command; Director, Space, Information Warfare, Command and Control on the Navy staff; Department of the Navy, Deputy Chief Information Officer (CIO), Navy; Commander, Carrier Group Three and Commander, Naval Space Command.


Mr. James S. Marcelli. Mr. Marcelli has served as an officer and director of our Company since August 2008. Since May 2012 Mr. Marcelli has served as our Company’s President and Chief Operating Officer. Previously, from August 2008 to April 2012, Mr. Marcelli served as our President and Chief Executive Officer. Mr. Marcelli is in charge of the day-to-day operations of our Company and its movement to a fully functioning commercial corporation, and also serves as our Company’s principal financial officer. Since 2000, Mr. Marcelli has served as the president and chief executive officer of Marcelli Associates, a consulting company that offers senior management consulting, mentoring, and business development services to start-up and growth companies. Business segments Mr. Marcelli has worked with included an Internet networking gaming center, high-speed custom gaming computers, high tech manufacturing businesses and business service companies.

  

Mr. Andrew J. Ashton.  Mr. Ashton has served as an officer and director of our Company since July 2004. Mr. Ashton has served as our Senior Vice president since April 2009. Since 2004, his assistance in the creation of the synthetic chemistry of our novel molecular architecture has been fundamental to our Company's success.  His current duties include the development of chemical synthesis, providing extensive analytical support and assisting with our Company's management goals. Mr. Ashton is a skilled computer scientist and organic chemist who began his career in 1998 at the Army Research Laboratory on the Aberdeen Proving Grounds where he helped to design and implement computer interfaces for fiberglass composite analysis.



43





Mr. Terry Turpin. Mr. Turpin has served as our Optical Computing expert since March 2008. Since October 2006, Mr. Turpin has been a member of the UMBC College of Natural Science and Mathematics Advisory Board. Until January 2007, when Northrop Grumman Space & Mission Systems Corp. acquired Essex Corporation, Mr. Turpin was a director of Essex Corporation. Mr. Turpin remained Senior Vice President and Chief Scientist for Essex Corporation after its acquisition until April 2007. Mr. Turpin was appointed as a director of Essex Corporation in January 1997 and became its Senior Vice President and Chief Scientist in 1996. He joined Essex Corporation through a merger with SEDC where he was Vice President and Chief Scientist from September 1984 through June 1989. From December 1983 to September 1984 he was an independent consultant. From 1963 through December 1983, the National Securities Agency (NSA) employed Mr. Turpin. He was Chief of the Advanced Processing Technologies Division for ten years. He holds patents for optical computers and adaptive optical components. Mr. Turpin represented NSA on the Tri-Service Optical Processing Committee organized by the Under Secretary of Defense for Research and Engineering. He received a Bachelor of Science degree in Electrical Engineering from the University of Akron in 1966 and a Master of Science degree in Electrical Engineering from Catholic University in Washington, D.C. in 1970.


Mr. William C. Pickett. Mr. Pickett has served as a director of our Company since January 2008. Mr. Pickett enjoyed a 32 year career with E.I. DuPont de Nemours & Co., where he worked in numerous financial leadership positions, including serving from February 2002 to April 2004 as Chief Financial Officer of Invista, DuPont’s $7 billion man-made fibers company, which was ultimately sold to Koch Industries, Inc. From 2005 through 2011, Mr. Pickett served on the Board of Directors of the Ronald McDonald House of Delaware. He also served as Treasurer, was a member of the Executive Committee, and chaired the Finance Committee. From 2004 through 2015, Mr. Pickett served on the Board of Trustees of Operation Warm, a not-for-profit organization, and chaired their Audit Committee. Mr. Pickett received his MBA from the Harvard Business School and a BA from Trinity College.  


Dr. Joseph A. Miller, Jr.  Dr. Miller has served as a director of our Company since May 10, 2011.  From 2002 to May 2012, Dr. Miller served as Executive Vice President and Chief Technology Officer of Corning Incorporated, having joined Corning Incorporated in 2001 as Senior Vice President and Chief Technology Officer.  Prior to joining Corning Incorporated, Dr. Miller was with E.I. DuPont de Nemours, Inc., where he served as Chief Technology Officer and Senior Vice President for Research and Development since 1994.  Dr. Miller began his career with DuPont in 1966.  Dr. Miller is a director and Non-executive Chairman of Nuvectra Corp.  He holds a doctorate degree in Chemistry from Penn State University.  


Mr. Ronald A. BucchiMr. Bucchi has served as a director of our Company since June 11, 2012.  Mr. Bucchi is currently a self employed C.P.A. with a specialized practice that concentrates in CEO consulting, strategic planning, mergers, acquisitions, business sales and tax. He works with domestic and international companies. Mr. Bucchi is currently a member of the board of directors of First Connecticut Bancorp, Inc. (Farmington Bank) (FBNK:NASDAQ GM), serving on Asset Liability Committee, the Governance and Loan committees in addition to chairing the Audit committee. He is currently the Treasurer and a member of the Board of Directors of the Petit Family Foundation, Inc. He has served on numerous other community boards and is past Chairman of the Wheeler Clinic and the Wheeler YMCA. He is a member of the Connecticut Society of Certified Public Accountants, American Institute of Certified Public Accountants and the National Association of Corporate Directors. Mr. Bucchi is a graduate of the Harvard Business School Executive Education program with completed course studies in general board governance, audit and compensation and a graduate of Central Connecticut State University where he received his B.S. in Accounting.


Mr. Siraj Nour El-Ahmadi. Mr. El-Ahmadi has served as a director of our Company since October 2, 2013. Since 2004, Mr. El-Ahmadi has served as Founder, President and Chief Executive Officer of Menara Networks, a developer of innovative products and solutions that simplify layered optical transport networks. Mr. El-Ahmadi has over 17 years of experience in optical transmission in particular and the telecom industry in general. Prior to founding Menara, Mr. El-Ahmadi served as Vice President-Marketing & Product Management at Nortel where he was responsible for the OPTera LH 4000 ULR product (acquired from Qtera) that achieved over $200M in revenues in its first two years. Prior to that, Mr. El-Ahmadi was the Product Architect & Vice President of Product Management at Qtera Corporation, a successful technology start-up acquired by Nortel in 2000 for $3.25 billion. Mr. El-Ahmadi also held a Senior Manager position at Bell Northern Research and worked as a Transmission Engineer at WilTel (WorldCom) where he evaluated and deployed the world first bidirectional EDFA and bi-directional WDM transmission. Mr. El-Ahmadi holds a BS and MS in Electrical Engineering from the University of Oklahoma, is a member of Eta Kappa Nu and is the inventor of 11 patents, issued or pending, in the area of optical communications. He has authored a number of publications and is a frequent speaker at telecom and optical networking events and conferences.




44





Mr. George L Lauro. Mr. Lauro has served as a director of our Company since May 12, 2014. Since 2009, Mr. Lauro has served as Founder/Partner of Alteon Capital Partners, a Venture Capital Advisory firm. Mr. Lauro has 25 years of experience as a technology entrepreneur, operating executive and venture capitalist. He was a Managing Director at Wasserstein Perella, and head of West Coast technology investing. He has led and syndicated 18 private equity financing rounds and control deals, raising over $100M equity financing for portfolio companies and completed over $1 billion in M&A transactions. Mr. Lauro began his career in the hi-tech industry holding positions primarily focused on the commercialization of emerging technologies. He served as the Director of Technology Commercialization at IBM where he was responsible for transitioning technologies from research labs to the market. Also, he was the Director of New Business Development for Motorola. Mr. Lauro has previously served on numerous corporate boards of both public and private technology companies. Mr. Lauro holds a B.S. in Electrical Engineering from Brown University, a MBA from Wharton School – University of Pennsylvania, and he participated in aeronautical engineering graduate studies at MIT.


Dr. Michael Lebby. Dr. Lebby has served as a director of our Company since August 26, 2016. From June 2013 to present, Dr. Lebby has served as President and CEO of OneChip Photonics, Inc., a privately held company headquartered in Ottawa, Canada, that is a leading provider of low-cost, small-footprint, high-performance indium phosphide (InP)-based photonic integrated circuits (PICs) and PIC-based optical sub-assemblies (OSAs) for the Data Center markets. Also, Dr. Lebby presently serves as part-time full professor, and chair of optoelectronics at Glyndwr University in Wales, UK, and as a consultant to bring forward advanced materials, device, and integrated photonics technologies that will generate high margin value as products.  Since 2015, Dr. Lebby has been focusing on InP-based photonic integrated circuits (PICs) and optoelectronic integrated circuits (OEICs) for the datacenter segment and has been instrumental in assembling California’s proposal (via USC) to the Federal Government for an integrated photonics manufacturing institute.  Dr. Lebby holds a Doctor of Engineering, a Ph.D., a MBA and a Bachelors degree, all from the University of Bradford, United Kingdom.


The Board of Directors believes that each of the Directors named above has the necessary qualifications to be a member of the board of directors. Each Director has exhibited during his prior service as a director the ability to operate cohesively with the other members of the board of directors. Moreover, the Board of Directors believes that each director brings a strong background and skill set to the Board of Directors, giving the Board of Directors as a whole competence and experience in diverse areas, including corporate governance and board service, finance, management and industry experience.


Our bylaws provide that the number of directors who constitute our Board of Directors is determined by resolution of the Board of Directors, but the total number of directors constituting the entire Board of Directors shall not be less than three or more than nine. Our Board of Directors currently consists of nine directors. On July 25, 2013, certain provisions of our bylaws were amended, including provisions relating to: (i) Classes of Directors, whereby the Board of Directors is divided into three classes, as nearly equal in number as possible, designated: Class I, Class II and Class III. Prior to the amendment, there was only one class of directors; and (ii) Terms of Office, whereby provisions were created for staggered terms with each director serving for a term ending on the date of the third annual meeting following the annual meeting at which such director was elected; provided, that each director initially appointed to Class I shall serve for an initial term expiring at the first annual meeting of stockholders following the effectiveness of this provision; each director initially appointed to Class II shall serve for an initial term expiring at the second annual meeting of stockholders following the effectiveness of this provision; and each director initially appointed to Class III shall serve for an initial term expiring at the third annual meeting of stockholders following the effectiveness of this provision; provided further, that the term of each director shall continue until the election and qualification of a successor and be subject to such director's earlier death, resignation or removal. Prior to the amendment, there were no staggered terms and each director served for a term of one (1) year.


Section 16(a) Beneficial Ownership Reporting Compliance


Section 16(a) of the Securities Exchange Act of 1934 requires that our executive officers and directors, and persons who own more than ten percent of a registered class of our equity securities, file reports of ownership and changes in ownership with the SEC.  Executive officers, directors and greater-than-ten percent stockholders are required by SEC regulations to furnish us with all Section 16(a) forms they file.  To the best of our knowledge, based solely upon a review of Forms 3 and 4 and amendments thereto furnished to our Company during its most recent fiscal year and Forms 5 and amendments thereto furnished to our Company with respect to its most recent fiscal year, and any written representation referred to in paragraph (b)(1) of Item 405 of Regulation S-K, all of our executive officers, directors and greater-than-ten percent stockholders complied with all Section 16(a) filing requirements with the following exception: Mr. George Lauro filed one late Form 4 to report shares he acquired directly from the Company in connection with his Operations Committee work.




45





Code of Ethics


Our Company has adopted a Code of Ethics and Business Conduct that applies to all of the Company’s employees, including its principal executive officer and principal accounting officer. A copy of our Code of Ethics is available for review on the “Investors” page of our Company’s website www.lightwavelogic.com. The Company intends to disclose any changes in or waivers from its Code of Ethics by posting such information on its website.

 

Nominating Committee


Our Board of Directors does not have a nominating committee. This is due to our development stage and smaller sized Board of Directors. Instead of having such a committee, our entire Board of Directors historically has searched for and evaluated qualified individuals to become nominees for membership on our Board of Directors. No material changes to the procedures by which our stockholders may recommend nominees to our Board of Directors has occurred since we last provided disclosure regarding these procedures in our Definitive Schedule 14A filed on April 7, 2015.


Audit Committee


Our Company has in place a separately designated standing audit committee in accordance with Section 3(a)(58)(A) of the Securities Exchange Act of 1934, as amended. Our audit committee is governed by an audit committee charter, a current copy of which is available to security holders on our web site located at www.lightwavelogic.com.


Our audit committee has reviewed and discussed the audited financial statements with management and has discussed with its independent auditors the matters required to be discussed by the statement on Auditing Standards No. 61, as amended (AICPA, Professional Standards, Vol. 1, AU section 380) as adopted by the Public Company Accounting Oversight Board in Rule 3200T.  The audit committee has received the written disclosures and the letter from its independent accountant required by applicable requirements of the Public Company Accounting Oversight Board regarding the independent accountant’s communications with the audit committee concerning independence, and has discussed with its independent accountant its independent accountant’s independence. Based on the review and discussions described above, the audit committee recommended that the audited financial statements be included in our Annual Report on Form 10-K for the last fiscal year for filing with the Securities and Exchange Commission.


Our audit committee is comprised of Ronald A. Bucchi, William C. Pickett, III and George L. Lauro.  Mr. Bucchi serves as our audit committee financial expert as that term is defined by the rules promulgated by the Securities and Exchange Commission. Mr. Bucchi is an independent director, as defined below in Certain Relationships and Related Transactions, and Director Independence.


Item 11.

Executive Compensation.


The table below summarizes all compensation awarded to, earned by, or paid to our named executive officers for the fiscal years ended December 31, 2015 and 2014.


Summary Compensation Table


Name and Principal Position


(a)

Year


(b)

Salary

($)

(c)

Bonus

($)

(d)

Stock Awards

($)

(e)

Option

Awards

($)

(f)

All Other

Compensation

($)

(i)

Total

($)

(j)

 

 

 

 

 

 

 

 

Thomas E. Zelibor

2015

352,440

0

0

188,402

0

540,842

CEO, Chmn. of the Board (1)

2014

301,834

0

0

  78,979

0

380,813

 

 

 

 

 

 

 

 

James S. Marcelli

2015

221,317

0

0

522,716

0

744,033

President, COO, Director (2)

2014

217,160

0

0

  20,425

0

237,585




46





1.

Pursuant to an employment agreement, effective May 1, 2012, Mr. Zelibor received an option to purchase up to 500,000 shares of common stock at an exercise price of $1.30 per share. The options vest quarterly over one year in equal installments of 125,000 shares per quarter beginning May 1, 2012. The employment agreement was amended on August 29, 2013, and effective September 1, 2013, his receives a salary of $18,750 per month. Pursuant to a new employment agreement dated March 3, 2014, Mr. Zelibor receives a salary of $25,000 per month effective January 1, 2014, a salary of $29,166.66 per month effective January 1, 2015 and an option to purchase up to 40,000 shares of common stock at an exercise price of $0.92 per share. The options vest quarterly over one year in equal installments of 10,000 beginning April 1, 2014. On July 11, 2008, Mr. Zelibor was awarded an option to purchase up to 100,000 shares of common stock at an exercise price of $1.75 per share. The option vests 25,000 shares immediately and the remaining annually over three years in equal annual installments of 25,000 shares per year beginning July 11, 2009. On November 9, 2012 the options were extended to July 10, 2015. On August 29, 2008, Mr. Zelibor was awarded an option to purchase up to 150,000 shares of common stock at an exercise price of $1.42 per share. The option vests 37,500 shares immediately and the remaining annually over three years in equal annual installments of 37,500 shares per year beginning August 29, 2009. On November 9, 2012 the options were extended to August 28, 2015. On December 13, 2010, Mr. Zelibor was awarded an option to purchase up to 100,000 shares of common stock at an exercise price of $1.00 per share. The option vests 25,000 shares immediately and the remaining annually over three years in equal annual installments of 25,000 shares per year beginning November 4, 2011. On December 19, 2011, Mr. Zelibor was awarded an option to purchase up to 250,000 shares of common stock at an exercise price of $1.01 per share. The option vests 62,500 shares immediately and the remaining annually over three years in equal annual installments of 62,500 shares per year beginning December 19, 2011. On July 1, 2015, the options issued July 11, 2008, August 29, 2008 and December 2010 totaling 350,000 shares were cancelled, and on that same date, Mr. Zelibor was granted an option to purchase up to 350,000 shares of Company stock at an exercise price of $.70 per share that vested immediately.   On November 10, 2015, Mr. Zelibor was granted an option to purchase up to 100,000 shares of Company stock at an exercise price of $.86 per share. The option vests 12,500 shares on January 1, 2016 and the remaining vest quarterly in equal installments of 12,500 shares beginning April 1, 2016. The compensation includes the amount for services rendered to the Company in his capacity as both an officer and a director.


2.

Effective August 1, 2013, Mr. Marcelli receives a salary of $17,917 per month and an option to purchase up to 100,000 shares of common stock at an exercise price of $1.00 per share. The options vest in equal installments of 25,000 options with the first installment vesting on August 1, 2013 and the remaining installments vesting quarterly commencing on October 1, 2013. Pursuant to previous employment agreements, Mr. Marcelli received, among other things, (i) an option to purchase up to 100,000 shares of common stock at an exercise price of $1.50 per share. The options vest quarterly over two years in equal installments of 12,500 shares per quarter beginning August 1, 2010; and (ii) an option to purchase up to 1,050,000 shares of common stock at an exercise price of $1.75 per share. The options vest quarterly over three years in equal installments of 87,500 shares per quarter beginning November 1, 2008. On November 9, 2012 the options were extended to July 31, 2015. Additionally, in the event Mr. Marcelli’s employment terminates upon his death and the key man life insurance is in place for Mr. Marcelli, our Company will continue to pay the base cash compensation described in Mr. Marcelli’s employment agreement to his estate through the remainder of term of his employment agreement, or 90 days, whichever is longer. On July 1, 2015, the options issued August 1, 2010 and August 1, 2013 totaling 1,150,000 shares were cancelled, and on that same date, Mr. Marcelli received an option to purchase up to1,150,000 shares of Company stock at an exercise price of $.70 that vested immediately.    Pursuant to an employment agreement amendment, effective August 1, 2015, Mr. Marcelli receives a salary of $18,750 per month and an option to purchase 50,000 shares of common stock.  The options vest 12,500 immediately and the remainder in equal quarterly installments of 12,500 shares.  The compensation includes the amount for services rendered to the Company in his capacity as both an officer and a director.


Other than as described above, at no time during the last fiscal year was any outstanding option otherwise modified or re-priced, and there was no tandem feature, reload feature, or tax-reimbursement feature associated with any of the stock options we granted to our executive officers or otherwise.


We grant stock awards and stock options to our executive officers based on their level of experience and contributions to our Company. The aggregate fair value of awards and options are computed in accordance with FASB ASC 718 and are reported in the Summary Compensation Table above in the columns (e) and (f).




47





The table below summarizes all of the outstanding equity awards for our named executive officers as of December 31, 2015, our latest fiscal year end.


Outstanding Equity Awards At Fiscal Year-End


 

Option Awards

Stock Awards

Name


   (a)

Number of
securities
underlying
unexercised
options(#) exercisable


(b)

Number of
securities
underlying unexercised
options(#) unexercisable


(c)

Equity incentive plan awards: number of
securities
underlying
unexercised
unearned
options

(#)

(d)

Option

exercise

price

($)

(e)

Option

expiration

date


(f)

Number of shares or units of stock that have not

vested

(#)

(g)

Market value of  shares of units of stock that have not

vested

($)

(h)

Equity incentive plan awards: number of unearned shares, units or other rights that have not

vested

(#)

(i)

Equity incentive plan awards: market or payout value of unearned shares, units or other rights that have not

vested

($)

(j)

 

 

 

 

 

 

 

 

 

 

Thomas E. Zelibor

CEO, Chairman of the

100,000

0.86

11/09/25

Board(1)(3)

   350,000

0.70

6/30/25

 

   250,000

1.01

12/19/16

 

   500,000

1.30

4/30/22

 

     40,000

0.92

3/4/24

 

 

 

 

 

 

 

 

 

 

James S. Marcelli

     25,000

  25,000

 

0.67

8/9/25

President, COO,

1,150,000

0.70

6/30/25

Director(2)(3)

   100,000

1.00

5/16/23


(1)

On November 10, 2015, Mr. Zelibor received an option to purchase up to 100,000 shares of Company stock at an exercise price of $.86 per share. The option vests 12,500 shares on January 1, 2016 and the remaining vest quarterly in equal installments of 12,500 shares beginning April 1, 2016. On July 1, 2015, Mr. Zelibor received an option to purchase up to 350,000 shares of Company stock at an exercise price of $.70 that vested immediately. On March 4, 2014, Mr. Zelibor received an option to purchase 40,000 shares of common stock at an exercise price of $0.92 per share. The options vested quarterly over one year in equal installments of 10,000 beginning April 1, 2014. On May 1, 2012, Mr. Zelibor received an option to purchase up to 500,000 shares of common stock at an exercise price of $1.30 per share. The options vested quarterly over one year in equal installments of 125,000 shares per quarter beginning May 1, 2012.  On December 19, 2011, Mr. Zelibor received an option to purchase up to 250,000 shares of common stock at an exercise price of $1.01 per share. The option vested 62,500 shares immediately and the remaining annually over three years in equal annual installments of 62,500 shares per year beginning December 19, 2011.

(2)

On August 10, 2015, Mr. Marcelli received an option to purchase 50,000 shares of common stock.  The options vest 12,500 immediately and the remainder in equal quarterly installments of 12,500 shares.  On July 1, 2015, Mr. Marcelli received an option to purchase up to 1,150,000 shares of Company stock at an exercise price of $.70 that vested immediately.  August 1, 2013, Mr. Marcelli received an option to purchase up to 100,000 shares of common stock. The options vested in equal installments of 25,000 options with the first installment vesting on August 1, 2013 and the remaining installments vesting quarterly commencing on October 1, 2013.  

(3)

In the event of a change in control of our Company, such person’s options will become fully vested and/or exercisable, as the case may be, immediately prior to such change in control, and shall remain exercisable as set forth in their stock option agreement.




48





Compensation of Directors


Set forth below is a summary of the compensation of our directors during our December 31, 2015 fiscal year.


Name

Fees Earned or Paid in Cash
($)

Stock Awards

($)

Option Awards

($)

Non-Equity Incentive
Plan Compensation
($)

Non-Qualified Deferred Compensation Earnings
($)

All
Other Compensation

($)

Total

($)

 

 

 

 

 

 

 

 

Thomas E. Zelibor (1)

James S. Marcelli (1)

Andrew J. Ashton (1)

William C. Pickett, III (2)

180,115

180,115

Joseph A. Miller (3)

  24,901

  24,901

Ronald A. Bucchi, (4)

  40,909

  40,909

Siraj Nour El-Ahmadi (5)

  68,428

  68,428

George L. Lauro (6)

18,871

10,000

  55,529

  84,400

Michael Lebby (7)

15,581

8,387

  30,518

  54,486


(1)

Serves as an executive officer and a director, but receives no additional compensation for serving as a director.

(2)

On January 1, 2014, Mr. Pickett received an option to purchase up to 50,000 shares of Company stock at an exercise price of $0.715 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in equal quarterly installments of 10,000 per quarter commencing on April 1, 2014.  On March 4, 2015, Mr. Pickett received an option to purchase up to 50,000 shares of Company stock at an exercise price of $0.80 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in 3 equal annual installments of 10,000 options per year commencing on April 1, 2015.  On July 1, 2015, Mr. Pickett received an option to purchase up to 350,000 shares of Company stock at an exercise price of $.70 that vested immediately.  

(3)

On May 10, 2011, Mr. Miller received an option to purchase up to 200,000 shares of Company stock at an exercise price of $1.12 that vest pursuant to the following schedule: 50,000 shares vested immediately; and the remaining options vest in 3 equal annual installments of 50,000 options per year commencing on May 10, 2012. On January 1, 2014, Mr. Miller received an option to purchase up to 50,000 shares of Company stock at an exercise price of $0.715 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in equal quarterly installments of 10,000 per quarter commencing on April 1, 2014.  On March 4, 2015, Mr. Miller received an option to purchase up to 50,000 shares of Company stock at an exercise price of $0.80 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in 3 equal annual installments of 10,000 options per year commencing on April 1, 2015.

(4)

On June 11, 2012, Mr. Bucchi received an option to purchase up to 200,000 shares of Company stock at an exercise price of $0.90 that vest pursuant to the following schedule: 50,000 shares vested immediately; and the remaining options vest in 3 equal annual installments of 50,000 options per year commencing on June 11, 2013. On August 29, 2013, Mr. Bucchi received an option to purchase up to 50,000 shares of Company stock at an exercise price of $0.84 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in equal quarterly installments of 10,000 options per quarter commencing on October 1, 2013. On January 1, 2014, Mr. Bucchi received an option to purchase up to 50,000 shares of Company stock at an exercise price of $0.715 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in equal quarterly installments of 10,000 per quarter commencing on April 1, 2014.  On March 4, 2015, Mr. Bucchi received an option to purchase up to 50,000 shares of Company stock at an exercise price of $0.80 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in 3 equal annual installments of 10,000 options per year commencing on April 1, 2015.



49





(5)

On November 1, 2013, Mr. Siraj Nour El-Ahmadi received an option to purchase up to 200,000 shares of Company stock at an exercise price of $0.93 that vest pursuant to the following schedule: 50,000 shares on November 1, 2013 and the remaining options vest in equal annual installments of 50,000 options per year commencing on November 1, 2014. On January 1, 2014, Mr. Siraj Nour El-Ahmadi received an option to purchase up to 50,000 shares of Company stock at an exercise price of $0.715 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in equal quarterly installments of 10,000 per quarter commencing on April 1, 2014.  On March 4, 2015, Mr. Siraj Nour El-Ahmadi received an option to purchase up to 50,000 shares of Company stock at an exercise price of $0.80 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in 3 equal annual installments of 10,000 options per year commencing on April 1, 2015.

(6)

During 2015 Mr. Lauro received $18,871 in cash and 12,040 shares of common stock as compensation for serving on our Operations Committee. On May 12, 2014, Mr. Lauro received an option to purchase up to 200,000 shares of Company stock at an exercise price of $0.763 that vest pursuant to the following schedule: 50,000 shares vested immediately; and the remaining options vest in 3 equal annual installments of 50,000 options per year commencing on May 12, 2015.  On March 4, 2015, Mr. Lauro received an option to purchase up to 50,000 shares of Company stock at an exercise price of $0.80 that vest pursuant to the following schedule: 20,000 shares vested immediately; and the remaining options vest in 3 equal annual installments of 10,000 options per year commencing on April 1, 2015.

(7)

During 2015 Mr. Lebby received $15,581 in cash and 12,718 shares of common stock as compensation for serving on our Operations Committee. On August 26, 2015, Mr. Lebby received an option to purchase up to 200,000 shares of Company stock at an exercise price of $0.69 that vest pursuant to the following schedule: 50,000 shares vested immediately; and the remaining options vest in 3 equal annual installments of 50,000 options per year commencing on August 26, 2016.

 

In the event of a change in control of our Company, all of the above person’s options become fully vested and/or exercisable, as the case may be, immediately prior to such change in control, and shall remain exercisable as set forth in their stock option agreement.  


Compensation Committee


Our Board of Directors currently has no standing compensation committee or committee performing similar functions. This is due to the Company’s development stage, lack of business operations, the small number of executive officers involved with the Company, and the fact that the Company operates with few employees. The Company’s entire Board of Directors currently participates in the consideration of executive officer and director compensation. Our Board of Directors will continue to evaluate, from time to time, whether it should appoint standing compensation committee.


Compensation Policies and Practices As They Relate To Our Risk Management


No risks arise from our Company’s compensation policies and practices for our employees that are reasonably likely to have a material adverse effect on our Company.



















50






Item 12.

Security Ownership of Certain Beneficial Owners and Management and Related Stockholder Matters.


The following table sets forth, as of March 17, 2016, the names, addresses, amount and nature of beneficial ownership and percent of such ownership of each person or group known to our Company to be the beneficial owner of more than five percent (5%) of our common stock:


Security Ownership of Certain Beneficial Owners


Name and Address of Beneficial Owner (1)

 

Amount and Nature

of Beneficial Ownership (3)

 

% of Class Owned (4)

 

 

 

 

 

 

Frederick J. Goetz, Jr. (2)

 

3,319,542

 

 

5.06%

Mary Goetz (2)

 

4,517,306

 

 

6.88%


(1)

In care of our Company at 1831 Lefthand Circle, Suite C, Longmont, CO 80501.

(2)

Frederick J. Goetz, Jr. is Mary Goetz’s son.

(3)

To our best knowledge, as of the date hereof, such holders had the sole voting and investment power with respect to the voting securities beneficially owned by them, unless otherwise indicated herein. Includes the person's right to obtain additional shares of common stock within 60 days from the date hereof.

(4)

Based on 65,591,629 shares of common stock outstanding on March 17, 2016. Does not include shares underlying: (i) options to purchase shares of our common stock under our 2007 Plan, or (ii) outstanding warrants to purchase shares of our common stock.


The following table sets forth, as of March 17, 2016, the names, addresses, amount and nature of beneficial ownership and percent of such ownership of our common stock of each of our officers and directors, and officers and directors as a group:


Security Ownership of Management


Name and Address (1)

 

Amount and Nature

of Beneficial Ownership (2)

 

% Owned (3)(4)

 

 

 

 

 

 

Thomas E. Zelibor
Chief Executive Officer, Principal Executive Officer and Chmn. of the Board of Directors

 

1,221,824

(5)

 

1.86%

James S. Marcelli
President, Chief Operating Officer, Principal Financial Officer and Director

 

1,578,400

(6)

 

2.40%

Andrew J. Ashton
Senior Vice President, Secretary, and Director

 

2,981,667

 

 

4.54%

William C. Pickett, III

Director

 

601,000

(7)

 

*

Joseph A. Miller, Jr.

Director

 

356,800

(8)

 

*

Ronald A. Bucchi

Director

 

567,400

(9)

 

*

Siraj Nour El-Ahmadi

Director

 

280,000

(10)

 

*

George L. Lauro

Director

 

257,727

(11)

 

*

Michael Lebby

Director

 

96,468

(12)

 

*

Directors and Officers as a Group (9 Persons):

 

7,941,286

 

 

12.10%

———————

* Less than 1%.


(1)

In care of our Company at 1831 Lefthand Circle, Suite C, Longmont, CO 80501.



51





(2)

To our best knowledge, as of the date hereof, such holders had the sole voting and investment power with respect to the voting securities beneficially owned by them, unless otherwise indicated herein. Includes the person's right to obtain additional shares of common stock within 60 days from March 17, 2016.

(3)

Based on 65,591,629 shares of common stock outstanding on March 17, 2016. Does not include shares underlying: (i) options to purchase shares of our common stock under our 2007 Plan and (ii) outstanding warrants to purchase shares of our common stock.

(4)

If a person listed on this table has the right to obtain additional shares of common stock within 60 days from March 17, 2016, the additional shares are deemed to be outstanding for the purpose of computing the percentage of class owned by such person, but are not deemed to be outstanding for the purpose of computing the percentage of any other person.

(5)

Consists of 50,124 shares of common stock, an option to purchase up to 1,165,000 shares of common stock exercisable within 60 days from March 17, 2016 and a warrant to purchase up to 6,700 shares of common stock exercisable within 60 days from March 17, 2016.

(6)

Consists of 246,700 shares of common stock, an option to purchase up to 1,325,000 shares of common stock exercisable within 60 days from March 17, 2016, and a warrant to purchase up to 6,700 shares of common stock exercisable within 60 days from March 17, 2016.

(7)

Consists of 21,000 shares of common stock and an option to purchase up to 580,000 shares of common stock exercisable within 60 days from March 17, 2016.

(8)

Consists of 13,400 shares of common stock, options to purchase up to 330,000 shares of common stock exercisable within 60 days from March 17, 2016 and warrants to purchase up to 13,400 shares of common stock exercisable within 60 days from March 17, 2016.

(9)

Consists of 174,000 shares of common stock, an option to purchase up to 380,000 shares of common stock exercisable within 60 days from March 17, 2016 and warrants to purchase up to 13,400 shares of common stock exercisable within 60 days from March 17, 2016. Mr. Bucchi disclaims beneficial ownership of 53,000 shares held by his spouse.

(10)

Consists of an option to purchase up to 280,000 shares of common stock exercisable within 60 days from March 17, 2016.

(11)

Consists of 27,727 shares of common stock and options to purchase up to 230,000 shares of common stock exercisable within 60 days from March 17, 2016.

(12)

Consists of 16,468 shares of common stock and an option to purchase up to 80,000 shares of common stock exercisable within 60 days from March 17, 2016.


We are not aware of any arrangements that could result in a change of control.


Securities Authorized for Issuance under Equity Compensation Plans


Information regarding our compensation plans under which our equity securities are authorized for issuance can be found in Part II –Item 5 of this report.


Item 13.

Certain Relationships and Related Transactions, and Director Independence.


No related party transaction was required to be reported under this Item 13.


Policies and Procedures for Related-Party Transactions


Our Company does not have any formal written policies or procedures for related party transactions, however in practice, our board of directors reviews and approves all related party transactions and other matters pertaining to the integrity of management, including potential conflicts of interest, trading in our securities, or adherence to standards of business conduct.


Director Independence

 

Although we are currently traded on the Over-the-Counter Markets, our Board has reviewed each of the directors’ relationships with the Company in conjunction with Section 121 and Part 8 (Corporate Governance Requirements) of the listing standards of the NYSE Alternext US and has affirmatively determined that five of our directors, William C. Pickett, III, Joseph A. Miller, Jr. Ronald A. Bucchi, Siraj Nour El-Ahmadi, George L. Lauro, and Michael Lebby are independent directors in that they are independent of management and free of any relationship that would interfere with their independent judgment as members of our Board of Directors.  Mr. Bucchi serves as our audit committee financial expert as that term is defined by the rules promulgated by the Securities and Exchange Commission.




52





Our Company does not have a separately designated nominating or compensation committee or committee performing similar functions; therefore, our full Board of Directors currently serves in these capacities. Three members of our Board of Directors, Thomas E. Zelibor, James S. Marcelli and Andrew J. Ashton, are not are independent directors pursuant to the standards described above.


Item 14.

Principal Accounting Fees and Services.


Audit Fees.


The aggregate fees billed for the years ended December 31, 2015 and 2014 for professional services rendered by Morison Cogen, LLP for the audit of the Company’s annual financial statements and review of financial statements included in the Company’s Form 10-Q or services that are normally provided by Morison Cogen, LLP in connection with statutory and regulatory filings or engagements were $54,400 for the year ended December 31, 2015; and $51,330 for the year ended December 31, 2014.


Audit-Related Fees.


Fees billed for the years ended December 31, 2015 and December 31, 2014 for assurance and related services by Morison Cogen, LLP that are reasonably related to the performance of the audit or review of the Company’s financial statements and are not reported under the category Audit Fees described above were $0 for the year ended December 31, 2015 and $0 for the year ended December 31, 2014.


Tax Fees.


Fees billed for the year ended December 31, 2015 for tax compliance by Morison Cogen, LLP was $6,000; and for the year ended December 31, 2014 was $6,000.


All Other Fees.


Fees billed for the years ended December 31, 2015 and December 31, 2014 for products and services provided by Morison Cogen, LLP, other than the services reported in the Audit Fees, Audit-Related Fees, and Tax Fees categories above were $0 for year ended December 31, 2015 and 2014.


Audit Committee Pre-Approval Policies.


The Company’s audit committee currently does not have any pre-approval policies or procedures concerning services performed by Morison Cogen, LLP. All the services performed by Morison Cogen, LLP that are described above were pre-approved by the Company’s audit committee.


None of the hours expended on Morison Cogen, LLP ‘s engagement to audit the Company’s financial statements for the years ended December 31, 2015 were attributed to work performed by persons other than Morison Cogen, LLP’s full-time, permanent employees.



53





PART IV


Item 15.

Exhibits, Financial Statement Schedules


(a)

The following Audited Financial Statements are filed as part of this Form 10-K Report:

 

 

 

Report of Independent Registered Public Accounting Firm

 

 

 

Balance Sheets

 

 

  

Statements of Operations

 

 

  

Statement of Stockholders’ Equity

 

 

  

Statements of Cash Flows

 

 

  

Notes to Financial Statements

 

 

(b)

The following exhibits are filed as part of this report.


Exhibit No.

 

Description of Exhibit

 

Location

3.1

 

Articles of Incorporation

 

Incorporated by reference to Company’s Form 10-SB as filed with the SEC on April 13, 2007

3.2

 

Certificate of Amendment to Articles of Incorporation

 

Incorporated by reference to Company’s Definitive Schedule 14C Information Statement as filed with the SEC on February 19, 2008

3.3

 

Certificate of Amendment to Articles of Incorporation filed June 8, 2015

 

Incorporated by reference to Company’s Form S-1 Registration  Statement as filed with the SEC on August 3, 2015

10.1

 

Form of June 15, 2015 Subscription Agreement

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on June 15, 2015

10.2

 

Form of June 15, 2015 Warrant

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on June 15, 2015

10.3

 

Employee Agreement - James Marcelli

 

Incorporated by reference to Company’s Form 10-Q as filed with the SEC on August 12, 2015

10.4

 

Director Agreement - Michael Lebby

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on August 27, 2015

10.5

 

Statement Of Operations Committee Work

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on August 27, 2015

10.6

 

Employee Agreement Amendment – Thomas E. Zelibor

 

Incorporated by reference to the Company's Form 10-Q as filed with the SEC on November 16, 2015

10.7

 

Form of Regulation D Subscription Agreement

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on December 31, 2015

10.8

 

Form of Regulation S Subscription Agreement

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on December 31, 2015

10.9

 

Form of Regulation D Warrant

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on December 31, 2015

10.10

 

Form of Regulation S Warrant

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on December 31, 2015

10.11

 

Purchase Agreement, dated as of January 29, 2016, by and between the Company and Lincoln Park Capital Fund, LLC

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on February 1, 2016

10.12

 

Registration Rights Agreement, dated as of January 29, 2016, by and between the Company and Lincoln Park Capital Fund, LLC

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on February 1, 2016

10.13

 

Termination Agreement, dated as of February 1, 2016, by and between the Company and Lincoln Park Capital Fund, LLC

 

Incorporated by reference to the Company's Form 8-K as filed with the SEC on February 1, 2016



54








14.1

  

Code of Ethics and Business Conduct

  

Incorporated by reference to the Company’s Annual Report on Form 10-K as filed with the SEC on April 1, 2013

31.1

 

Certification pursuant to Rule 13a-14(a) of the Securities Exchange Act of 1934, as amended, executed by the Principal Executive Officer of the Company.

 

Filed herewith

31.2

 

Certification pursuant to Rule 13a-14(a) of the Securities Exchange Act of 1934, as amended, executed by the Principal Financial Officer of the Company.

 

Filed herewith

32.1

 

Certification pursuant to 18 U.S.C. Section 1350, as adopted pursuant to Section 906 of the Sarbanes-Oxley Act of 2002, executed by the Principal Executive Officer of the Company.

 

Filed herewith

32.2

 

Certification pursuant to 18 U.S.C. Section 1350, as adopted pursuant to Section 906 of the Sarbanes-Oxley Act of 2002, executed by the Principal Financial Officer of the Company.

 

Filed herewith

101

 

XBRL data files of Financial Statements and Notes contained in this Annual Report on Form 10-K

 

 





55





SIGNATURES


Pursuant to the requirements of Section 13 or 15(d) of the Securities Exchange Act of 1934, the registrant has duly caused this report to be signed on its behalf by the undersigned, thereunto duly authorized.

 

LIGHTWAVE LOGIC, INC.

Registrant

 

By:

/s/ Thomas E. Zelibor

  

  

Thomas E. Zelibor,

  

  

Chief Executive Officer

  

  

(Principal Executive Officer)

  


Date:  March 18, 2016

 

Pursuant to the requirements of the Securities Exchange Act of 1934, this report has been signed below by the following persons on behalf of the registrant and in the capacities and on the dates indicated.


Signature

  

Title

  

Date

                                                  

    

 

    

                                                  

/s/ Thomas E. Zelibor

  

Chief Executive Officer, (Principal Executive Officer) Chmn. of the Board of Directors

 

March 18, 2016

Thomas E. Zelibor

  

 

 

  

  

 

 

 

/s/ James S. Marcelli

  

President, Chief Operating Officer, (Principal Financial Officer) Director

 

March 18, 2016

James S. Marcelli

  

 

 

  

  

 

 

 

/s/ Andrew J. Ashton

  

Senior Vice President & Secretary, Director

 

March 18, 2016

Andrew J. Ashton

  

 

 

 

  

  

 

 

 

/s/ Siraj Nour El-Ahmadi

  

Director

 

March 18, 2016

Siraj Nour El-Ahmadi

  

 

 

 

  

  

 

 

 

/s/ William C. Pickett, III

  

Director

 

March 18, 2016

William C. Pickett, III

  

 

 

 

  

  

 

 

 

/s/ Joseph A. Miller

  

Director

 

March 18, 2016

Joseph A. Miller

  

 

 

 

  

  

 

 

 

/s/ Ronald A. Bucchi

  

Director

 

March 18, 2016

Ronald A. Bucchi

  

 

 

 

 

 

 

 

 

/s/ George L Lauro

  

Director

 

March 18, 2016

George L Lauro

  

 

 

 

 

 

 

 

 

/s/ Michael Lebby

  

Director

 

March 18, 2016

Michael Lebby

  

 

 

 





56





LIGHTWAVE LOGIC, INC.


FINANCIAL STATEMENTS


DECEMBER 31, 2015 AND 2014




CONTENTS


 

PAGE

 

 

REPORT OF INDEPENDENT REGISTERED PUBLIC ACCOUNTING FIRM 

F-2

 

 

BALANCE SHEETS 

F-3

 

 

STATEMENTS OF OPERATIONS 

F-4

 

 

STATEMENT OF STOCKHOLDERS' EQUITY 

F-5

 

 

STATEMENTS OF CASH FLOWS 

F-6

 

 

NOTES TO FINANCIAL STATEMENTS 

F-7 - F-21










F-1





REPORT OF INDEPENDENT REGISTERED PUBLIC ACCOUNTING FIRM


To the Board of Directors


Lightwave Logic, Inc.

Longmont, Colorado


We have audited the accompanying balance sheets of Lightwave Logic, Inc., as of December 31, 2015 and 2014 and the related statements of operations, stockholders’ equity and cash flows for the years then ended. Lightwave Logic, Inc.’s management is responsible for these financial statements. Our responsibility is to express an opinion on these financial statements based on our audits.


We conducted our audits in accordance with the standards of the Public Company Accounting Oversight Board (United States). Those standards require that we plan and perform the audits to obtain reasonable assurance about whether the financial statements are free from material misstatement. The Company is not required to have, nor were we engaged to perform, an audit of its internal control over financial reporting. Our audits included consideration of internal control over financial reporting as a basis for designing audit procedures that are appropriate in the circumstances, but not for the purpose of expressing an opinion on the effectiveness of the Company’s internal control over financial reporting. Accordingly, we express no such opinion. An audit includes examining, on a test basis, evidence supporting the amounts and disclosures in the financial statements, assessing the accounting principles used and significant estimates made by management, as well as evaluating the overall financial statement presentation. We believe that our audits provide a reasonable basis for our opinion.


In our opinion, the financial statements referred to above present fairly, in all material respects, the financial position of Lightwave Logic, Inc., as of December 31, 2015 and 2014 and results of its operations and its cash flows for the years then ended in conformity with accounting principles generally accepted in the United States of America.



/s/ MORISON COGEN LLP

Blue Bell, Pennsylvania

March 18, 2016









F-2





LIGHTWAVE LOGIC, INC.

BALANCE SHEETS


 

 

December 31,

 

 

 

2015

 

 

2014

 

 

  

                        

  

  

                        

  

ASSETS

 

 

 

 

 

 

CURRENT ASSETS

 

 

 

 

 

 

Cash and cash equivalents

 

$

3,730,705

 

 

$

3,165,940

 

Prepaid expenses and other current assets

 

 

264,491

 

 

 

128,227

 

 

 

 

3,995,196

 

 

 

3,294,167

 

 

 

 

 

 

 

 

 

 

PROPERTY AND EQUIPMENT - NET

 

 

495,062

 

 

 

375,227

 

 

 

 

 

 

 

 

 

 

OTHER ASSETS

 

 

 

 

 

 

 

 

Intangible assets - net

 

 

619,767

 

 

 

610,029

 

 

 

 

 

 

 

 

 

 

TOTAL ASSETS

 

$

5,110,025

 

 

$

4,279,423

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

LIABILITIES AND STOCKHOLDERS' EQUITY

 

 

 

 

 

 

 

 

CURRENT LIABILITIES

 

 

 

 

 

 

 

 

Accounts payable

 

$

32,852

 

 

$

178,165

 

Accounts payable and accrued expenses- related parties

 

 

5,069

 

 

 

10,323

 

Accrued expenses

 

 

65,036

 

 

 

33,353

 

 

 

 

 

 

 

 

 

 

TOTAL LIABILITIES

 

 

102,957

 

 

 

221,841

 

 

 

 

 

 

 

 

 

 

STOCKHOLDERS' EQUITY

 

 

 

 

 

 

 

 

Preferred stock, $0.001 par value, 1,000,000 authorized no shares issued or outstanding

 

 

 

 

 

 

Common stock $0.001 par value, 250,000,000 authorized 65,237,879 and 58,381,854 issued and outstanding at December 31, 2015 and December 31, 2014

 

 

65,238

 

 

 

58,382

 

Additional paid-in-capital

 

 

46,541,251

 

 

 

40,753,189

 

Accumulated deficit

 

 

(41,599,421

)

 

 

(36,753,989

)

 

 

 

 

 

 

 

 

 

TOTAL STOCKHOLDERS' EQUITY

 

 

5,007,068

 

 

 

4,057,582

 

 

 

 

 

 

 

 

 

 

TOTAL LIABILITIES AND STOCKHOLDERS' EQUITY

 

$

5,110,025

 

 

$

4,279,423

 





The accompanying notes are an integral part of these financial statements.


F-3





LIGHTWAVE LOGIC, INC.

STATEMENTS OF OPERATIONS

FOR THE YEARS ENDING DECEMBER 31, 2015 AND 2014


 

 

For the Year Ending

 

 

 

December 31,

 

 

 

2015

 

 

2014

 

 

  

                        

  

  

                        

  

NET SALES

 

$

 

 

$

2,500

 

 

 

 

 

 

 

 

 

 

COST AND EXPENSE

 

 

 

 

 

 

 

 

Research and development

 

 

2,825,099

 

 

 

2,849,620

 

General and administrative

 

 

2,020,582

 

 

 

1,546,064

 

 

 

 

4,845,681

 

 

 

4,395,684

 

 

 

 

 

 

 

 

 

 

LOSS FROM OPERATIONS

 

 

(4,845,681

)

 

 

(4,393,184

)

 

 

 

 

 

 

 

 

 

OTHER INCOME (EXPENSE)

 

 

 

 

 

 

 

 

Interest income

 

 

249

 

 

 

249

 

Commitment fee

 

 

 

 

 

(16,862

)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

NET LOSS

 

$

(4,845,432

)

 

$

(4,409,797

)

 

 

 

 

 

 

 

 

 

Basic and Diluted Loss per Share

 

$

(0.08

)

 

$

(0.08

)

 

 

 

 

 

 

 

 

 

Basic and Diluted Weighted Average Number of Shares

 

 

60,326,470

 

 

 

55,637,906

 


 




The accompanying notes are an integral part of these financial statements.


F-4





LIGHTWAVE LOGIC, INC.

STATEMENT OF STOCKHOLDERS' EQUITY

FOR THE YEARS ENDING DECEMBER 31, 2015 AND 2014

 

 

 

Number of

 

 

Common

 

 

Paid-in

 

 

Accumulated

 

 

 

 

 

 

Shares

 

 

Stock

 

 

Capital

 

 

Deficit

 

 

Total

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

BALANCE AT DECEMBER 31, 2013

 

 

52,617,789

 

 

$

52,618

 

 

$

35,414,206

 

 

$

(32,344,192

)

 

$

3,122,632

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Common stock issued to institutional investor

 

 

1,063,648

 

 

 

1,065

 

 

 

1,035,083

 

 

 

 

 

 

1,036,148

 

Common stock issued for additional commitment shares

 

 

15,630

 

 

 

15

 

 

 

16,847

 

 

 

 

 

 

16,862

 

Common stock issued in private placement

 

 

4,207,600

 

 

 

4,207

 

 

 

3,135,793

 

 

 

 

 

 

3,140,000

 

Common stock issued for services

 

 

28,187

 

 

 

28

 

 

 

24,472

 

 

 

 

 

 

24,500

 

Exercise of options

 

 

35,000

 

 

 

35

 

 

 

10,965

 

 

 

 

 

 

11,000

 

Exercise of warrants

 

 

414,000

 

 

 

414

 

 

 

142,416

 

 

 

 

 

 

142,830

 

Options issued for services

 

 

 

 

 

 

 

 

824,726

 

 

 

 

 

 

824,726

 

Warrants issued for services

 

 

 

 

 

 

 

 

148,681

 

 

 

 

 

 

148,681

 

Net loss for the year ending December 31, 2014

 

 

 

 

 

 

 

 

 

 

 

(4,409,797

)

 

 

(4,409,797

)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

BALANCE AT DECEMBER 31, 2014

 

 

58,381,854

 

 

$

58,382

 

 

$

40,753,189

 

 

$

(36,753,989

)

 

$

4,057,582

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Common stock issued in private placement

 

 

6,793,767

 

 

 

6,794

 

 

 

4,308,206

 

 

 

 

 

 

4,315,000

 

Common stock issued for services

 

 

62,258

 

 

 

62

 

 

 

48,901

 

 

 

 

 

 

48,963

 

Options issued for services

 

 

 

 

 

 

 

 

1,339,692

 

 

 

 

 

 

1,339,692

 

Warrants issued for services

 

 

 

 

 

 

 

 

91,263

 

 

 

 

 

 

91,263

 

Net loss for the year ending December 31, 2015

 

 

 

 

 

 

 

 

 

 

 

(4,845,432

)

 

 

(4,845,432

)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

BALANCE AT DECEMBER 31, 2015

 

 

65,237,879

 

 

$

65,238

 

 

$

46,541,251

 

 

$

(41,599,421

)

 

$

5,007,068

 






The accompanying notes are an integral part of these financial statements.


F-5





LIGHTWAVE LOGIC, INC.

STATEMENTS OF CASH FLOWS
FOR THE YEARS ENDING DECEMBER 31, 2015 AND 2014

 

 

 

For the Year Ending

 

 

 

December 31,

 

 

 

2015

 

 

2014

 

CASH FLOWS FROM OPERATING ACTIVITIES

  

                        

  

  

                        

  

Net loss

 

$

(4,845,432

)

 

$

(4,409,797

)

Adjustment to reconcile net loss to net cash used in operating activities

 

 

 

 

 

 

 

 

Warrants issued for services

 

 

91,263

 

 

 

148,681

 

Stock options issued for services

 

 

1,339,692

 

 

 

824,726

 

Common stock issued for services and fees

 

 

48,963

 

 

 

41,362

 

Depreciation and amortization of patents

 

 

179,907

 

 

 

151,183

 

(Increase) decrease in assets

 

 

 

 

 

 

 

 

Prepaid expenses and other current assets

 

 

(136,264

)

 

 

3,977

 

Increase (decrease) in liabilities

 

 

 

 

 

 

 

 

Accounts payable

 

 

(145,313

)

 

 

112,755

 

Accounts payable and accrued expenses-related parties

 

 

(5,254

)

 

 

(38,494

)

Accrued expenses

 

 

31,683

 

 

 

25,404

 

 

 

 

 

 

 

 

 

 

Net cash used in operating activities

 

 

(3,440,755

)

 

 

(3,140,203

)

 

 

 

 

 

 

 

 

 

CASH FLOWS FROM INVESTING ACTIVITIES

 

 

 

 

 

 

 

 

Cost of intangibles

 

 

(29,577

)

 

 

(81,350

)

Purchase of equipment, furniture and leasehold improvements

 

 

(279,903

)

 

 

(213,189

)

 

 

 

 

 

 

 

 

 

Net cash used in investing activities

 

 

(309,480

)

 

 

(294,539

)

 

 

 

 

 

 

 

 

 

CASH FLOWS FROM FINANCING ACTIVITIES

 

 

 

 

 

 

 

 

Issuance of common stock, private placement

 

 

4,315,000

 

 

 

3,140,000

 

Issuance of common stock, exercise of options and warrants

 

 

 

 

 

153,830

 

Issuance of common stock, institutional investor

 

 

 

 

 

1,036,148

 

 

 

 

 

 

 

 

 

 

Net cash provided by financing activities

 

 

4,315,000

 

 

 

4,329,978

 

 

 

 

 

 

 

 

 

 

NET INCREASE IN CASH AND CASH EQUIVALENTS

 

 

564,765

 

 

 

895,236

 

 

 

 

 

 

 

 

 

 

CASH AND CASH EQUIVALENTS - BEGINNING OF YEAR

 

 

3,165,940

 

 

 

2,270,704

 

 

 

 

 

 

 

 

 

 

CASH AND CASH EQUIVALENTS - END OF YEAR

 

$

3,730,705

 

 

$

3,165,940

 


  




The accompanying notes are an integral part of these financial statements.


F-6





LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014


NOTE 1 – SUMMARY OF SIGNIFICANT ACCOUNTING POLICIES


History and Nature of Business


Lightwave Logic, Inc. is a technology Company focused on the development of next generation photonic devices and non-linear optical polymer materials systems for applications in high speed fiber-optic data communications and optical computing markets. Currently the Company is in various stages of photonic device and materials development and evaluation with potential customers and strategic partners. The Company expects the next revenue stream to be in sales of non-linear optical polymers, prototype devices and product development agreements prior to moving into production.


The Company’s current development activities are subject to significant risks and uncertainties, including failing to secure additional funding to operationalize the Company’s technology now under development.


Lightwave Logic, Inc., formerly Third-Order Nanotechnologies, Inc., formerly PSI-Tec Holdings, Inc., formerly Eastern Idaho Internet Service, Inc. (the “Company”) was organized under the laws of the State of Nevada in 1997. The Company was engaged in the business of marketing internet services until June 30, 1998, at which time the principal assets of the business were sold and operations were discontinued. The Company was inactive until the acquisition of PSI-TEC Corporation (“PSI-TEC”) on July 14, 2004, at which time the name was changed to PSI-TEC Holdings, Inc.


Merger

On July 14, 2004, the Company acquired PSI-TEC. Under the terms of the merger agreement, the stockholders of PSI-TEC received 15,600,000 shares of common stock in exchange for its 2,206,280 shares. Following the merger, the Company changed its name to PSI-TEC Holdings, Inc. Under accounting principles generally accepted in the United States, the share exchange is considered to be a capital transaction in substance rather than a business combination. That is, the share exchange is equivalent to the issuance of stock by PSI-TEC Holdings, Inc. for the net monetary assets of PSI-TEC, accompanied by a recapitalization, and is accounted for as a change of capital structure. Accordingly, the accounting for the share exchange was identical to that resulting from a reverse acquisition, except no goodwill was recorded. Under reverse takeover accounting, the post-reverse acquisition comparative historical financial statements of the legal acquirer, PSI-TEC Holdings, Inc., are those of the legal acquiree, PSI-TEC, which is considered to be the accounting acquirer. On October 20, 2006, PSI-TEC Holdings, Inc. and PSI-TEC merged and changed its name to Third-Order Nanotechnologies, Inc. On March 10, 2008, Third-Order Nanotechnologies, Inc. changed its name to Lightwave Logic, Inc.


Basis of Presentation

The financial statements are presented in accordance with Financial Accounting Standards Board of Accounting Standards Codification (“FASB ASC”) 915 for development stage companies. The accompanying financial statements are presented in accordance with accounting principles generally accepted in the United States of America.


Estimates

The preparation of financial statements in conformity with accounting principles generally accepted in the United States requires management to make estimates and assumptions that affect the amounts reported in the financial statements and accompanying disclosures. Although these estimates are based on management’s best knowledge of current events and actions the Company may undertake in the future, actual results could differ from the estimates.








F-7



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 1 – SUMMARY OF SIGNIFICANT ACCOUNTING POLICIES (CONTINUED)


Cash Equivalents

For the purposes of the statement of cash flows, the Company considers all highly liquid instruments with maturities of three months or less at the time of purchase to be cash equivalents.


Concentration of Credit Risk

Certain financial instruments potentially subject the Company to concentrations of credit risk. These financial instruments consist primarily of cash. At December 31, 2015, the Company did have deposits with a financial institution that exceed the Federal Depository Insurance coverage.


Property and Equipment

Equipment is stated at cost. Depreciation is principally provided by use of straight-line methods for financial and tax reporting purposes over the estimated useful lives of the assets, generally 5 years. When property is retired or otherwise disposed of, the cost and accumulated depreciation are removed from the accounts and any resulting gain or loss is included in operations.


Intangible Assets

Definite-lived intangible assets are stated at cost. Patents are amortized over their estimated useful lives, commencing from the date of grant for the remaining legal lives of the patents. The patents generally have a term of up to 20 years from the date of filing of the earliest related patent application. When certain patent applications are abandoned by the Company for claims that are covered by patents already granted to the Company, the cost of patent applications are removed from the accounts and the resulting expense is reflected in the statement of operations.


Fair Value of Financial Instruments

The Company’s financial instruments consist of cash, accounts payable and accrued expenses. The carrying values of cash, accounts payable and accrued expenses approximate fair value because of their short maturities.


Income Taxes

The Company follows FASB ASC 740, “Income Taxes,” which requires an asset and liability approach to financial accounting and reporting for income taxes. Deferred income tax assets and liabilities are computed annually for temporary differences between the financial statement and tax bases of assets and liabilities that will result in taxable or deductible amounts in the future based on enacted tax laws and rates applicable to the periods in which the differences are expected to affect taxable income. Valuation allowances are established when necessary to reduce deferred tax assets to the amount expected to be realized. Income tax expense is the tax payable or refundable for the period plus or minus the change during the period in deferred tax assets and liabilities.


Stock-based Payments

The Company accounts for stock-based compensation under the provisions of FASB ASC 718, "Compensation - Stock Compensation" which requires the measurement and recognition of compensation expense for all stock-based awards made to employees and directors based on estimated fair values on the grant date. The Company estimates the fair value of stock-based awards on the date of grant using the Black-Scholes model. The value of the portion of the award that is ultimately expected to vest is recognized as expense over the requisite service periods using the straightline method. The Company accounts for stock-based compensation awards to nonemployees in accordance with FASB ASC 505-50, "Equity-Based Payments to Non-Employees (“ASC 505-50”). Under ASC 505-50, the Company determines the fair value of the warrants or stock-based compensation awards granted as either the fair value of the consideration received or the fair value of the equity instruments issued, whichever is more reliably measurable. All issuances of stock options or other equity instruments to non-employees as consideration for goods or services received by the Company are accounted for based on the fair value of the equity instruments issued. Any stock options issued to non-employees are recorded as an expense and additional paid in capital in stockholders’ equity over the applicable service periods. Non-employee equity based payments that do not vest immediately upon grant are recorded as an expense over the service period, as if the Company had paid cash for the services. At the end of each financial reporting period, prior to vesting or prior to the completion of the services, the fair value of the equity based payments will be re-measured and the non-cash expense recognized during the period will be adjusted accordingly. Since the fair value of equity based payments granted to non-employees is subject to change in the future, the amount of the future expense will include fair value re-measurements until the equity based payments are fully vested or the service completed.

 



F-8



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 1 – SUMMARY OF SIGNIFICANT ACCOUNTING POLICIES (CONTINUED)


Loss Per Share

The Company follows FASB ASC 260, “Earnings per Share”, resulting in the presentation of basic and diluted earnings per share. Because the Company reported a net loss in 2015 and 2014, common stock equivalents, including stock options and warrants were anti-dilutive; therefore, the amounts reported for basic and dilutive loss per share were the same.


Recoverability of Long Lived Assets

The Company follows FASB ASC 360, “Property, Plant, and Equipment”. Long-lived assets to be held and used are reviewed for impairment whenever events or changes in circumstances indicate that the related carrying amount may not be recoverable. When required, impairment losses on assets to be held and used are recognized based on the excess of the asset’s carrying amount.


Comprehensive Income

The Company follows FASB ASC 220.10, “Reporting Comprehensive Income.” Comprehensive income is a more inclusive financial reporting methodology that includes disclosure of certain financial information that historically has not been recognized in the calculation of net income. Since the Company has no items of other comprehensive income, comprehensive income (loss) is equal to net loss.


Recently Adopted Accounting Pronouncements

As of December 31, 2015 and for the period then ended, there were no recently adopted accounting pronouncements that had a material effect on the Company’s financial statements.


Recently Issued Accounting Pronouncements Not Yet Adopted

As of December 31, 2015, there are no recently issued accounting standards not yet adopted which would have a material effect on the Company’s financial statements through 2017.


NOTE 2 – MANAGEMENT’S PLANS


As a technology company focusing on the development of the next generation photonic devices and non-linear optical polymer materials systems, substantial net losses have been incurred since inception. The Company has satisfied capital requirements since inception primarily through the issuance and sale of its common stock. The Company currently has a cash position of approximately $3,290,000. Based upon the current cash position and expenditures of approximately $290,000 per month and no debt service, management believes the Company has sufficient funds currently to finance its operations through January 2017. In January 2016, the Company signed a Purchase Agreement with an institutional investor to sell up to $20,000,000 of common stock. The Company also entered into a Registration Rights Agreement with the institutional investor whereby the Company filed a registration statement related to the transaction with the U.S. Securities and Exchange Commission registering 5,000,000 shares of the Company’s common stock. Under the Purchase Agreement and at Company's sole discretion, the institutional investor has committed to invest up to $20,000,000 in common stock over a 36-month period.







F-9



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 3 – PROPERTY AND EQUIPMENT


Property and equipment consists of the following:


 

 

December 31,

 

 

 

2015

 

 

2014

 

 

 

 

 

 

 

 

Office equipment

 

$

51,323

 

 

$

51,322

 

Lab equipment

 

 

722,555

 

 

 

544,858

 

Furniture

 

 

26,028

 

 

 

18,782

 

Leasehold improvements

 

 

231,859

 

 

 

136,900

 

 

 

 

1,031,765

 

 

 

751,862

 

Less: Accumulated depreciation

 

 

536,703

 

 

 

376,635

 

 

 

 

 

 

 

 

 

 

 

 

$

495,062

 

 

$

375,227

 


Depreciation expense for the years ending December 31, 2015 and 2014 was $160,068 and $136,322.


NOTE 4 – INTANGIBLE ASSETS


This represents legal fees and patent fees associated with the prosecution of patent applications. The Company has recorded amortization expenses on the Spacer and Chromophore patents granted by the United States Patent and Trademark Office in February 2011, April 2011 and September 2012, which are amortized over the remaining legal life and Chromophore patent granted by the Australian Patent Office in November 2012 which is amortized over the remaining legal life. Certain patent applications are abandoned by the Company when the claims are covered by patents already granted to the Company. Patent applications abandoned have been written off at full capitalized cost. No amortization expense has been recorded on the remaining patent applications since patents have yet to be granted.


Patents consists of the following:


 

 

December 31,

 

 

 

2015

 

 

2014

 

 

 

 

 

 

 

 

Patents

 

$

690,162

 

 

$

660,586

 

Less: Accumulated amortization

 

 

70,395

 

 

 

50,557

 

 

 

 

 

 

 

 

 

 

 

 

$

619,767

 

 

$

610,029

 


Amortization expense for the years ending December 31, 2015 and 2014 was $19,839 and $14,861. Expense for abandoned patents for claims covered by patents already granted to the Company are recorded in research and development expenses and for the years ending December 31, 2015 and 2014 were $0.




F-10



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 5 – COMMITMENTS


The Company is obligated under an operating lease for office and laboratory space. The aggregate minimum future lease payments under the operating leases are as follows:

 

DECEMBER 31,

 

AMOUNT

 

 

 

 

 

2016

 

$

64,886

 

2017

 

 

48,817

 

2018

 

 

50,274

 

2019

 

 

6,307

 

TOTAL

 

$

170,284

 


Rent expense approximating $104,724 and $18,347 is included in research and development and general and administrative expenses for the year ended December 31, 2015. The rent expense for the year ended December 31, 2014 is approximating $98,501 and $12,777 and is included in research and development and general and administrative expenses.


NOTE 6 – INCOME TAXES


As discussed in Note 1, the Company utilizes the asset and liability method of accounting for income taxes in accordance with FASB ASC 740.


The income tax benefit (provision) consists of the following:


 

 

2015

 

 

2014

 

 

 

 

 

 

 

 

Current

 

$

(1,468,000

)

 

$

(1,582,000

)

Deferred

 

 

346,000

 

 

 

(211,000

)

Change in valuation allowance

 

 

1,122,000

 

 

 

1,793,000

 

 

 

 

 

 

 

 

 

 

 

 

$

 

 

$

 


The reconciliation of the statutory federal rate to the Company’s effective income tax rate is as follows:


 

 

2015

 

 

2014

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Amount

 

 

%

 

 

Amount

 

 

%

 

Income tax benefit at U.S.

 

 

 

 

 

 

 

 

 

 

 

 

federal income tax rate

 

$

(1,647,000

)

 

 

(34

)

 

$

(1,503,000

)

 

 

(34

)

State tax, net of federal tax effect

 

 

(436,000

)

 

 

(9

)

 

 

(398,000

)

 

 

(9

)

Non-deductible share-based compensation

 

 

961,000

 

 

 

20

 

 

 

91,000

 

 

 

2

 

Other non-deductible

 

 

 

 

 

 

 

 

17,000

 

 

 

 

Change in valuation allowance

 

 

1,122,000

 

 

 

23

 

 

 

1,793,000

 

 

 

41

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

$

 

 

 

 

 

$

 

 

 

 





F-11



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 6 – INCOME TAXES (CONTINUED)


The components of deferred tax assets as of December 31, 2015 and 2014 are as follows:


 

 

2015

 

 

2014

 

 

 

 

 

 

 

 

Deferred tax asset for NOL carryforwards

 

$

13,043,000

 

 

$

11,574,000

 

Share-based compensation

 

 

3,217,000

 

 

 

3,564,000

 

Accrued expenses

 

 

 

 

 

 

Valuation allowance

 

 

(16,260,000

)

 

 

(15,138,000

)

 

 

 

 

 

 

 

 

 

 

 

$

 

 

$

 


The valuation allowance for deferred tax assets as of December 31, 2015 and 2014 was $16,260,000 and $15,138,000, respectively. The change in the total valuation for the years ended December 31, 2015 and 2014 was an increase of $1,122,000 and $1,793,000, respectively. In assessing the realization of deferred tax assets, management considers whether it is more likely than not that some portion or all of the deferred tax assets will not be realized. The ultimate realization of deferred tax assets is dependent upon the generation of future taxable income during the periods in which the net operating losses and temporary differences become deductible. Management considered projected future taxable income and tax planning strategies in making this assessment. The value of the deferred tax assets was offset by a valuation allowance, due to the current uncertainty of the future realization of the deferred tax assets.


As of December 31, 2015, the Company had net operating loss carry forwards of approximately $30,332,000, expiring through the year ending December 31, 2035. This amount can be used to offset future taxable income of the Company.


The timing and manner in which the Company can utilize operating loss carryforwards in any year may be limited by provisions of the Internal Revenue Code regarding changes in ownership of corporations. Such limitation may have an impact on the ultimate realization of its carryforwards and future tax deductions.


On January 1, 2007, the Company adopted FASB ASC 740.10, which provides guidance for the recognition and measurement of certain tax positions in an enterprise’s financial statements. Recognition involves a determination of whether it is more likely than not that a tax position will be sustained upon examination with the presumption that the tax position will be examined by the appropriate taxing authority having full knowledge of all relevant information. The adoption of FASB ASC 740.10 did not require an adjustment to the Company’s financial statements.


The Company’s policy is to record interest and penalties associated with unrecognized tax benefits as additional income taxes in the statement of operations. As of January 1, 2015, the Company had no unrecognized tax benefits and no charge during 2015, and accordingly, the Company did not recognize any interest or penalties during 2015 related to unrecognized tax benefits. There is no accrual for uncertain tax positions as of December 31, 2015.


The Company files U.S. income tax returns and a state income tax return. With few exceptions, the U.S. and state income tax returns filed for the tax years ending on December 31, 2012 and thereafter are subject to examination by the relevant taxing authorities.




F-12



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 7 – STOCKHOLDERS’ EQUITY


Preferred Stock

Pursuant to the Company’s Articles of Incorporation, the Company’s board of directors is empowered, without stockholder approval, to issue series of preferred stock with any designations, rights and preferences as they may from time to time determine. The rights and preferences of this preferred stock may be superior to the rights and preferences of the Company’s common stock; consequently, preferred stock, if issued could have dividend, liquidation, conversion, voting or other rights that could adversely affect the voting power or other rights of the common stock. Additionally, preferred stock, if issued could be utilized, under special circumstances, as a method of discouraging, delaying or preventing a change in control of the Company’s business or a takeover from a third party.


Common Stock and Warrants


During November 2007, under the 2007 Employee Stock Option Plan, the Company issued options to purchase 1,752,000 shares of common stock at a purchase price of $0.72 per share. The options expire in 5 years with 146,000 shares vesting each quarter from date of grant. During 2008, an option to purchase 750,000 shares of common stock, of which 125,000 shares were vested, forfeited. In November 2012, the remaining options were extended to November 2014. In October 2014, the remaining options were extended to November 2016. The incremental increase in fair value of the modified options was $245,082 using the Black-Scholes Option Pricing Formula which was expensed immediately. As of December 31, 2015, the options to purchase the remaining 1,002,000 shares of common stock are still outstanding.


In January 2008, under the 2007 Employee Stock Option Plan, the Company issued an option to purchase 100,000 shares of common stock at a purchase price of $0.72 per share, vesting 25,000 immediately and the remaining in annual equal installments of 25,000. In November 2012, the option was extended to January 2015. In October 2014, the option was extended to January 2017. The incremental increase in fair value of the modified options was $21,462 using the Black-Scholes Option Pricing Formula which was expensed immediately. As of December 31, 2015, the option to purchase 100,000 shares of common stock is still outstanding.


In July 2008, the Company issued options to purchase 200,000 shares of common stock at a purchase price of $1.75 per share to members of the board of directors, under the 2007 Employee Stock Option Plan, vesting 50,000 immediately and the remaining in annual equal installments of 50,000 over the next three years. In November 2012, the options were extended to July 2015. In July 2015, an option to purchase 100,000 shares of common stock was cancelled. In July 2015, an option to purchase 100,000 shares of common stock expired.


In August 2008, under the 2007 Employee Stock Option Plan, the Company issued options to purchase 550,000 and 1,050,000 shares of common stock at a purchase price of $1.42 and $1.75 per share to members of the board of directors and the Chief Executive Officer, vesting 212,500 immediately and the remaining in annual equal installments of 112,500 over the next three years and vesting in quarterly equal installments of 87,500 commencing November 1, 2008, respectively. In November 2012, the options were extended to August 2015 and July 2015, respectively. In July 2015, the options to purchase 1,450,000 shares of common stock were cancelled. In August 2015 an option to purchase 150,000 shares of common stock expired.


In January 2009, an employee was granted with an option to purchase up to 25,000 shares of common stock at a purchase price of $.25 per share. Using the Black-Scholes Option Pricing Formula, the options were valued at $13,136, fair value. These options expire in 5 years and vest immediately. The expense recognized during 2009 is $13,136. In May 2010, the option was partially exercised to purchase 15,000 shares of common stock for proceeds of $3,750. In January 2014, the remaining 10,000 options were exercised to purchase 10,000 shares of common stock for proceeds of $2,500.


In June 2009, an employee was granted with an option to purchase up to 25,000 shares of common stock at a purchase price of $.34 per share. Using the Black-Scholes Option Pricing Formula, the options were valued at valued at $21,085, fair value. These options expire in 5 years and vest immediately. The expense recognized during 2009 was $21,085. In May 2014, the option was fully exercised to purchase 25,000 shares of common stock for proceeds of $8,500.





F-13



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 7 – STOCKHOLDERS’ EQUITY (CONTINUED)


Common Stock and Warrants (Continued)


During June 2009, the Company issued a warrant to purchase 464,000 shares of common stock at a purchase price of $0.34 per share for accounting services rendered. The warrant was valued at $391,342 using the Black-Scholes Option Pricing Formula, vesting 46,400 immediately and the remaining on equal monthly installments of 23,200 over the next eighteen months. The warrant expires in 5 years. The expense is being recognized based on service terms of the agreement over a twenty two month period. The expense recognized during 2010 and 2009 was $213,459 and $177,883. In April 2010, the warrant was partially exercised to purchase 10,000 shares of common stock for proceeds of $3,450. In February 2012, the warrant was partially exercised to purchase 20,000 shares of common stock for proceeds of $6,900. In June 2013, the warrant was partially exercised to purchase 20,000 shares of common stock for proceeds of $6,900. In March 2014, warrants were exercised to purchase 250,000 shares of common stock for proceeds of $86,250. In June 2014, the remaining outstanding 164,000 warrants were exercised to purchase 164,000 shares of common stock for proceeds of $56,580.


In January 2010, the Company issued a warrant to purchase 650,000 shares of common stock at a purchase price of $1.51 per share to a new member of its board of directors serving as the Company’s full-time non-executive chair of the board of directors. Using the Black-Scholes Option Pricing Formula, the warrants were valued at $1,188,000, fair value, vesting 162,500 immediately and the remaining in annual equal installments of 162,500 over the next three years. The warrant expires in 5 years. During 2011, the warrant to purchase 650,000 shares of common stock, of which 487,500 shares were vested, forfeited. For the year ending December 31, 2011 and 2010, the Company recognized $306,765 and $580,167 of expense. The warrant to purchase 487,500 shares of common stock expired in January 2015.


In June 2010, an employee was granted with an option to purchase up to 100,000 shares of common stock at a purchase price of $1.50 per share, vesting in equal installments of 12,500 over the next two years commencing August 1, 2010. In July 2015, the option was cancelled.


In November 2010, the board of directors approved a grant to employees of options to purchase up to 250,000 shares of common stock at a purchase price of $1.00 per share. These options were granted on December 13, 2010, vesting 125,000 on December 13, 2010 and 125,000 vesting on June 13, 2011. In July 2015, the options were cancelled.


In November 2010, the board of directors approved a grant to three outside directors of options to purchase up to 300,000 shares of common stock at a purchase price of $1.00 per share. These options were granted on December 13, 2010, vesting 75,000 on December 13, 2010 and the remaining in equal annual installments of 75,000 over the next three years commencing November 4, 2011. In July 2015, the options to purchase 200,000 shares of common stock were cancelled. In September 2015, options to purchase 100,000 shares of common stock were extended for 5 years. The incremental increase in fair value of the modified options was $33,393, using the Black-Scholes Option Pricing Formula, and was expensed immediately. As of December 31, 2015, the remaining options to purchase 100,000 shares of common stock are still outstanding.


In January 2011, the Company issued a warrant to a related party to purchase 10,000 shares of common stock for legal services at an exercise price of $1.25 per share. Using the Black-Scholes Option Pricing Formula, the warrants were valued at $10,453, fair value. These warrants expire in 3 years and vest immediately. For the years ending December 31, 2015 and 2014, the Company recognized $0 and $0 of expense. In January 2014, the warrant to purchase 10,000 shares of common stock forfeited.


In August 2012, the board of directors approved a grant to a new employee of an option to purchase up to 100,000 shares of common stock at a purchase price of $0.925 per share. Using the Black-Scholes Option Pricing Formula, the option was valued at $74,486, fair value. The option expires in 5 years with 12,500 vesting every 3 months from date of grant. The option is expensed over the vesting terms. For the years ending December 31, 2015 and 2014, the Company recognized $0 and $3,012 of net expense. In February 2014, the option to purchase 25,000 shares of common stock forfeited. In May 2014, the option to purchase 75,000 shares of common stock forfeited.




F-14



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 7 – STOCKHOLDERS’ EQUITY (CONTINUED)


Common Stock and Warrants (Continued)


In March 2013, the board of directors approved a grant to a new employee of an option to purchase up to 75,000 shares of common stock at a purchase price of $1.16 per share. Using the Black-Scholes Option Pricing Formula, the option was valued at $81,076, fair value. The option expires in 10 years with 9,375 vesting quarterly from date of grant. The option is expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $6,551 and $40,539 of expense. In November 2015, the options to purchase 75,000 shares of common stock forfeited.


In May 2013, the board of directors approved a grant to a new employee of an option to purchase up to 10,000 shares of common stock at a purchase price of $1.03 per share. Using the Black-Scholes Option Pricing Formula, the option was valued at $9,574, fair value. The option expires in 10 years with 1,250 vesting quarterly from date of grant. The option is expensed over the vesting terms. In December 2013, the option to purchase 7,500 shares of common stock forfeited. For the year ending December 31, 2015 and 2014, the Company recognized a net expense of $0. In March 2014, the options to purchase 2,500 shares of common stock forfeited.


In May 2013, the board of directors approved a grant to an employee of an option to purchase up to 100,000 shares of common stock at a purchase price of $1.00 per share. Using the Black-Scholes Option Pricing Formula, the option was valued at $80,824, fair value. The option expires in 10 years with 25,000 vesting August 1, 2013, October 1, 2013 and quarterly thereafter. The option is expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $0 and $20,425 of expense. As of December 31, 2015, options to purchase 100,000 shares of common stock are still outstanding.


In June 2013, the Company signed a Purchase Agreement and Registration Rights Agreement with an institutional investor to sell up to $20,000,000 of common stock. Under the agreement subject to certain conditions and at the Company's sole discretion, the institutional investor has committed to invest up to $20,000,000 in the Company's common stock over a 30-month period. The Company filed the registration statement with the U.S. Securities and Exchange Commission in September 2013. The institutional investor is obligated to make purchases as the Company directs in accordance with the agreement, which may be terminated by the Company at any time, without cost or penalty. Sales of shares will be made in specified amounts and at prices that are based upon the market prices of the Company's common stock immediately preceding the sales to the institutional investor. The Company issued 200,000 shares of restricted common stock to the institutional investor as an initial commitment fee valued at $170,000, fair value and 400,000 shares of common stock are reserved for additional commitment fees to the institutional investor in accordance with the terms of the agreement. During June 2013 through December 2015, the institutional investor purchased 1,563,648 shares of common stock for proceeds of $1,514,647 and the Company issued 23,272 shares of common stock as additional commitment fee, valued at $24,745, fair value, leaving 376,728 in reserve for additional commitment fees. For the year ending December 31, 2015, the institutional investor did not purchase shares of common stock and the Company did not issue shares of common stock as additional commitment fee. For the year ending December 31, 2014, the institutional investor purchased 1,063,648 shares of common stock for proceeds of $1,036,148 and the Company issued 15,630 shares of common stock as additional commitment fee, valued at $16,862, fair value. On February 1, 2016, the Company and the institutional investor entered into an Agreement to terminate the Purchase Agreement and Registration Rights Agreement dated June 6, 2013.


During July 2013, the Company issued a warrant to purchase 100,000 shares of common stock at a purchase price of $0.90 per share for accounting services rendered commencing July 1, 2013. The warrant was valued at $48,915 using the Black-Scholes Option Pricing Formula, vesting over the next twelve months with 8,333 vesting each month for the first eleven months and 8,337 vesting the twelfth month from date of grant. The warrant expires in five years. The expense is being recognized based on service terms of the agreement over a twelve month period. For the year ending December 31, 2015 and 2014, the Company recognized $0 and $24,257 of expense. As of December 31, 2015, warrant to purchase 100,000 shares of common stock is still outstanding.




F-15



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 7 – STOCKHOLDERS’ EQUITY (CONTINUED)


Common Stock and Warrants (Continued)


During August 2013, the Company issued an option to an employee to purchase 25,000 shares of common stock at a purchase price of $0.84 per share. The option was valued at $17,852 using the Black-Scholes Option Pricing Formula. The option expires in ten years and vests immediately. The option is expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $0 and $0 of expense. As of December 31, 2015, the option to purchase 25,000 shares of common stock is still outstanding.


During August 2013, the Company issued an option to a director to purchase 50,000 shares of common stock at a purchase price of $0.84 per share. The option was valued at $35,704 using the Black-Scholes Option Pricing Formula, vesting 20,000 options immediately and 10,000 options vesting in three equal quarterly installments commencing October 1, 2013. The option expires in ten years. The option is expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $0 and $7,219 of expense. As of December 31, 2015, the option to purchase 50,000 shares of common stock is still outstanding.


In October 2013, the Company issued an option to a new director to purchase 200,000 shares of common stock at a purchase price of $0.93 per share for a directorship commencing November 1, 2013. The option was valued at $174,106 using the Black-Scholes option pricing model. The option expires in 10 years with 50,000 vesting in annual installments commencing November 1, 2013. The option is expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $43,527 and $43,527 of expense. As of December 31, 2015, the option to purchase 200,000 shares of common stock is still outstanding.


In December 2013, the board of directors approved a grant to a senior advisor effective January 2014 of a warrant to purchase up to 100,000 shares of common stock at a purchase price of $0.715 per share. Using the Black-Scholes Option Pricing Formula, the warrant was valued at $53,313, fair value. The warrant expires in 5 years and vests 25,000 immediately and the remaining in equal monthly installments of 7,500 over the next 10 months. The warrant is expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $0 and $53,313 of expense. As of December 31, 2015, the warrants to purchase 100,000 shares of common stock are still outstanding.


In January 2014, the Company issued options to the Company’s 4 independent directors to each purchase 50,000 shares of common stock at a purchase price of $0.715 per share. The options were each valued at $29,440, fair value, using the Black-Scholes Option Pricing Formula. The options expire in 10 years with 20,000 vesting immediately and the remainder vesting in quarterly equal installments of 10,000 commencing April 1, 2014. The options are expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $0 and $117,760 of expense. As of December 31, 2015, the options to purchase 200,000 shares of common stock are still outstanding.


In March 2014, the Company issued options to a new employee to purchase 30,000 shares of common stock at a purchase price of $0.92 per share. The options were valued at $23,304, fair value, using the Black-Scholes Option Pricing Formula. The options expire in 10 years vesting in quarterly equal installments of 3,750 from date of employment. The options are expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $11,652 and $10,100 of expense. As of December 31, 2015, the options to purchase 30,000 shares of common stock are still outstanding.


In March 2014, the Company issued options to a new employee to purchase 75,000 shares of common stock at a purchase price of $0.92 per share. The options were valued at $58,384, fair value, using the Black-Scholes Option Pricing Formula. The options expire in 10 years vesting in quarterly equal installments of 9,375 from date of employment. The options are expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $29,192 and $24,829 of expense. As of December 31, 2015, the options to purchase 75,000 shares of common stock are still outstanding.


In March 2014, the Company issued options to a new employee to purchase 50,000 shares of common stock at a purchase price of $0.92 per share. The options were valued at $38,922, fair value, using the Black-Scholes Option Pricing Formula. The options expire in 10 years vesting in quarterly equal installments of 6,250 from date of employment. The options are expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $19,427 and $16,164 of expense. As of December 31, 2015, the options to purchase 50,000 shares of common stock are still outstanding.



F-16



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 7 – STOCKHOLDERS’ EQUITY (CONTINUED)


Common Stock and Warrants (Continued)


In March 2014, the Company issued options to an employee to purchase 125,000 shares of common stock at a purchase price of $0.92 per share. The options were valued at $96,211, fair value, using the Black-Scholes Option Pricing Formula. The options expire in 10 years vesting in quarterly equal installments of 15,625 commencing April 1, 2014. The options are expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $24,183 and $47,975 of expense. In August 2015, options to purchase 31,250 shares of common stock forfeited. In November 2015, the remaining options to purchase 93,750 shares of common stock forfeited.


In March 2014, the Company issued options to an employee to purchase 30,000 shares of common stock at a purchase price of $0.92 per share. The options were valued at $22,222, fair value, using the Black-Scholes Option Pricing Formula. The options expire in 10 years vesting in quarterly equal installments of 7,500 commencing April 1, 2014. The options are expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $60 and $22,162 of expense. As of December 31, 2015, the options to purchase 30,000 shares of common stock are still outstanding.


In March 2014, the Company issued options to purchase 40,000 shares of common stock at a purchase price of $0.92 per share to its Chief Executive Officer as part of a new employment agreement. The options were valued at $29,630, fair value, using the Black-Scholes Option Pricing Formula. The options expire in 10 years vesting in quarterly equal installments of 10,000 commencing April 1, 2014. The options are expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $80 and $29,550 of expense. As of December 31, 2015, the options to purchase 40,000 shares of common stock are still outstanding.


In March 2014, the Company issued warrants to purchase 100,000 shares of common stock for consulting services at an exercise price of $0.92 per share. The warrants were valued at $66,936, fair value, using the Black-Scholes Option Pricing Formula. The warrants expire in 5 years vesting 25,000 immediately with the remaining 75,000 vesting in monthly equal installments of 7,500 commencing April 1, 2014. The warrants are expensed over the vesting terms. In October 2014, warrants to purchase 22,500 shares of common stock forfeited. For the year ending December 31, 2015 and 2014, the Company recognized $0 and $39,061 of expense. As of December 31, 2015, the warrants to purchase 77,500 shares of common stock are still outstanding.

 

In May 2014, the Company issued options to a new director to purchase 200,000 shares of common stock at a purchase price of $0.763 per share. The options were valued at $122,515 using the Black-Scholes Option Pricing Formula. The options expire in 10 years with 50,000 vesting immediately and the remainder vesting in annual equal installments of 50,000 commencing on the one year anniversary of the date of grant. The options are expensed over the vesting terms. For the year ending December 31, 2015 and 2014, the Company recognized $30,628 and $50,264 of expense. As of December 31, 2015, the options to purchase 200,000 shares of common stock are still outstanding.

 

During June 2014 through August 2014, the Company issued 4,207,600 shares of common stock and warrants to purchase 4,207,600 shares of common stock expiring five years from the date of purchase, for proceeds of $3,140,000 in accordance to a private placement memorandum as amended on May 27, 2014. Pursuant to the terms of the offerings, up to 60 units were offered at the purchase price of $50,000 per unit, with each unit comprised of 67,000 shares and a warrant to purchase 33,500 shares of common stock at $1.00 per share and a warrant to purchase 33,500 shares of common stock at $1.25 per share. The warrants to purchase 2,103,800 shares of common stock at $1.00 per share are still outstanding as of December 31, 2015. The warrants to purchase 2,103,800 shares of common stock at $1.25 per share are still outstanding as of December 31, 2015. Since the warrants are considered indexed to its own stock and qualify for equity classification, there is no requirement to separately account for the warrants. On September 9, 2014 the Company filed the Registration Statement on Form S-1 which became effective on September 17, 2014.

 

During 2015 and 2014 the Company issued 12,040 shares and 15,687 shares, respectively, with a fair value of $24,000, to a director serving as a member of the Company’s Operations Committee. For the year ending December 31, 2015 and 2014, the Company recognized $10,000 and $14,000 of expense.




F-17



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 7 – STOCKHOLDERS’ EQUITY (CONTINUED)


Common Stock and Warrants (Continued)


During July 2014, the Company issued a warrant to purchase 100,000 shares of common stock at a purchase price of $0.95 per share for accounting services rendered commencing July 1, 2014. The warrant was valued at $53,288, fair value, using the Black-Scholes Option Pricing Formula, vesting over the next twelve months with 8,333 vesting immediately, 8,333 vesting per month on the first day of the next ten months and 8,337 vesting on the first day of the twelfth month of the corresponding service agreement. The warrant expires in five years. The expense is being recognized based on service terms of the agreement over a twelve month period. For the year ending December 31, 2015 and 2014, the Company recognized $21,238 and $32,050 of expense. As of December 31, 2015, the warrants to purchase 100,000 shares of common stock are still outstanding.


Effective August 21, 2014, the number of shares of the Company’s common stock available for issuance under the 2007 Employee Stock plan was increased from 8,000,000 to 10,000,000 shares.


During 2015 and 2014 the Company issued 37,500 shares and 12,500 shares, respectively, with a fair value of $41,075, to a firm for investor relations services. For the year ending December 31, 2015 and 2014, the Company recognized $30,575 and $10,500 of expense.


In December 2014, the board of directors approved a grant to a senior advisor effective January 1, 2015 of a warrant to purchase up to 100,000 shares of common stock at a purchase price of $0.77 per share. Using the Black-Scholes Option Pricing Formula, the warrant was valued at $46,576, fair value. The warrant expires in 5 years and vests 25,000 immediately and the remaining in equal monthly installments of 7,500 over the next 10 months. The warrant is expensed over the vesting terms. For the year ending December 31, 2015, the Company recognized $46,576 of expense. As of December 31, 2015, the warrants to purchase 100,000 shares of common stock are still outstanding.


In December 2014, the board of directors approved a grant to an employee effective January 1, 2015 to purchase 15,000 shares of common stock at a purchase price of $0.77 per share. The options were valued at $7,362, fair value, using the Black-Scholes Option Pricing Formula. The options expire in 10 years vesting 7,500 immediately and 7,500 in 3 months from the effective date of the option agreement. The options are expensed over the vesting terms. For the year ending December 31, 2015, the Company recognized $7,362 of expense. As of December 31, 2015, the options to purchase 15,000 shares of common stock are still outstanding.


In March 2015, the Company issued options to the Company’s five independent directors to each purchase 50,000 shares of common stock at a purchase price of $0.80 per share. The options were each valued at $24,901, fair value, using the Black-Scholes Option Pricing Formula. The options expire in 10 years with 20,000 vesting immediately and the remainder vesting in quarterly equal installments of 10,000 commencing April 1, 2015. The options are expensed over the vesting terms. For the year ending December 31, 2015, the Company recognized $124,505 of expense. As of December 31, 2015, the options to purchase 250,000 shares of common stock are still outstanding.


In March 2015, the Company issued an option to an employee to purchase 2,500 shares of common stock at a purchase price of $0.80 per share. The option was valued at $1,231, fair value, using the Black-Scholes Option Pricing Formula. The option expires in 10 years vesting immediately. The option is expensed over the vesting terms. For the year ending December 31, 2015, the Company recognized $1,231 of expense. As of December 31, 2015, the options to purchase 2,500 shares of common stock are still outstanding.


In May 2015, the Company increased the authorized shares of common stock from 100,000,000 to 250,000,000.







F-18



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 7 – STOCKHOLDERS’ EQUITY (CONTINUED)


Common Stock and Warrants (Continued)


During May 2015 through June 2015, the Company issued 2,816,199 shares of common stock and warrants to purchase 2,816,199 shares of common stock expiring five years from the date of purchase, for proceeds of $1,915,000 in accordance to a private placement memorandum as amended on May 27, 2015. Pursuant to the terms of the offerings, up to 20 units were offered at the purchase price of $100,000 per unit, with each unit comprised of 147,060 shares and a warrant to purchase 73,530 shares of common stock at $0.85 per share and a warrant to purchase 73,530 shares of common stock at $1.02 per share. The warrants to purchase 1,408,102 shares of common stock at $0.85 per share are still outstanding as of December 31, 2015. The warrants to purchase 1,408,097 shares of common stock at $1.02 per share are still outstanding as of December 31, 2015. Since the warrants are considered indexed to its own stock and qualify for equity classification, there is no requirement to separately account for the warrants.


During July 2015, under the 2007 Employee Stock Option Plan, the Company issued to employees and a director options to purchase 2,100,000 shares of common stock at a purchase price of $0.70 per share. The options were valued at $931,284, fair value, using the Black-Scholes Option Pricing Formula. The options expire in 10 years and vest immediately. The options are expensed over the vesting terms. All the options issued replaced options that either expired or were canceled. For the year ending December 31, 2015, the Company recognized $931,284 of expense. As of December 31, 2015, the options to purchase 2,100,000 shares of common stock are still outstanding.


During July 2015, the Company issued a warrant to purchase 125,000 shares of common stock at a purchase price of $0.70 per share for accounting services to be rendered over a twelve month period commencing July 1, 2015. The warrant was valued at $46,897, fair value at December 31, 2015, using the Black-Scholes Option Pricing Formula, vesting over the next twelve months with 10,416 vesting immediately, 10,416 vesting per month on the first day of the next ten months and 10,424 vesting on the first day of the twelfth month of the corresponding service agreement. The warrant expires in five years. The expense is being recognized based on service terms of the agreement over a twelve month period. For the year ending December 31, 2015, the Company recognized $23,449 of expense. As of December 31, 2015, the warrants to purchase 125,000 shares of common stock are still outstanding.


During August 2015, under the 2007 Employee Stock Option Plan, the Company issued an option to an employee to purchase 50,000 shares of common stock at a purchase price of $0.67 per share. The option was valued at $19,930, fair value, using the Black-Scholes Option Pricing Formula. The option expires in 10 years and vests 12,500 immediately and the remaining in equal quarterly installments of 12,500 over the next three quarters. The option is expensed over the vesting terms. For the year ending December 31, 2015, the Company recognized $12,727 of expense. As of December 31, 2015, the options to purchase 50,000 shares of common stock are still outstanding.


During August 2015, under the 2007 Employee Stock Option Plan, the Company issued an option to three employees to purchase 75,000 shares of common stock at a purchase price of $0.69 per share. The option was valued at $32,734, fair value, using the Black-Scholes Option Pricing Formula. The option expires in 10 years and vests 15,000 immediately and the remaining in equal quarterly installments of 15,000 over the next four quarters. The option is expensed over the vesting terms. For the year ending December 31, 2015, the Company recognized $15,582 of expense. As of December 31, 2015, the options to purchase 75,000 shares of common stock are still outstanding.


During August 2015, under the 2007 Employee Stock Option Plan, the Company issued an option to a new director to purchase 200,000 shares of common stock at a purchase price of $0.69 per share. The option was valued at $90,615, fair value, using the Black-Scholes Option Pricing Formula. The option expires in 10 years and vests 50,000 immediately and the remaining in equal annual installments of 50,000 over the next three years. The option is expensed over the vesting terms. For the year ending December 31, 2015, the Company recognized $30,518 of expense. As of December 31, 2015, the options to purchase 200,000 shares of common stock are still outstanding.


During 2015 the Company issued 12,718 shares, with a fair value of $8,387, to a director serving as a member of the Company’s Operations Committee. For the year ending December 31, 2015, the Company recognized $8,387 of expense. During January 2016 and February 2016, the Company issued 3,750 and 3,330 additional shares of common stock valued at $2,000 and $2,000.



F-19



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 7 – STOCKHOLDERS’ EQUITY (CONTINUED)


Common Stock and Warrants (Continued)


During October 2015, under the 2007 Employee Stock Option Plan, the Company issued options to a new employee to purchase 35,000 shares of common stock at a purchase price of $0.74 per share. The option was valued at $16,393, fair value, using the Black-Scholes Option Pricing Formula. The options expire October 12, 2025 with 4,375 shares vesting on the anniversary date of the third month of employment and the remaining vesting in seven equal installments of 4,375 at the end of every three month period thereafter. The option is expensed over the vesting terms. For the year ending December 31, 2015, the Company recognized $1,782 of expense. As of December 31, 2015, the options to purchase 35,000 shares of common stock are still outstanding.


During November 2015, under the 2007 Employee Stock Option Plan, the Company granted options effective January 1, 2016 to the Chief Executive Officer to purchase 100,000 shares of common stock at a purchase price of $0.86 per share. The options expire November 9, 2025 with 12,500 shares vesting on January 1, 2016 and the remaining vesting quarterly in equal installments of 12,500 options commencing April 1, 2016. The options were valued at $33,108, fair value, using the Black-Scholes Option Pricing Formula. The options will be expensed over the vesting terms.


During November 2015 through December 2015, the Company issued 3,977,568 shares of common stock and warrants to purchase 3,977,568 shares of common stock expiring five years from the date of purchase, for proceeds of $2,400,000 in accordance to a private placement memorandum as amended on November 10, 2015. Pursuant to the terms of the offerings, up to 60 units were offered at the purchase price of $50,000 per unit, with each unit comprised of 82,866 shares and a warrant to purchase 82,866 shares of common stock at $0.80 per share. The warrants to purchase 3,977,568 shares of common stock at $0.80 per share are still outstanding as of December 31, 2015. Since the warrants are considered indexed to its own stock and qualify for equity classification, there is no requirement to separately account for the warrants.


NOTE 8 – STOCK BASED COMPENSATION


The Company uses the Black-Scholes option pricing model to calculate the grant-date fair value of an award, with the following assumptions for 2015 and 2014: no dividend yield in both years, expected volatility, based on the Company’s historical volatility, 75% to 79% in 2015 and between 70.25% to 109% in 2014, risk-free interest rate between 1.44% to 1.70% in 2015 and between 0.58% to 2.08% in 2014 and expected option life of 5 to 5.75 years in 2015 and 2.13 to 7.25 years in 2014.


As of December 31, 2015, there was $209,618 of unrecognized compensation expense related to non-vested market-based share awards that is expected to be recognized through August 2018.


The following tables summarize all stock option and warrant activity of the Company during the year ended December 31, 2015 and 2014:


 

 

Non-Qualified Stock Options and Warrants
Outstanding and Exercisable

 

 

 

 

 

 

 

 

 

Weighted

 

 

 

 

 

 

 

 

 

Average

 

 

 

Number of

 

 

Exercise

 

 

Exercise

 

 

 

Shares

 

 

Price

 

 

Price

 

 

  

 

 

 

 

 

 

 

  

Outstanding, December 31, 2013

 

 

7,146,000

 

 

$0.25 - $1.75

 

 

$

1.16

 

Granted

 

 

5,257,600

 

 

$0.72 - $1.25

 

 

$

1.07

 

Expired

 

 

(10,000

)

 

$1.25

 

 

$

1.25

 

Forfeited

 

 

(125,000

)

 

$0.92 - $1.03

 

 

$

0.93

 

Exercised

 

 

(449,000

)

 

$0.25 - $0.345

 

 

$

0.34

 

Outstanding, December 31, 2014

 

 

11,819,600

 

 

$0.25 - $1.75

 

 

$

1.15

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Granted

 

 

9,746,267

 

 

$0.67 - $1.02

 

 

$

0.81

 

Expired

 

 

(2,837,500

)

 

$1.00 - $1.75

 

 

$

1.52

 

Forfeited

 

 

(200,000

)

 

$0.92 - $1.16

 

 

$

1.01

 

Exercised

 

 

 

 

 

 

 

 

 

 

Outstanding, December 31, 2015

 

 

18,528,367

 

 

$0.63 - $1.69

 

 

$

0.92

 

Exercisable, December 31, 2015

 

 

18,006,488

 

 

$0.63 - $1.69

 

 

$

0.92

 



F-20



LIGHTWAVE LOGIC, INC.

NOTES TO FINANCIAL STATEMENTS

DECEMBER 31, 2015 AND 2014

 


NOTE 8 – STOCK BASED COMPENSATION (CONTINUED)


The aggregate intrinsic value of options and warrants outstanding and exercisable as of December 31, 2015 was $0. The aggregate intrinsic value is calculated as the difference between the exercise price of the underlying options and warrants and the closing stock price of $.585 for our common stock on December 31, 2015. The total intrinsic value of options and warrants exercised during the year ended December 31, 2014 was $232,139. No options or warrants were exercised during 2015.


Non-Qualified Stock Options and Warrants Outstanding

 

 

Number Outstanding

 

Weighted Average

 

Weighted Average

Range of

 

Currently Exercisable

 

Remaining

 

Exercise Price of Options and

Exercise Prices

 

at December 31, 2015

 

Contractual Life

 

Warrants Currently Exercisable

 

 

 

 

 

 

 

$0.63 - $1.69

 

18,006,488

 

4.86 Years

 

$0.92


NOTE 9 – RELATED PARTY


At December 31, 2015 the Company had a legal accrual to related party of $1,420 and travel and office expense accruals of officers in the amount of $3,649. At December 31, 2014 the Company had a legal accrual to related party of $8,258 and travel and office expense accruals of officers in the amount of $1,144.


NOTE 10 – RETIREMENT PLAN


The Company established a 401(k) retirement plan covering all eligible employees beginning November 15, 2013. There were no contributions charged to expense in 2015 and 2014.


NOTE 11 – SUBSEQUENT EVENTS


In December 2015, the board of directors approved a grant to a senior advisor effective January 1, 2016 of a warrant to purchase up to 125,000 shares of common stock at a purchase price of $0.60 per share. Using the Black-Scholes Option Pricing Formula, the warrant was valued at $44,868, fair value. The warrant expires in 5 years and vests 31,250 immediately and the remaining in equal monthly installments of 9,375 over the next 10 months. The warrant is expensed over the vesting terms.


In February 2016, the Company issued options to the Company’s six independent directors to each purchase 50,000 shares of common stock at a purchase price of $0.68 per share. The options were each valued at $21,475 using the Black-Scholes Option Pricing Formula. The options expire in 10 years with 20,000 vesting immediately and the remainder vesting in quarterly equal installments of 10,000 commencing April 1, 2016. The options are expensed over the vesting terms.


In January 2016, the Company signed a Purchase Agreement with an institutional investor to sell up to $20,000,000 of common stock. The Company also entered into a Registration Rights Agreement with the institutional investor whereby the Company agreed to file a registration statement related to the transaction with the U.S. Securities and Exchange Commission registering 5,000,000 shares of the Company’s common stock. The registration statement was filed on February 16, 2016. Under the Purchase Agreement and at Company's sole discretion, the institutional investor has committed to invest up to $20,000,000 in common stock over a 36-month period. The new Purchase Agreement provides more flexibility for the Company than the previous 2013 Purchase Agreement which was terminated on February 1, 2016.





F-21