SBIR-STTR Award

The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase I project is to develop and commercialize a high resolution, protein-based retinal implant intended to restore vision to the millions of patients suffering from retinal degenerative diseases, particularly retinitis pigmentosa and age-related macular degeneration. These currently incurable and blinding diseases affect between 30-50 million people worldwide, and lead to a loss of independence for the individual, as well as an increased burden on their caregivers. Additionally besides the emotional and physical burden of vision loss, the cost of vision problems in the US alone is estimated at $139 billion. The work outlined in this SBIR proposal has the potential to significantly impact our understanding of retinal degenerative diseases, as well as the field of retinal prosthetics. The subretinal implant under development provides the framework for the next generation of high-resolution retinal prosthetics, while offering a cost-effective solution to vision restoration, and will help these patients regain independence and thus improve their quality of life. ------------------

The proposed project seeks to quantify the spatial resolution of a flexible, protein-based, ion-mediated retinal implant, as well as to perform an initial evaluation of the implant in vivo. The retinal implant under development is the first implantable technology to use the light-activated protein, bacteriorhodopsin, to convert light energy into an ion gradient that is capable of activating the remaining neural circuitry of the degenerate retina. The retinal implant will replace the function of the damaged photoreceptor cells. Spatial resolution will be evaluated ex vivo using excised retinas obtained from a transgenic rat model of retinitis pigmentosa. Extracellular microelectrode array experiments will be carried out to demonstrate the resolution of the implant, which is critical for meaningful vision. Safety and efficacy of the implant will be evaluated in vivo via a 6-week feasibility study on domestic swine. These in vivo studies are critical to establish the surgical procedures and biocompatibility and biostability of the implant in preparation for long-term, rigorous, preclinical efficacy testing of the implant as part of Phase II investigations. These experiments are critical value creation milestones that will demonstrate the commercial viability of the retinal implant under development.

The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase II project is to develop and commercialize a high resolution, protein-based retinal implant intended to restore vision to the millions of patients blinded by retinal degenerative diseases, particularly retinitis pigmentosa and age-related macular degeneration. These currently incurable and blinding diseases affect between 30-50 million people worldwide, and lead to a loss of independence for the individual, as well as an increased burden on their caregivers. While improved quality of life is the most vital outcome of this technology, reduction of medical costs of treating chronic retinal degeneration and limiting time with doctors will also be of benefit to the broad healthcare field. The work outlined in this SBIR proposal also has the potential to significantly impact our understanding of retinal degenerative diseases, which will help in developing better and more effective treatments for a number of ophthalmic indications. The subretinal implant under development provides the framework for the next generation of high-resolution retinal prosthetics, while offering a cost-effective solution to vision restoration, and will help these patients regain independence and thus improve their quality of life. The proposed project will expand on the data collected from the in vivo surgical development and ex vivo efficacy studies supported by our Phase I/IB awards. First, a 40-animal rat study will be undertaken to further investigate the biocompatibility of the retinal implant. Second, previously developed surgical procedures will be refined in pigs to ensure reproducible and safe subretinal implantation. Third, a high-throughput in vitro assay will be designed to investigate a number of implant parameters, as well as the integrity and biostability of the retinal implant using retinal pigment epithelial cells. Additionally, medical device sealants will be investigated in this in vitro study, and the functional integrity of the implant will be measured using time-resolved absorption spectroscopy and an ion-sensitive detector, which is being developed specifically for this application. Lastly, this ion-sensitive detector will provide an opportunity to further measure the spatial sensitivity of the retinal implant with high resolution. These in vivo and in vitro studies are vital for the continued evaluation of biocompatibility, surgical feasibility, and efficacy of the implant. The results from these studies will further demonstrate the commercial viability of the technology under development.