grant

Drug Screening Platform in the Light-Responsive Human Eye

Organization EYESCREEN, INC.Location SALT LAKE CITY, UNITED STATESPosted 1 Apr 2025Deadline 31 Mar 2027
NIHUS FederalResearch GrantFY2025(TNF)-α21+ years oldAchievementAchievement AttainmentAddressAdultAdult HumanAffectAge related macular degenerationAge-Related MaculopathyAgingAmericanAnimal ExperimentsAnimal ModelAnimal Models and Related StudiesAnimal TestingAnimalsAnti-InflammatoriesAnti-Inflammatory AgentsAnti-inflammatoryAreaAssayAutopsyBenchmarkingBest Practice AnalysisBioassayBiological AssayBiomedical EngineeringBiomedical ResearchBiotechBiotechnologyBlindnessBody TissuesCachectinCell BodyCell Communication and SignalingCell Culture TechniquesCell LineCell SignalingCellLineCellsClinicalClinical TrialsCollaborationsCustomDNA TherapyDataDegenerative Neurologic DisordersDependenceDeteriorationDevelopmentDiabetic RetinopathyDiminished VisionDiseaseDisorderDoppler OCTDrug FormulationsDrug ScreeningDrug TargetingDrugsDysfunctionElectroretinographyEnsureEnvironmentExposure toEyeEye BanksEye diseasesEyeballFunctional disorderFutureGene Transfer ClinicalGenetic InterventionGlaucomaGliaGlial CellsGoalsHourHumanHuman BiologyHypoxiaHypoxicIncubatedInflammationIntracellular Communication and SignalingInvestigational DrugsInvestigational New DrugsIschemiaKolliker's reticulumLaboratoriesLibrariesLifeLightLinkLionsLow VisionMacrophage-Derived TNFManualsMeasuresMedicationMetabolicMiceMice MammalsModelingModern ManMonkeysMonocyte-Derived TNFMurineMusNational Eye InstituteNerve CellsNerve UnitNervous System Degenerative DiseasesNeural CellNeural Degenerative DiseasesNeural RetinaNeural degenerative DisordersNeurocyteNeurodegenerative DiseasesNeurodegenerative DisordersNeurogliaNeuroglial CellsNeurologic Degenerative ConditionsNeuronsNon-neuronal cellNonneuronal cellOCT TomographyOptical Coherence TomographyOrganOrganoidsOutcomeOxidative StressOxygen DeficiencyPanthera leoPartial SightPathologicPatient CarePatient Care DeliveryPatient outcomePatient-Centered OutcomesPatient-Focused OutcomesPatientsPersonsPharmaceutical AgentPharmaceutical PreparationsPharmaceuticalsPharmacologic SubstancePharmacological SubstancePhasePhotoradiationPhotoreceptor CellPhotoreceptorsPhotosensitive CellPhysiologicPhysiologicalPhysiologyPhysiopathologyPre-Clinical ModelPreclinical ModelsPreclinical dataProbabilityProcessPublishingReduced VisionReperfusion TherapyReportingResearchResearch ContractsResearch SpecimenRetinaRetina ProperRetinal DiseasesRetinal DisorderSBIRSafetySamplingSightSignal TransductionSignal Transduction SystemsSignalingSmall Business Innovation ResearchSmall Business Innovation Research GrantSocietiesSpecimenSpeedStrains Cell LinesSubnormal VisionSystemTNFTNF ATNF AlphaTNF geneTNF-αTNFATNFαTechnologyTestingTherapeutic InterventionTimeTissue DonorsTissuesTranslationsTumor Necrosis FactorTumor Necrosis Factor-alphaUtahVisionVisual ReceptorVisual impairmentWorkadulthoodage dependent macular degenerationage induced macular degenerationage related macular diseaseage related macular dystrophyagedanimal experimentbenchmarkbio-engineeredbio-engineersbioengineeringbiological engineeringbiological signal transductioncardiovascular healthcare for patientscare of patientscaring for patientscell culturecell culturescell typeclinical applicabilityclinical applicationclinical relevanceclinically relevantcommercializationcostcultured cell linecustomscytokinedata driven platformdata platformdegenerative diseases of motor and sensory neuronsdegenerative neurological diseasesdetermine efficacydevelop therapydevelopmentaldisease stressordrug detectiondrug developmentdrug discoverydrug testingdrug/agentefficacy analysisefficacy assessmentefficacy determinationefficacy evaluationefficacy examinationefficacy testingelectroretinogramevaluate efficacyexamine efficacyexperimental animalexperimental animalsexposed human populationeye centereye disordereye transplantationfeasibility testinggene repair therapygene therapygene-based therapygenetic therapygenomic therapyglaucomatoushuman diseasehuman exposurehuman subjecthuman tissueimprovedin vivoinherited retinal degenerationinsightintervention developmentintervention therapylater in lifelater lifemaculamacularminimize animal testingminimize animal usemodel of animalnecropsynerve cementneurodegenerative illnessneuronalneuroprotectionneuroprotectivenew drug treatmentsnew drugsnew pharmacological therapeuticnew technologynew therapeuticsnew therapynext generation therapeuticsnovelnovel drug treatmentsnovel drugsnovel pharmaco-therapeuticnovel pharmacological therapeuticnovel technologiesnovel therapeuticsnovel therapyocular diseaseocular disorderophthalmic drugophthalmopathyoptical Doppler tomographyoptical coherence Doppler tomographypathophysiologypatient oriented outcomespharmaceuticalpostmortempre-clinicalpreclinicalpreclinical findingspreclinical informationpreservationpreventpreventingprogenitor cell based therapyprogenitor cell therapyprogenitor cell treatmentprogenitor therapyprogenitor treatmentprotective effectreduce animal experimentationreduce animal model usereduce animal testingreduce animal usereduce dependence on animalsreduce reliance on animalsreducing animal numbersreducing animal studiesreperfusionresponserestore sightrestore visionretina diseaseretina disorderretinal neuronretinopathysample collectionscale upsenile macular diseasesight restorationsmall moleculespecimen collectionstem and progenitor cell therapystem cell based therapystem cell mediated therapystem cell organoidsstem cell therapeuticsstem cell therapystem cell treatmentstem cell-based therapeuticstem cell-based treatmentstem cell-derived organoidsstressorsuccesstherapy developmenttimelinetranslationtreatment developmentvision impairmentvision lossvision restorationvisual functionvisual lossvisually impaired
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Full Description

Blinding diseases rob independence from millions of people in aging societies with poor metabolic and
cardiovascular health. There are currently almost 1,000 planned or active clinical trials for investigational new
drugs (INDs) to address AMD, diabetic retinopathy, glaucoma or inherited retinal degenerations. In addition,
stem cell and gene therapies or even whole eye transplantation to restore vision is an active area of research,
currently mostly advanced using animal models. Overall, biomedical research, including pharmaceutical
companies and contract research organizations, use about 100 million mice and 100,000 monkeys every year.
Despite this, translation success has remained poor, at ~5-10%. Our long-term goal is to improve the translation
probability of INDs that enter clinical trials using functionally viable human donor tissues to improve patient care
and reduce animal experiments and suffering. This goal is achieved by developing new technology and assays
to test efficacy and safety of INDs preclinically in functionally viable postmortem human donor eyes. Our recent
ground-breaking work has demonstrated revival of in vivo-like light signaling in postmortem human retinas. Our
central hypothesis is that these human retina samples can be maintained functional for >48-hrs and used
efficiently to screen the efficacy of INDs to protect human neurons and glia from stressors caused by retinal and
neurodegenerative disease before clinical trials. The rationale for this project is that demonstrating that an IND
is not expected to work in human tissue pharmaceutical companies can save >$10M/IND and significant number
of animals by preventing those INDs not expected to work in human tissues from advancing to in vivo animal
testing or clinical trials. On the other hand, our platform can promote advancement of an IND to the clinical trial
and ultimate approval where it could have been otherwise deemed ineffective based on animal experiments,
thus, potentially delivering new life- or sight-saving treatments and multi-billion-dollar revenues for
pharmaceutical companies. Eyescreen, Inc. will test the central hypothesis in Phase 1 and 2 of this SBIR project.
Phase 1 proposes two specific aims. Aim 1: Establish novel ex vivo preclinical models for human ocular
diseases; Aim 2: Development of a multichannel drug screening platform in the light-responsive mouse and
human retina. These aims will scale up access to viable human eyes by restoring and preserving in vivo-like light
responsiveness in eyes procured up to 1-h and stored >48-h post-mortem as well as establish novel new high-
throughput platform (Aim 2) for testing impact of INDs on physiology of human retinal neurons and glia exposed
to disease stressors like ischemia and inflammation (Aim 1). In Phase 2 Eyescreen Inc., in collaboration with the
Vinberg lab, will use these assays to screen clinically approved/failed drugs and compound libraries to test the
hypothesis that our platform can improve translation probability. In addition, Phase 2 will expand the utility of our
platform to study the impact of not only small-molecule drugs, but also gene therapies, in aged and diseased
human eyes.

Grant Number: 1R43EY037154-01
NIH Institute/Center: NIH
Principal Investigator: Jordan Allen

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