grant

Mechanisms that support Raphespinal tract plasticity and regeneration after spinal cord injury

Organization YALE UNIVERSITYLocation NEW HAVEN, UNITED STATESPosted 1 Apr 2025Deadline 31 Mar 2027
NIHUS FederalResearch GrantFY202621+ years old5-HT5-Hydroxytryptamine5HTAI AugmentedAI assistedAI drivenAI enhancedAI integratedAI poweredAcuteAdoptionAdultAdult HumanAnatomic SitesAnatomic structuresAnatomyArtificial Intelligence enhancedAugmented by AIAugmented by the AIAugmented with AIAugmented with the AIAutomobile DrivingAxonAxon TerminalsBody TissuesBruiseCNS Nervous SystemCNS traumaCell Communication and SignalingCell SignalingCentral Nervous SystemCervicalCervical InjuryCervical spinal cord injuryChronicClinicalContusionsCorticospinal TractsDREADDsDataData SetDiseaseDisorderDisparateEnteramineExpression SignatureExtremitiesGene Expression ProfileGene TranscriptionGeneralized GrowthGenesGeneticGenetic TranscriptionGrowthHippophaineHumanImageInjuryInterventionIntracellular Communication and SignalingIntraspinal InjectionsLaboratoriesLesionLimb structureLimbsLocationLocomotionMediatingMedical RehabilitationMedulla SpinalisMiceMice MammalsModelingModern ManMolecularMotorMotor PathwaysMurineMusNatural regenerationNerve CellsNerve UnitNeural CellNeuraxisNeurocyteNeuronsNeurostimulation procedures of spinal cord tissueNociceptionNon-TrunkPathway interactionsPatientsPersonsPresynaptic Nerve EndingsPresynaptic TerminalsRNA ExpressionRecoveryRecovery of FunctionRegenerationRehabilitationRehabilitation therapyReporterRoleSCI PatientsSensorySerotoninSignal TransductionSignal Transduction SystemsSignalingSiteSpinalSpinal CordSpinal Cord ContusionsSpinal Cord StimulationSpinal Cord TraumaSpinal InjectionsSpinal TraumaSpinal cord injuredSpinal cord injurySpinal cord injury patientsSynapsesSynapticSynaptic BoutonsSynaptic TerminalsSynaptic Vesicle P38 Membrane ProteinSynaptic Vesicle Protein P38SynaptophysinTherapeutic InterventionTissue GrowthTissuesTitrationsTracerTranscriptionTraumaTraumatic CNS injuryTraumatic Myelopathyadulthoodartificial intelligence assistedartificial intelligence augmentedartificial intelligence drivenartificial intelligence integratedartificial intelligence poweredaxon growthaxon regenerationaxonal growthaxonal regenerationbiological signal transductioncentral nervous system traumadesigner receptors exclusively activated by designer drugsdrivingeffective therapyeffective treatmentenhanced with AIenhanced with Artificial Intelligencefunctional gainfunctional recoverygene expression patterngene expression signatureglobal gene expressionglobal transcription profilehigh rewardhigh riskimagingin vivoinjuredinjuriesintervention therapykinematic modelkinematicsmotor rehabmotor rehabilitationmotor rehabilitative therapyneural controlneural regulationneuromodulationneuromodulatoryneuronalneuroregulationnociceptivenovelontogenypathwaypatient prognosispreventpreventingprogramsraphe nucleiraphe nucleus magnusregeneraterehab therapyrehabilitativerehabilitative therapyrepairrepairedsequencing platformsocial rolespatial RNA sequencingspatial gene expression analysisspatial gene expression profilingspatial resolved transcriptome sequencingspatial temporal transcriptomicsspatial transcriptome analysisspatial transcriptome profilingspatial transcriptome sequencingspatial transcriptomicsspatially resolved transcriptomicsspatio transcriptomicsspatiotemporal gene expression analysisspatiotemporal gene expression patternsspatiotemporal transcriptomicssynapsetheoriestranscriptional profiletranscriptional signaturetranscriptometraumatic central nervous system injury
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Full Description

SUMMARY
The adult spinal cord is incapable of self-repair after injury or disease, thus leading to lifelong sensory, autonomic, and
motor functional deficits. Rehabilitation remains the only effective treatment after CNS trauma, however the anatomical
and molecular substrates that support rehab-induced functional re-enforcement and recovery are known. Central to the
recovery of voluntary motor function is the capacity for supraspinal circuits to regain access to spinal motor centers. The
raphespinal tract (RpST) innervates all spinal lamina and has been shown to be remarkably plastic after spinal cord injury
(SCI). Here, we propose to use anatomy, spatial transcriptomics and intersectional in vivo chemogenetics to define the
capacity and necessity of intact and lesioned supraspinal RpST terminals to support rehab-induced functional recovery
after SCI.

Grant Number: 5R21NS139481-02
NIH Institute/Center: NIH
Principal Investigator: William Cafferty

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