grant

Oxytocin-mediated modulation of peripheral mechanical sensibility after injury

Organization WAKE FOREST UNIVERSITY HEALTH SCIENCESLocation WINSTON-SALEM, UNITED STATESPosted 15 Apr 2022Deadline 31 Mar 2027
NIHUS FederalResearch GrantFY2025AcuteAcute PainAcutely painfulAddressAffectAnimal BehaviorAnimalsAttentionAutomobile DrivingBehaviorBehavioralBlood PlasmaCNS Nervous SystemCentral Nervous SystemChronicClosure by LigationCommon Rat StrainsDataDevelopmentDiseaseDisorderDoseDrug KineticsExposure toFiberGoalsHourHumanHypersensitivityIV InfusionInfusionInfusion proceduresInjuryIntravenous infusion proceduresJointsLigationLong-term painMaintenanceMechanicsMechanoreceptorsMediatingMedulla SpinalisModern ManModificationNerve BlockNerve CellsNerve Impulse TransmissionNerve TransmissionNerve UnitNervous SystemNeural BlockNeural BlockadeNeural CellNeuraxisNeurobiologyNeurocyteNeurologic Body SystemNeurologic Organ SystemNeuronal TransmissionNeuronsNeuropathyNociceptionNociceptorsOcytocinOperative ProceduresOperative Surgical ProceduresOxytocinPainPain ControlPain TherapyPain managementPainfulPatientsPeripheralPeripheral NervesPersistent painPharmacodynamicsPharmacokineticsPharmacologyPhenotypePhysiologicPhysiologicalPlacebosPlasmaPlasma SerumPost-operative PainPostoperative PainProcessPropertyProphylactic treatmentProphylaxisPublishingRatRats MammalsRattusRecombinant OxytocinRecoveryResearchResolutionReticuloendothelial System, Serum, PlasmaRoleSensorySham TreatmentSiteSpeedSpinal CordSpinal NervesSpinal nerve structureStimulusSurgicalSurgical InterventionsSurgical ProcedureTactileTestingTimeTraumaTraumatic injuryWorkacute to chronic pain transitionaxon signalingaxon-glial signalingaxonal signalingbasebaseschronic pain transitionconstant paindesensitizationdevelopmentaldrivingelectrical propertyglia signalingglial signalinginfusionsinjuredinjuriesinjury responseintravenous infusionlasting painmechanicmechanicalmechanical stimulusnerve damagenerve injurynerve signalingneural injuryneural signalingneurobiologicalneuronalneuronal signalingneuropathicneurophysiologicalneurophysiologyneurotransmissionnociceptivenociceptive neuronson-going painongoing painpain after surgerypain chronificationpain interventionpain reductionpain reliefpain treatmentpain-sensing neuronspain-sensing sensory neuronspain-sensing somatosensory neuronspharmacodynamic modelpost-surgical painpostsurgical painreceptive fieldreduce painrelieve painresolutionsresponseresponse to injurysensory inputsham therapysocial rolesurgerysynergismtherapy optimizationtransition to chronic paintranslational studytreatment optimization
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Full Description

SUMMARY.
The current proposal addresses fundamental neurophysiological questions related to oxytocin (OXT)
pharmacology and pain neurobiology in normal and nerve injury settings. We aim to define (a) the OXT PK/PD
relationships on fast-conducting afferents (A-fibers), both tactile (LTMRs: low threshold mechanoreceptors) and
nociceptive (AHTMRs: A-fiber high threshold mechanoreceptors), (b) to study the effects of L5 SNL at the peak
of maximal sensitization (week 2) on injured (L5) and uninjured (L4) afferents and the OXT-mediated modulation
of these sensitization process and (c) to correlate the OXT-induced modulation of sensibility (L4) and excitability
(L5) with the animal behavior (normal or abnormal) after recovery (weeks 8-12).
Our working hypothesis has two parts: 1) that A-fibers response to injury (LTMR: desensitization and AHTMR:
sensitization) is critical for the development of a peripheral mediated neuropathic state and 2) that OXT can
resolve this state and modulate the recovery by rescuing these afferents from they abnormal excitability. We
anticipate that this research will contribute to understanding the physiological effects of OXT, how much of overall
central effects can be explained by the OXT peripheral modulation (interaction with Project 2, Dr. Martin), and
how these effects can be optimized for the treatment of pain in human patients (interaction with Project 3, Dr.
Eisenach).

Grant Number: 5P01NS119159-04
NIH Institute/Center: NIH
Principal Investigator: Mario Boada

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