2008
18 MULTIPLE SCLEROSIS: REMYELINATION
KOCSIS J, SASAKI M, LANKFORD K, RADTKE C. 18 MULTIPLE SCLEROSIS: REMYELINATION. 2008, 413-435. DOI: 10.1016/b978-012373994-0.50020-8.Peer-Reviewed Original ResearchMyelin-forming cellsMultiple sclerosisConduction abnormalitiesPotential neuroprotective effectsProminent pathological featurePeripheral nervous systemEndogenous progenitor cellsPotassium channel distributionRemyelinated axonsIon channel organizationDemyelinated lesionsNeuroprotective effectsAxonal transectionPathological featuresFunctional deficitsMyelin repairAxonal repairMyelin resultsNervous systemImpulse conductionProgenitor cellsRemyelinationSclerosisTransectionAbnormalities
2007
Demyelinating diseases and potential repair strategies
Radtke C, Spies M, Sasaki M, Vogt PM, Kocsis JD. Demyelinating diseases and potential repair strategies. International Journal Of Developmental Neuroscience 2007, 25: 149-153. PMID: 17408905, PMCID: PMC2692731, DOI: 10.1016/j.ijdevneu.2007.02.002.Peer-Reviewed Original ResearchConceptsMultiple sclerosisInjury modelSpinal cord injuryCell-based strategiesAxon lossNerve compressionNeuroprotective potentialCord injuryFunctional outcomeClinical studiesMS lesionsTherapeutic goalsVulnerable axonsCellular transplantationNeurological disordersDemyelinationRemyelinationNeuroprotectionPotential repair strategiesCell typesSclerosisTransplantationInjuryLesionsAxons
2005
28 Transplantation of Peripheral-Myelin-Forming Cells to Repair Demyelinated Axons
Kocsis J, Sasaki M. 28 Transplantation of Peripheral-Myelin-Forming Cells to Repair Demyelinated Axons. 2005, 421-433. DOI: 10.1016/b978-012738761-1/50029-8.Peer-Reviewed Original ResearchTransplantation of SCsTransplantation of OECsSpinal cord injuryCentral nervous systemSchwann cellsAxonal regenerationBone marrow cellsFunctional recoveryMultiple sclerosisCell transplantationCord injurySpinal cordHind limb locomotor functionContusive spinal cord injuryBone marrow cell transplantationMarrow cellsSpinal cord injury modelMarrow cell transplantationCerebral ischemia modelSpinal cord resultsGlobal neuroprotectionDemyelination modelCord resultsFunctional outcomeDemyelinated axons
2001
Transplantation of Cryopreserved Adult Human Schwann Cells Enhances Axonal Conduction in Demyelinated Spinal Cord
Kohama I, Lankford K, Preiningerova J, White F, Vollmer T, Kocsis J. Transplantation of Cryopreserved Adult Human Schwann Cells Enhances Axonal Conduction in Demyelinated Spinal Cord. Journal Of Neuroscience 2001, 21: 944-950. PMID: 11157080, PMCID: PMC2605383, DOI: 10.1523/jneurosci.21-03-00944.2001.Peer-Reviewed Original ResearchConceptsHuman Schwann cellsSchwann cellsDorsal columnsSural nerveAxonal conductionIntra-axonal recording techniquesDorsal column lesionLegs of patientsDemyelinated spinal cordHuman sural nerveAdult human Schwann cellsFunctional remyelinationExtensive remyelinationCell-based therapiesMultiple sclerosisVascular diseaseSpinal cordWistar ratsConduction blockAdult CNSConduction velocityLesion zoneAction potentialsMonoclonal antibodiesLesions
1987
Physiological effects of 4‐aminopyridine on demyelinated mammalian motor and sensory fibers
Bowe C, Kocsis J, Targ E, Waxman S. Physiological effects of 4‐aminopyridine on demyelinated mammalian motor and sensory fibers. Annals Of Neurology 1987, 22: 264-268. PMID: 2821876, DOI: 10.1002/ana.410220212.Peer-Reviewed Original ResearchConceptsSensory fibersClinical trialsAction potentialsPotassium channel blockadeDorsal root axonsCompound action potentialDorsal spinal rootsSingle action potentialMammalian motorIntrathecal injectionMultiple sclerosisSensory dysfunctionVentral rootsSpinal rootsNeuromuscular disordersSpecific fiber typesElectrophysiological responsesSingle stimulusPhysiological effectsTrialsFiber typesResponseParesthesiaSclerosisDysfunction