2022
Enhanced Network in Corticospinal Tracts after Infused Mesenchymal Stem Cells in Spinal Cord Injury
Hirota R, Sasaki M, Kataoka-Sasaki Y, Oshigiri T, Kurihara K, Fukushi R, Oka S, Ukai R, Yoshimoto M, Kocsis JD, Yamashita T, Honmou O. Enhanced Network in Corticospinal Tracts after Infused Mesenchymal Stem Cells in Spinal Cord Injury. Journal Of Neurotrauma 2022, 39: 1665-1677. PMID: 35611987, PMCID: PMC9734021, DOI: 10.1089/neu.2022.0106.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAxonsMammalsMesenchymal Stem CellsNerve RegenerationPyramidal TractsRecovery of FunctionSpinal CordSpinal Cord InjuriesConceptsSpinal cord injuryCorticospinal tractMesenchymal stem cellsCord injurySpinal cordSpontaneous recoveryInfused mesenchymal stem cellsLimited spontaneous recoveryDorsal corticospinal tractLateral corticospinal tractStem cellsCST pathwayCST projectionsSCI inductionMSC infusionAxonal sproutingFunctional recoveryLateral funiculusIntravenous infusionAxonal tracerLesion coreMotor pathwaysFunctional improvementCircuit reorganizationMajor projections
2013
Sural nerve defects after nerve biopsy or nerve transfer as a sensory regeneration model for peripheral nerve conduit implantation
Radtke C, Kocsis J, Reimers K, Allmeling C, Vogt P. Sural nerve defects after nerve biopsy or nerve transfer as a sensory regeneration model for peripheral nerve conduit implantation. Medical Hypotheses 2013, 81: 500-502. PMID: 23867139, DOI: 10.1016/j.mehy.2013.06.020.Peer-Reviewed Original ResearchMeSH KeywordsBiopsyHumansMicrosurgeryNerve RegenerationPeripheral Nerve InjuriesSural NerveTransplantation, AutologousConceptsConduit implantationNerve repairNerve biopsyNerve injurySural nerveAxonal regenerationNerve defectsAcute peripheral nerve injuryHuman nerve injurySural nerve graftRecovery of sensationPeripheral nerve injuryVon Frey filamentsExtent of injuryNerve graft harvestingCold allodyniaMajor morbidityNerve transferNerve stumpNerve graftsNeuroma formationNerve lengthDigital nerveGraft harvestingAutograft treatmentSciatic nerve regeneration is not inhibited by anti-NGF antibody treatment in the adult rat
Lankford K, Arroyo E, Liu C, Somps C, Zorbas M, Shelton D, Evans M, Hurst S, Kocsis J. Sciatic nerve regeneration is not inhibited by anti-NGF antibody treatment in the adult rat. Neuroscience 2013, 241: 157-169. PMID: 23531437, DOI: 10.1016/j.neuroscience.2013.03.024.Peer-Reviewed Original ResearchConceptsNerve growth factorAdult ratsNerve regenerationFunctional recoveryAnti-NGF antibody treatmentElevated nerve growth factorUnilateral sciatic nerve crushDorsal root ganglion neuronsAnti-NGF antibodySciatic nerve crushType of painVehicle-treated animalsSciatic nerve regenerationPost nerve injuryNovel therapeutic approachesCell body sizePeripheral nerve regenerationFluro-GoldPeripheral nervous system developmentNerve injuryPain modelNerve crushPain managementAntibody treatmentGait recovery
2009
Peripheral glial cell differentiation from neurospheres derived from adipose mesenchymal stem cells
Radtke C, Schmitz B, Spies M, Kocsis J, Vogt P. Peripheral glial cell differentiation from neurospheres derived from adipose mesenchymal stem cells. International Journal Of Developmental Neuroscience 2009, 27: 817-823. PMID: 19699793, DOI: 10.1016/j.ijdevneu.2009.08.006.Peer-Reviewed Original ResearchConceptsMesenchymal stem cellsStem cellsGlial-like cellsAdipose-derived mesenchymal stem cellsGlial cell differentiationPeripheral glial cellsGrowth factorEpidermal growth factorGrowth factor receptorMitogen withdrawalFibroblast growth factorBasic fibroblast growth factorCell differentiationDorsal root ganglion neuronsSchwann cell marker S100P75 nerve growth factor receptorAdipose-derived stem cellsNerve growth factor receptorCellular aggregatesSimultaneous expressionOlfactory Ensheathing CellsAppropriate inductionFactor receptorNeurospheresGlia markers
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 ResearchMeSH KeywordsAnimalsCell TransplantationDemyelinating DiseasesDisease Models, AnimalHumansMyelin SheathNerve RegenerationConceptsMultiple sclerosisInjury modelSpinal cord injuryCell-based strategiesAxon lossNerve compressionNeuroprotective potentialCord injuryFunctional outcomeClinical studiesMS lesionsTherapeutic goalsVulnerable axonsCellular transplantationNeurological disordersDemyelinationRemyelinationNeuroprotectionPotential repair strategiesCell typesSclerosisTransplantationInjuryLesionsAxons
2006
Myelination and nodal formation of regenerated peripheral nerve fibers following transplantation of acutely prepared olfactory ensheathing cells
Dombrowski MA, Sasaki M, Lankford KL, Kocsis JD, Radtke C. Myelination and nodal formation of regenerated peripheral nerve fibers following transplantation of acutely prepared olfactory ensheathing cells. Brain Research 2006, 1125: 1-8. PMID: 17112480, PMCID: PMC2673087, DOI: 10.1016/j.brainres.2006.09.089.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAnimals, Genetically ModifiedCell Adhesion Molecules, NeuronalCell TransplantationGreen Fluorescent ProteinsImmunohistochemistryMicroscopy, ImmunoelectronMyelin SheathNAV1.6 Voltage-Gated Sodium ChannelNerve RegenerationNeurofilament ProteinsNeurogliaOlfactory BulbRanvier's NodesRatsRats, Sprague-DawleySciatic NeuropathySodium ChannelsTime FactorsConceptsPeripheral nerve fibersPeripheral nervesNodes of RanvierFunctional outcomeAxonal regenerationNerve fibersRegenerated peripheral nerve fibersSciatic nerve crush lesionNerve crush lesionPeripheral-type myelinSpinal cord resultsTransplantation of olfactoryPeripheral axonal regenerationParanodal CasprCrush lesionCord resultsFunctional improvementOlfactory bulbTransection siteTransgenic ratsLesion zoneNerveNodal formationTransplantation siteOECs
2001
[The role of transplanted astrocytes for the regeneration of CNS axons].
Imaizumi T, Lankford K, Kocsis J, Hashi K. [The role of transplanted astrocytes for the regeneration of CNS axons]. Brain And Nerve 脳と神経 2001, 53: 632-8. PMID: 11517487.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAstrocytesAxonsCentral Nervous SystemElectrophysiologyNerve RegenerationRatsRats, WistarSchwann CellsConceptsCompound action potentialRegenerated axonsSC transplantationAxonal regenerationAdult ratsLong-tract axonsMyelin associated proteinsDorsal column axonsRegeneration of axonsDC axonsCell transplantationDorsal rootsNeonatal ratsSpinal cordReduction of scarsHistological examinationTransplantationMammalian CNSCNS axonsAction potentialsAxonsMyelin formationLesionsThree daysRatsTransplantation of an acutely isolated bone marrow fraction repairs demyelinated adult rat spinal cord axons
Sasaki M, Honmou O, Akiyama Y, Uede T, Hashi K, Kocsis J. Transplantation of an acutely isolated bone marrow fraction repairs demyelinated adult rat spinal cord axons. Glia 2001, 35: 26-34. PMID: 11424189, PMCID: PMC2605363, DOI: 10.1002/glia.1067.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAnimals, NewbornBeta-GalactosidaseBone Marrow TransplantationCells, CulturedEthidiumGlial Fibrillary Acidic ProteinImmunohistochemistryMiceMice, TransgenicMyeloid Progenitor CellsNerve Fibers, MyelinatedNerve RegenerationNeurogliaRatsRats, WistarRecovery of FunctionSpinal CordSpinal Cord InjuriesConceptsBone marrow cellsSpinal cordMyelin-forming cellsMarrow cellsDemyelinated rat spinal cordRat spinal cord axonsDorsal column lesionBone marrow cell fractionRat spinal cordX-irradiation treatmentSpinal cord axonsLacZ transgenic miceSchwann cell myelinationCell fractionCell transplantation techniquesDorsal funiculusPeripheral patternTransgenic miceTransplantation techniquesHematopoietic stem cellsIsolated cell fractionsCordFemoral bonePrecursor cellsTransplantation
2000
Transplantation of olfactory ensheathing cells or Schwann cells restores rapid and secure conduction across the transected spinal cord
Imaizumi T, Lankford K, Kocsis J. Transplantation of olfactory ensheathing cells or Schwann cells restores rapid and secure conduction across the transected spinal cord. Brain Research 2000, 854: 70-78. PMID: 10784108, DOI: 10.1016/s0006-8993(99)02285-4.Peer-Reviewed Original ResearchConceptsRegenerated axonsCell transplantationSpinal cordSchwann cellsTransection siteIsolated spinal cord preparationSpinal cord preparationTransplantation of olfactoryRat spinal cordSpinal cord axonsConduction velocity measurementsTransplantation of cellsCord preparationDorsal columnsAxonal regenerationAxon areaTransplantationImpulse conductionHost tractElectrophysiological recordingsAxonsNormal axonsDonor cellsNeuronal sourcesCord
1998
Peripheral Axotomy Induces Long-Term c-Jun Amino-Terminal Kinase-1 Activation and Activator Protein-1 Binding Activity by c-Jun and junD in Adult Rat Dorsal Root Ganglia In Vivo
Kenney A, Kocsis J. Peripheral Axotomy Induces Long-Term c-Jun Amino-Terminal Kinase-1 Activation and Activator Protein-1 Binding Activity by c-Jun and junD in Adult Rat Dorsal Root Ganglia In Vivo. Journal Of Neuroscience 1998, 18: 1318-1328. PMID: 9454841, PMCID: PMC2605350, DOI: 10.1523/jneurosci.18-04-01318.1998.Peer-Reviewed Original ResearchConceptsC-Jun proteinC-JunC-Jun amino-terminal kinase 1Nerve injuryAxonal regenerationAmino-terminal phosphorylationLumbar dorsal root ganglion neuronsActivator protein-1 bindingEarly post-injury periodJun kinase activationAdult rat dorsal root gangliaDorsal root ganglion neuronsRat dorsal root gangliaKinase 1 activationC-Jun phosphorylationSciatic nerve injuryActivator protein-1 binding activityPost-injury periodSciatic nerve transectionAdult rat DRGDorsal root gangliaLong-term upregulationPeripheral axonal regenerationAP-1 bindingProtein-1 bindingMechanisms of enhancement of neurite regeneration in vitro following a conditioning sciatic nerve lesion
Lankford K, Waxman S, Kocsis J. Mechanisms of enhancement of neurite regeneration in vitro following a conditioning sciatic nerve lesion. The Journal Of Comparative Neurology 1998, 391: 11-29. PMID: 9527536, PMCID: PMC2605358, DOI: 10.1002/(sici)1096-9861(19980202)391:1<11::aid-cne2>3.0.co;2-u.Peer-Reviewed Original ResearchConceptsDorsal root gangliaConditioning lesionNerve injuryNerve regenerationAffected dorsal root ganglionControl dorsal root gangliaDenervated peripheral nervePrior nerve injurySciatic nerve lesionCultured DRG neuronsSciatic nerve transectionPeripheral target tissuesPeripheral nerve stumpRapid nerve regenerationAbility of neuronsSecond axotomyNerve lesionsDRG neuronsNerve transectionNerve stumpRoot gangliaControl neuronsPeripheral nervesNerve tractsAdult rats
1996
Chapter 5 Cellular mechanisms regulating neurite initiation
Lankford K, Kenney A, Kocsis J. Chapter 5 Cellular mechanisms regulating neurite initiation. Progress In Brain Research 1996, 108: 55-81. PMID: 8979794, DOI: 10.1016/s0079-6123(08)62532-7.Peer-Reviewed Original ResearchConceptsNeurite initiationImmediate early genesGrowth cone behaviorEarly genesNeurite formationCell typesCellular mechanismsNeurite outgrowthCellular changesCone behaviorCritical roleMacromolecular levelOutgrowthInitial eventPossible roleMorphological changesProtein 43Complex processMorphogenesisGenesMicrotubulesInitiationProteinCalcium transientsMechanism
1991
Tea‐sensitive potassium channels and inward rectification in regenerated rat sciatic nerve
Gardon T, Kocsis J, Waxman S. Tea‐sensitive potassium channels and inward rectification in regenerated rat sciatic nerve. Muscle & Nerve 1991, 14: 640-646. PMID: 1922170, DOI: 10.1002/mus.880140707.Peer-Reviewed Original ResearchConceptsCompound action potentialRat sciatic nerveNerve crushRegenerated axonsSciatic nerveRegenerated nervesInward rectificationIntra-axonal recording techniquesAdult rat sciatic nerveTEA-sensitive potassium channelsPotassium channelsRegenerated rat sciatic nerveSucrose gap recordingsSciatic nerve crushPeripheral nerve axonsWhole nerve recordingsIntra-axonal recordingsVoltage-sensitive sodium channelsCrush injuryNormal nervesSensitive relaxationRepetitive stimulationAfterhyperpolarizationGap recordingsNerve recordings
1987
Axonal GABA receptors are selectively present on normal and regenerated sensory fibers in rat peripheral nerve
Bhisitkul R, Villa J, Kocsis J. Axonal GABA receptors are selectively present on normal and regenerated sensory fibers in rat peripheral nerve. Experimental Brain Research 1987, 66: 659-663. PMID: 3038587, DOI: 10.1007/bf00270698.Peer-Reviewed Original ResearchConceptsGamma-aminobutyric acidVentral root fibersGABA receptorsRoot fibersSensory fibersPeripheral nervesSensory axonsRegenerated sensory axonsSucrose gap chamberPeripheral nerve fibersRat peripheral nerveDorsal root fibersMammalian peripheral nervesAgonist baclofenNerve crushDorsal rootsAgonist muscimolSciatic nerveNerve fibersRat peripheral nerve fibersNerveReceptorsMuscimolSelective presenceAxonsNodal spacing along regenerated axons following a crush lesion of the developing rat sciatic nerve.
Hildebrand C, Mustafa G, Bowe C, Kocsis J. Nodal spacing along regenerated axons following a crush lesion of the developing rat sciatic nerve. Brain Research 1987, 429: 147-54. PMID: 3567658, DOI: 10.1016/0165-3806(87)90148-9.Peer-Reviewed Original ResearchMeSH KeywordsAge FactorsAnimalsFemaleMaleMicroscopy, ElectronMyelin SheathNerve RegenerationRanvier's NodesRatsRats, Inbred StrainsSpinal NervesConceptsRat sciatic nerveSciatic nerveRegenerated nervesCrush lesionRegenerated rat sciatic nerveNewborn rat pupsSciatic nerve axonsPostnatal ageRegenerated axonsPostnatal eventsRat pupsNerveNerve axonsMyelin sheathL increaseAxonsWeeksBirthAgeLesionsMyelinationSignsRemodellingSuch signsLength growthChapter 8 Ionic channel organization of normal and regenerating mammalian axons
Kocsis J, Waxman S. Chapter 8 Ionic channel organization of normal and regenerating mammalian axons. Progress In Brain Research 1987, 71: 89-101. PMID: 2438722, DOI: 10.1016/s0079-6123(08)61816-6.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAxonsIon ChannelsMotor NeuronsNerve RegenerationNeurons, AfferentPeripheral NervesPotassiumSodiumConceptsNerve fibersPeripheral nervesRegenerated nerve fibersCell remodellingNormal developmentMammalian nerve fibresSchwann cellsElectrophysiological characteristicsFine caliberMyelinated axonsImmature axonsAxonal growthMammalian axonsNerveNormal maturationRemodelling occursAxonsCell arrestRemodellingTime courseMyelinIonic channelsLong termMaturationTime of maturation
1985
Myelin sheath remodelling in regenerated rat sciatic nerve
Hildebrand C, Kocsis J, Berglund S, Waxman S. Myelin sheath remodelling in regenerated rat sciatic nerve. Brain Research 1985, 358: 163-170. PMID: 2416385, DOI: 10.1016/0006-8993(85)90960-6.Peer-Reviewed Original ResearchConceptsRat sciatic nerveSciatic nerveRegenerated nervesAdult rat sciatic nerveRegenerated rat sciatic nerveNormal control nervesLight microscopic examinationAction potential waveformCrush lesionMonths survivalNerve segmentsControl nervesSame nerveIndividual nervesNerve fibersNerveShort sheathMyelin layersMyelin sheathPotassium channelsMicroscopic examination
1984
Retrograde impulse activity and horseradish peroxidase tracig of nerve fibers entering neuroma studied in vitro
Kocsis J, Preston R, Targ E. Retrograde impulse activity and horseradish peroxidase tracig of nerve fibers entering neuroma studied in vitro. Experimental Neurology 1984, 85: 400-412. PMID: 6745381, DOI: 10.1016/0014-4886(84)90150-x.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsElectrophysiologyHorseradish PeroxidaseNerve FibersNerve RegenerationNeuromaPeroxidasesRatsRats, Inbred Strains
1983
Long-term regenerated nerve fibres retain sensitivity to potassium channel blocking agents
Kocsis J, Waxman S. Long-term regenerated nerve fibres retain sensitivity to potassium channel blocking agents. Nature 1983, 304: 640-642. PMID: 6308475, DOI: 10.1038/304640a0.Peer-Reviewed Original ResearchMeSH Keywords4-AminopyridineAction PotentialsAminopyridinesAnimalsCell DifferentiationIon ChannelsMiceNerve Fibers, MyelinatedNerve RegenerationConceptsNerve fibersPotassium channelsMyelinated peripheral nerve fibresAxon segmentsPeripheral nerve fibersAxon sproutsEndoneurial tubesNerve crushFunctional recoveryFunctional organizationMyelinated fibersAxon cylindersSchwann cellsBurst activityMyelinated axonsMammalian axonsAxonsPeripheral connectionsMembrane depolarizationBasement membraneK channelsRegenerated fibersAxon maturation
1982
Regenerating mammalian nerve fibres: changes in action potential waveform and firing characteristics following blockage of potassium conductance
Kocsis J, Waxman S, Hildebrand C, Ruiz J. Regenerating mammalian nerve fibres: changes in action potential waveform and firing characteristics following blockage of potassium conductance. Proceedings Of The Royal Society B 1982, 217: 77-87. PMID: 6131423, DOI: 10.1098/rspb.1982.0095.Peer-Reviewed Original ResearchMeSH KeywordsAction PotentialsAminopyridinesAnimalsAxonsIon ChannelsMaleNerve RegenerationNeural ConductionPotassiumRatsConceptsRegenerating axonsNerve fibersFiring propertiesAction potentialsPotassium conductancePotassium channelsCompound action potentialSciatic nerve fibersEarly regenerating axonsAction potential waveformRat nerve fibresMammalian nerve fibresDemyelinated axonsMyelinated fibersExtracellular applicationAxonsRecording techniquesSingle stimulusFiring characteristicsPotential waveformPresent study