2023
Ih current stabilizes excitability in rodent DRG neurons and reverses hyperexcitability in a nociceptive neuron model of inherited neuropathic pain
Vasylyev D, Liu S, Waxman S. Ih current stabilizes excitability in rodent DRG neurons and reverses hyperexcitability in a nociceptive neuron model of inherited neuropathic pain. The Journal Of Physiology 2023, 601: 5341-5366. PMID: 37846879, PMCID: PMC10843455, DOI: 10.1113/jp284999.Peer-Reviewed Original ResearchMeSH KeywordsAction PotentialsAnimalsErythromelalgiaGanglia, SpinalHumansNAV1.7 Voltage-Gated Sodium ChannelNeuralgiaNeuronsNociceptorsRodentiaConceptsFunction Nav1.7 mutationsDorsal root ganglion neuronsSmall DRG neuronsDRG neuronsNav1.7 mutationNeuropathic painGanglion neuronsHuman genetic modelsAction potentialsDRG neuron excitabilityDRG neuron hyperexcitabilityRodent DRG neuronsAP generationCardiac cellsPotential molecular targetsNeuron hyperexcitabilitySevere painPain therapeuticsCNS neuronsExcessive firingNeuron excitabilityCentral neuronsSubthreshold oscillationsHyperexcitabilityNeuronal firing
2022
The fates of internalized NaV1.7 channels in sensory neurons: Retrograde cotransport with other ion channels, axon-specific recycling, and degradation
Higerd-Rusli G, Tyagi S, Liu S, Dib-Hajj F, Waxman S, Dib-Hajj S. The fates of internalized NaV1.7 channels in sensory neurons: Retrograde cotransport with other ion channels, axon-specific recycling, and degradation. Journal Of Biological Chemistry 2022, 299: 102816. PMID: 36539035, PMCID: PMC9843449, DOI: 10.1016/j.jbc.2022.102816.Peer-Reviewed Original ResearchMeSH KeywordsAction PotentialsAxonsHumansIon ChannelsMembrane ProteinsNAV1.7 Voltage-Gated Sodium ChannelSensory Receptor CellsConceptsMembrane proteinsIon channelsNeuronal functionDistinct neuronal compartmentsAxonal membrane proteinsRetrograde traffickingNeuronal polarityRecycling pathwayLate endosomesPlasma membraneSpecific proteinsAxonal traffickingNovel mechanismCell membraneSodium channel NaNeuronal compartmentsMultiple pathwaysLive neuronsVoltage-gated sodium channel NaProteinEndocytosisMembrane specializationsTraffickingMembraneChannel Na
2021
Contributions of NaV1.8 and NaV1.9 to excitability in human induced pluripotent stem-cell derived somatosensory neurons
Alsaloum M, Labau JIR, Liu S, Estacion M, Zhao P, Dib-Hajj F, Waxman SG. Contributions of NaV1.8 and NaV1.9 to excitability in human induced pluripotent stem-cell derived somatosensory neurons. Scientific Reports 2021, 11: 24283. PMID: 34930944, PMCID: PMC8688473, DOI: 10.1038/s41598-021-03608-x.Peer-Reviewed Original ResearchMeSH KeywordsAction PotentialsAutopsyCell DifferentiationElectrophysiologyHumansImmunohistochemistryInduced Pluripotent Stem CellsMembrane PotentialsMutationNAV1.8 Voltage-Gated Sodium ChannelNAV1.9 Voltage-Gated Sodium ChannelNeuronsNeurosciencesPainPatch-Clamp TechniquesProtein IsoformsSensory Receptor CellsSomatosensory CortexConceptsNeuronal excitabilitySomatosensory neuronsPluripotent stem cell-derived sensory neuronsDynamic clamp electrophysiologyTreatment of painPromising novel modalityVoltage-gated sodium channelsSodium channel isoformsNeuronal membrane potentialGenetic knockout modelsNav1.9 currentsPharmacologic blockSensory neuronsNav1.8Cellular correlatesRepetitive firingClamp electrophysiologyExcitabilityNeuronal backgroundNovel modalityChannel isoformsSodium channelsNeuronsNav1.9Knockout models
2013
Burn injury-induced mechanical allodynia is maintained by Rac1-regulated dendritic spine dysgenesis
Tan AM, Samad OA, Liu S, Bandaru S, Zhao P, Waxman SG. Burn injury-induced mechanical allodynia is maintained by Rac1-regulated dendritic spine dysgenesis. Experimental Neurology 2013, 248: 509-519. PMID: 23933578, DOI: 10.1016/j.expneurol.2013.07.017.Peer-Reviewed Original ResearchConceptsDendritic spine dysgenesisWDR neuronsNeuropathic painBurn injurySpine dysgenesisMechanical allodyniaInjury-induced chronic painInjury-induced mechanical allodyniaSpinal cord dorsal hornBurn-injured animalsHindpaw receptive fieldsInjury-induced painNeuropathic pain phenotypesSecond-degree burn injurySecond-degree burn modelDendritic spine morphologyDendritic spine shapeDorsal hornIntractable painMechanical painPain managementChronic painPain phenotypesElectrophysiological signsPreclinical models
2006
Long-term protection of central axons with phenytoin in monophasic and chronic-relapsing EAE
Black JA, Liu S, Hains BC, Saab CY, Waxman SG. Long-term protection of central axons with phenytoin in monophasic and chronic-relapsing EAE. Brain 2006, 129: 3196-3208. PMID: 16931536, DOI: 10.1093/brain/awl216.Peer-Reviewed Original ResearchMeSH KeywordsAction PotentialsAdministration, OralAnimalsAxonsCell CountCervical VertebraeChronic DiseaseEncephalomyelitis, Autoimmune, ExperimentalImmunohistochemistryInjections, SubcutaneousMiceMice, Inbred C57BLMyelin ProteinsMyelin-Associated GlycoproteinMyelin-Oligodendrocyte GlycoproteinNeural ConductionPhenytoinRecurrenceSodium Channel BlockersSpinal CordTreatment OutcomeConceptsExperimental autoimmune encephalomyelitisC57/BL6 miceChronic-relapsing experimental autoimmune encephalomyelitisBL6 miceLong-term protectionAxonal degenerationClinical statusDays post-EAE inductionMurine experimental autoimmune encephalomyelitisLong-term protective effectPhenytoin-treated miceInflammatory cell infiltrationDorsal column axonsCompound action potentialSodium channel blockersAutoimmune encephalomyelitisAxonal lossPhenytoin treatmentUntreated miceNeuroinflammatory diseasesDorsal columnsMultiple sclerosisCNS injuryCell infiltrationCorticospinal tract