about
Carbonic anhydrase generates CO2 and H+ that drive spider silk formation via opposite effects on the terminal domainsRapid rise of extracellular pH evoked by neural activity is generated by the plasma membrane calcium ATPase.Autocrine boost of NMDAR current in hippocampal CA1 pyramidal neurons by a PMCA-dependent, perisynaptic, extracellular pH shiftDouble-barreled and Concentric Microelectrodes for Measurement of Extracellular Ion Signals in Brain Tissue.Carbonic anhydrases CA4 and CA14 both enhance AE3-mediated Cl--HCO3- exchange in hippocampal neurons.Endogenous alkaline transients boost postsynaptic NMDA receptor responses in hippocampal CA1 pyramidal neurons.Carbonic anhydrase generates a pH gradient in Bombyx mori silk glands.Rapid astrocyte death induced by transient hypoxia, acidosis, and extracellular ion shifts.Surface carbonic anhydrase activity on astrocytes and neurons facilitates lactate transport.Role of Na+-H+ and Na+-Ca2+ exchange in hypoxia-related acute astrocyte death.Functional demonstration of surface carbonic anhydrase IV activity on rat astrocytes.Intracellular pH Measurements in Glioblastoma Cells Using the pH-Sensitive Dye BCECF.Effect of divalent cations on AMPA-evoked extracellular alkaline shifts in rat hippocampal slices.Endogenous pH shifts facilitate spreading depression by effect on NMDA receptors.Regulation of postsynaptic Ca2+ influx in hippocampal CA1 pyramidal neurons via extracellular carbonic anhydrase.Activity-evoked extracellular pH shifts in slices of rat dorsal lateral geniculate nucleus.Organization of the filum terminale in the frog.Regulation of intracellular pH in vertebrate central neurons.Fabrication and use of high-speed, concentric h+- and Ca2+-selective microelectrodes suitable for in vitro extracellular recording.Kinetics of activity-evoked pH transients and extracellular pH buffering in rat hippocampal slices.Modulation of extracellular pH by glutamate and GABA in rat hippocampal slices.Elevation and clearance of extracellular K+ following contusion of the rat spinal cord.GABA-sensitivity of dorsal column axons: an in vitro comparison between adult and neonatal rat spinal cords.Extracellular alkaline-acid pH shifts evoked by iontophoresis of glutamate and aspartate in turtle cerebellum.Calcium- and barium-dependent extracellular alkaline shifts evoked by electrical activity in rat hippocampal slices.Temporal resolution of activity-dependent pH shifts in rat hippocampal slices.A bicarbonate-dependent increase in extracellular pH mediated by GABAA receptors in turtle cerebellum.Activity-related extracellular potassium transients in the neonatal rat spinal cord: an in vitro study.pH regulation in the vertebrate central nervous system: microelectrode studies in the brain stem of the lampreyPharmacologic studies of alkaline extracellular pH transients in the in vitro turtle cerebellumBenzolamide inhibits low-threshold calcium currents in hippocampal pyramidal neuronsEndogenous H+ modulation of NMDA receptor-mediated EPSCs revealed by carbonic anhydrase inhibition in rat hippocampusCalcium dependence of glutamate receptor-evoked alkaline shifts in hippocampusAddition of carbonic anhydrase augments extracellular pH buffering in rat cerebral cortexEffects of GABA on axonal conduction and extracellular potassium activity in the neonatal rat optic nerveDepolarization-induced acid secretion in gliotic hippocampal slicesNon-synaptic modulation of dorsal column conduction by endogenous GABA in neonatal rat spinal cordElevation and clearance of extracellular K+ following graded contusion of the rat spinal cordDynamics of extracellular calcium activity following contusion of the rat spinal cordModulation of spreading depression by changes in extracellular pH
P50
Q27684943-0765AAF2-4C2E-46B1-85F9-3172A9CA58FEQ33656834-013EE266-0F4E-439E-86FF-5D46D9C9C061Q34989980-8149CE93-1015-4FC6-959E-E4011ED5F3B6Q36408164-A5FC2EF0-B2AC-4DFB-98CA-D654ADA58878Q37377176-2ED547D9-299E-4788-8F19-AEBE6FB0C2ADQ39333088-12923443-B672-470F-A773-57074C49E1E4Q41996111-9EB41219-5C00-4922-A78F-EB9851E7B658Q43578607-491F5420-2F6D-40D5-9777-BBEC66722C3DQ44295000-EAA7A064-3B5A-424F-A3FD-7B1E6CFF3AAEQ45076775-0457BA19-5BF9-4129-91B1-BA576D61814EQ46787357-60B35F31-AE66-496E-90C7-D6B8FD4EB7E9Q47824501-7BFC1E05-107E-4EAA-B3CE-A846A3488942Q48094495-AF051570-808F-4F63-ADB3-1B45EA4612CDQ48238319-631C77FA-8B4B-4CA5-AC36-AE68718478A4Q48291219-1A1A31C2-C3CF-4DE9-974E-C57E6717DB17Q48312398-014E904A-782F-4538-A930-7474DCC33221Q48452651-44373BB0-3AA0-4CE4-88EC-36FB3E63B5E0Q48533985-FE157D15-E19C-4CD6-A0B1-7C6EFC926C1BQ48556602-FBF8118B-24DB-4FFE-BE8A-34AE51F768D0Q48586019-83E91E0C-2686-4131-9B70-5696ABD8CCEFQ48594661-3D31A005-E9AE-4F96-8976-F8E28458BD50Q48673503-B7F618E8-1954-4EAD-8893-20CD72006A47Q48689545-77783400-1DAB-493E-B6BE-F9141B0411CBQ48821949-71377BCA-10E8-40C3-A0D0-44400411B463Q48855655-9B73A69E-71E5-486A-8ACE-9DA341B80A38Q48904683-5C9DCA0F-BB9B-4DE3-9574-536999BAD305Q48918218-01D7170C-CDB5-4373-B8DE-586B406A667BQ52251608-4FBB188B-4668-4937-9AFF-57E19FEE4874Q69204100-3CDC4793-2971-419A-8456-822FF4F429B4Q69800648-99D3EE62-651C-4C7F-B1BB-E16831BAC4FCQ71365422-916F6DB6-EE0A-4F56-B53A-1CB29969216BQ71657446-8216DF52-DD9F-4820-9570-886758A8E75DQ71683783-6E810163-69B1-4D13-8BC4-0FF19ED386E4Q71959027-FF85133C-D097-46B7-9DC7-7997D93DE7F7Q72067112-B1F9C782-2F3C-43C6-9DCC-A090E0BB2992Q72520265-8CB116C8-6B2B-44E2-95A7-F961F826DC93Q72612653-36C79EB0-D78E-47CC-AB0D-F7056A897A57Q72770942-4C86F44A-2117-4131-9804-B75998B591C8Q72897484-4EBF9BA9-9009-43A8-B33D-BFDB2228867FQ73163289-B6A73520-FC75-4D76-936A-CF0F86EB0434
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Mitchell Chesler
@ast
Mitchell Chesler
@en
Mitchell Chesler
@es
Mitchell Chesler
@nl
Mitchell Chesler
@sl
type
label
Mitchell Chesler
@ast
Mitchell Chesler
@en
Mitchell Chesler
@es
Mitchell Chesler
@nl
Mitchell Chesler
@sl
prefLabel
Mitchell Chesler
@ast
Mitchell Chesler
@en
Mitchell Chesler
@es
Mitchell Chesler
@nl
Mitchell Chesler
@sl
P106
P21
P31
P496
0000-0002-3189-8234
P569
2000-01-01T00:00:00Z