Long-lasting GABA-mediated depolarization evoked by high-frequency stimulation in pyramidal neurons of rat hippocampal slice is attributable to a network-driven, bicarbonate-dependent K+ transient.
about
Role of the neuronal K-Cl co-transporter KCC2 in inhibitory and excitatory neurotransmissionInternational Union of Pharmacology. LXX. Subtypes of gamma-aminobutyric acid(A) receptors: classification on the basis of subunit composition, pharmacology, and function. UpdateTwo developmental switches in GABAergic signalling: the K+-Cl- cotransporter KCC2 and carbonic anhydrase CAVIIGamma oscillation underlies hyperthermia-induced epileptiform-like spikes in immature rat hippocampal slicesIon dynamics during seizuresDepolarizing GABA/glycine synaptic events switch from excitation to inhibition during frequency increases.Suppression of epileptiform activity by high frequency sinusoidal fields in rat hippocampal slicesNeuronal carbonic anhydrase VII provides GABAergic excitatory drive to exacerbate febrile seizuresAstrocytic and neuronal accumulation of elevated extracellular K(+) with a 2/3 K(+)/Na(+) flux ratio-consequences for energy metabolism, osmolarity and higher brain function.Modulation of GABAergic transmission in development and neurodevelopmental disorders: investigating physiology and pathology to gain therapeutic perspectives.Maintenance and termination of neocortical oscillations by dynamic modulation of intrinsic and synaptic excitabilityAcetazolamide and midazolam act synergistically to inhibit neuropathic pain.Nociceptive afferent activity alters the SI RA neuron response to mechanical skin stimulation.Computational modeling reveals dendritic origins of GABA(A)-mediated excitation in CA1 pyramidal neurons.Excitatory effects of parvalbumin-expressing interneurons maintain hippocampal epileptiform activity via synchronous afterdischarges.Cell-attached recordings of responses evoked by photorelease of GABA in the immature cortical neurons.Pharmacotherapeutic targeting of cation-chloride cotransporters in neonatal seizuresCellular and network mechanisms of electrographic seizures.Cation-chloride cotransporters in neuronal development, plasticity and diseaseThe contribution of raised intraneuronal chloride to epileptic network activity.Protein expression and mRNA cellular distribution of the NKCC1 cotransporter in the dorsal root and trigeminal ganglia of the ratNKCC1 upregulation disrupts chloride homeostasis in the hypothalamus and increases neuronal activity-sympathetic drive in hypertension.Calexcitin transformation of GABAergic synapses: from excitation filter to amplifier.Columnar distribution of activity dependent gabaergic depolarization in sensorimotor cortical neurons.Hippocampal neuron firing and local field potentials in the in vitro 4-aminopyridine epilepsy model.GABA(A) receptors: structure and function in the basal gangliaSynchronous GABA-receptor-dependent potentials in limbic areas of the in-vitro isolated adult guinea pig brain.Independent epileptiform discharge patterns in the olfactory and limbic areas of the in vitro isolated Guinea pig brain during 4-aminopyridine treatment.Pubertal Expression of α4βδ GABAA Receptors Reduces Seizure-Like Discharges in CA1 HippocampusActivity-dependent hyperpolarization of EGABA is absent in cutaneous DRG neurons from inflamed rats.Intracellular bicarbonate regulates action potential generation via KCNQ channel modulationEnhancing the function of alpha5-subunit-containing GABAA receptors promotes action potential firing of neocortical neurons during up-states.Potassium diffusive coupling in neural networks.Electroconvulsive therapy stimulus parameters: rethinking dosageSpatial and temporal dynamics in the ionic driving force for GABA(A) receptors.GABAergic synchronization in the limbic system and its role in the generation of epileptiform activity.Mechanisms of physiological and epileptic HFO generation.Cortical inhibition, pH and cell excitability in epilepsy: what are optimal targets for antiepileptic interventions?The neurobiology of opiate motivation.Anion transport and GABA signaling.
P2860
Q21129489-5598CBE2-E514-4408-8522-6B129594717DQ24608968-FB35D111-323C-475C-9571-145AB06E05CBQ24676766-4C005C6B-3F73-4638-A100-A30E0F38542BQ24797094-D30E6AAB-CD5D-46C9-860E-6E4D0F17B31CQ26779710-4D4E31BD-99B9-44C7-8871-8A5D83880CBBQ27345060-FEDEABB9-1088-42AA-AD9B-742A65274A16Q28349377-B8E8A2FF-C4F0-42DD-9C9E-B0BCC26DC5ABQ28512731-BF07AA9E-36E0-4B52-AAEE-3DE9C127D295Q30450219-BECB4745-DA56-447E-803B-4E19F60A3C72Q33659830-653CCBDD-95E1-4ABE-BBFE-237AE032E9E9Q33913540-B4118D03-33B5-4119-99F8-EEBC81BB52BDQ34038813-3CD4C5A1-A508-4FFD-885E-06396C8B6C68Q34297639-586A0BA1-D10F-4DE2-AD1C-1EF9148F7982Q34448117-0B09D7FF-F337-4618-BB9E-5D97BB7508B5Q34491658-C66D9B6C-10B1-4EB9-B512-7AE4703DD18EQ34765445-D8EDF099-B705-4200-9056-CED05FF322DCQ34823865-336381F6-E42B-4CAF-840A-D638F058FF59Q34936366-3093E396-FACE-4550-B63F-1BDEAB5330FBQ34959293-128E3295-166D-4787-9006-9B85691EE387Q35625725-1F2D62D6-42BD-45A7-9DAF-72253BD34D90Q35854882-DFB1E8F6-ABBB-4A4F-B732-342E566AD3EAQ36077873-9E490E37-8B92-4FFA-BD2F-5BF1D2AE9D44Q36389714-549FE275-E930-44FD-98A6-45D112111AF1Q36462900-C78E8EA2-3871-4DB5-8617-39D220B2E02EQ36533217-5AFD291D-5F97-42CE-A4AF-D847C880AC1EQ36820566-7122719E-A21F-4CE9-8616-A9F77B379850Q36917602-507002E1-A94D-4C83-B281-562B75459A5FQ36932134-270B82D9-EF3C-44F2-804F-73564F3FF06BQ37209251-F1BE17A8-4F14-4B07-A0FC-5B92046F7C10Q37412722-D5B39F7D-49B6-4BF4-8EFE-0ACFB2F360EEQ37650249-0418CD80-E001-4992-B594-2D33B114837FQ37718469-B464FD3F-8C9D-4B64-860A-790B96C0A056Q37770177-FB91B37F-75FE-49D4-96F4-B0CD76DBB2EFQ37784121-04A709E4-7CDC-4383-BD74-2499844A8CDAQ37902085-8CB61212-E06A-45FA-BAB8-225CA76A618DQ37908500-9905CA74-5666-4E1D-B24E-39C35D41919BQ37993959-9AF59887-51A3-4D8D-AA34-926D43004A4BQ38034465-E1970EA2-978E-4994-8447-26191332977EQ38048764-978F5C87-CF98-477E-B0EE-113042FA47CAQ38159690-D48F450B-7D79-46F4-BFAC-F0AC3BC46CDB
P2860
Long-lasting GABA-mediated depolarization evoked by high-frequency stimulation in pyramidal neurons of rat hippocampal slice is attributable to a network-driven, bicarbonate-dependent K+ transient.
description
1997 nî lūn-bûn
@nan
1997年の論文
@ja
1997年学术文章
@wuu
1997年学术文章
@zh
1997年学术文章
@zh-cn
1997年学术文章
@zh-hans
1997年学术文章
@zh-my
1997年学术文章
@zh-sg
1997年學術文章
@yue
1997年學術文章
@zh-hant
name
Long-lasting GABA-mediated dep ...... bonate-dependent K+ transient.
@en
Long-lasting GABA-mediated dep ...... bonate-dependent K+ transient.
@nl
type
label
Long-lasting GABA-mediated dep ...... bonate-dependent K+ transient.
@en
Long-lasting GABA-mediated dep ...... bonate-dependent K+ transient.
@nl
prefLabel
Long-lasting GABA-mediated dep ...... bonate-dependent K+ transient.
@en
Long-lasting GABA-mediated dep ...... bonate-dependent K+ transient.
@nl
P50
P1476
Long-lasting GABA-mediated dep ...... rbonate-dependent K+ transient
@en
P2093
P304
P356
10.1523/JNEUROSCI.17-20-07662.1997
P407
P577
1997-10-01T00:00:00Z