The voltage dependence of I(h) in human myelinated axons.
about
Sustained maximal voluntary contraction produces independent changes in human motor axons and the muscle they innervateEffects of hemodiafiltration and high flux hemodialysis on nerve excitability in end-stage kidney diseaseWhy are sensory axons more vulnerable for ischemia than motor axons?Temporal Considerations for Stimulating Spiral Ganglion Neurons with Cochlear Implants.The Ih Channel Gene Promotes Synaptic Transmission and Coordinated Movement in Drosophila melanogaster.Burning pain: axonal dysfunction in erythromelalgia.A 3D Computational Model of Transcutaneous Electrical Nerve Stimulation for Estimating Aβ Tactile Nerve Fiber Excitability.Potassium and the excitability properties of normal human motor axons in vivo.IH activity is increased in populations of slow versus fast motor axons of the ratExcitability properties of motor axons in adults with cerebral palsyThe Temporal Profiles of Changes in Nerve Excitability Indices in Familial Amyloid Polyneuropathy.Chronic inflammatory demyelinating polyradiculoneuropathy: from pathology to phenotype.In vivo loss of slow potassium channel activity in individuals with benign familial neonatal epilepsy in remissionImpaired Axonal Na(+) Current by Hindlimb Unloading: Implication for Disuse Neuromuscular Atrophy.In vivo impact of presynaptic calcium channel dysfunction on motor axons in episodic ataxia type 2.Axonal Excitability in Amyotrophic Lateral Sclerosis : Axonal Excitability in ALS.Predictions of the Contribution of HCN Half-Maximal Activation Potential Heterogeneity to Variability in Intrinsic Adaptation of Spiral Ganglion Neurons.Effects of temperature on simulated electrotonic potentials and their current kinetics of human motor axons at 20°C-42°C.Excitability and the safety margin in human axons during hyperthermia.Persistent alterations in active and passive electrical membrane properties of regenerated nerve fibers of man and mice.Increased HCN channel driven inward rectification in benign cramp fasciculation syndrome.Nerve excitation using an amplitude-modulated signal with kilohertz-frequency carrier and non-zero offset.Volume conductor model of transcutaneous electrical stimulation with kilohertz signals.Accommodation to hyperpolarization of human axons assessed in the frequency domain.Pathophysiology of HNPP explored using axonal excitability.Neurofascin-155 IGG4 Neuropathy: Pathophysiological Insights, Spectrum of Clinical Severity and Response To treatment.Transient impairment of the axolemma following regional anaesthesia by lidocaine in humans.Comparing excitability at 37°C versus at 20°C: Differences between motor and sensory axons.Hyperpolarization-activated cyclic-nucleotide-gated channels potentially modulate axonal excitability at different thresholds.Differences in excitability properties between medial gastrocnemius, tibialis anterior, and abductor pollicis brevis motor axons.Penetration of Action Potentials During Collision in the Median and Lateral Giant Axons of Invertebrates
P2860
Q21132286-440D7326-8C1B-4404-9928-99F2D4562E45Q28487895-71C07E8E-A51A-40DC-B491-5E0E8FE3A240Q28534031-19004B94-9F4F-4C6C-B12C-96FC9E1253C0Q30364519-D1D78C5B-F97F-4190-B2C3-A29275D8F5F9Q30839844-8291DD11-6993-46C6-B634-5B4EF8F1D0E3Q33595891-ECA21F00-B11B-45D3-9349-0C74A87BA2A1Q33689813-E32C071E-F9DD-49DC-AD83-CB33BB866AF9Q33707451-716B4EA8-05EC-4629-84A9-DAD639663BEBQ34241463-E111DF80-DA03-4954-865B-3BE19AF33FEBQ35675829-C552C66E-95ED-4CF2-B0D2-A8C967E3A643Q35830457-5BDEE68D-F830-4D0F-967E-B12E8CC54D41Q36005389-BB810171-9892-4CBF-AF77-4E68F509052AQ36315358-ECF6F257-6192-4D43-9D09-8F709665216DQ36583137-07E772EA-205E-497F-A2D5-BEE622CBB9BCQ36696876-B40632D1-F7F7-4106-B064-2C0D506732F2Q39017694-BCBBEF44-D2E6-450A-8493-9FEB6F478A52Q39109351-7165EE1E-FD91-420C-8EB6-B9D0B705260EQ40194564-A99DCC4A-B5DE-4502-B2EA-8E9CAE0A8548Q40250206-E6BFA7C5-3C40-47E0-B76B-47C2E325F1A6Q40469043-57098893-8EDE-4B9B-A748-E9E1109F7E06Q40571096-7229C71E-C313-4713-B9B3-864F6E0CD2D3Q41851059-7D296E0A-0FE2-4B37-A4E3-708DC4C662F7Q41975735-D43800FF-2B5D-4259-B57B-43162BDF0241Q42388451-8F4E4EB0-7EFF-452C-8468-1A21B9AF37FBQ43631107-CECC4AFB-C25E-44A7-A88C-0DC27DE2A8A6Q47611455-A3BAC89D-C1E8-41B1-B113-5DF3210612BAQ47887252-9313697F-B76A-4B26-A7CE-F9DF65622632Q48119413-A6ADF336-7798-4839-B37F-900FEA037038Q48531133-D8086D5E-84B5-4D98-A185-7EEA42B75B44Q48549303-B931370C-B8EE-4DA7-A75B-1904BB0F35AFQ55015032-28D90BE5-F17B-4320-8A29-8FEE1A1B18DC
P2860
The voltage dependence of I(h) in human myelinated axons.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年学术文章
@wuu
2012年学术文章
@zh
2012年学术文章
@zh-cn
2012年学术文章
@zh-hans
2012年学术文章
@zh-my
2012年学术文章
@zh-sg
2012年學術文章
@yue
2012年學術文章
@zh-hant
name
The voltage dependence of I
@nl
The voltage dependence of I(h) in human myelinated axons.
@en
type
label
The voltage dependence of I
@nl
The voltage dependence of I(h) in human myelinated axons.
@en
prefLabel
The voltage dependence of I
@nl
The voltage dependence of I(h) in human myelinated axons.
@en
P2093
P2860
P1476
The voltage dependence of I(h) in human myelinated axons.
@en
P2093
David Burke
James Howells
Louise Trevillion
P2860
P304
P356
10.1113/JPHYSIOL.2011.225573
P407
P50
P577
2012-02-06T00:00:00Z