Potent block of Cx36 and Cx50 gap junction channels by mefloquine.
about
The position of mefloquine as a 21st century malaria chemoprophylaxisStructural and functional similarities of calcium homeostasis modulator 1 (CALHM1) ion channel with connexins, pannexins, and innexinsProperties of mouse connexin 30.2 and human connexin 31.9 hemichannels: implications for atrioventricular conduction in the heart.The role of pannexin hemichannels in the anoxic depolarization of hippocampal pyramidal cellsModafinil increases arousal determined by P13 potential amplitude: an effect blocked by gap junction antagonistsP2X7 receptor-Pannexin1 complex: pharmacology and signalingModafinil enhances thalamocortical activity by increasing neuronal electrotonic couplingElectrical coupling: novel mechanism for sleep-wake controlMalaria Prevention, Mefloquine Neurotoxicity, Neuropsychiatric Illness, and Risk-Benefit Analysis in the Australian Defence ForceRoles of gap junctions, connexins, and pannexins in epilepsyGap junction connexins in female reproductive organs: implications for women's reproductive healthThe contribution of electrical synapses to field potential oscillations in the hippocampal formationThe pannexins: past and presentRole of the gut endoderm in relaying left-right patterning in miceActive sulforhodamine 101 uptake into hippocampal astrocytesMefloquine and psychotomimetics share neurotransmitter receptor and transporter interactions in vitroThalamic modulation of cingulate seizure activity via the regulation of gap junctions in mice thalamocingulate sliceTales of a Dirty Drug: Carbenoxolone, Gap Junctions, and SeizuresEmerging concepts regarding pannexin 1 in the vasculature.Effect of Mefloquine, a Gap Junction Blocker, on Circadian Period2 Gene Oscillation in the Mouse Suprachiasmatic Nucleus Ex Vivo.Rapid developmental maturation of neocortical FS cell intrinsic excitability.Mefloquine damage vestibular hair cells in organotypic cultures.Gap junction coupling and calcium waves in the pancreatic isletReliable coding emerges from coactivation of climbing fibers in microbands of cerebellar Purkinje neurons.The developmental decrease in REM sleep: the role of transmitters and electrical coupling.Oculopalatal tremor explained by a model of inferior olivary hypertrophy and cerebellar plasticity.Pannexin 1: the molecular substrate of astrocyte "hemichannels".Gap junction blockers: a potential approach to attenuate morphine withdrawal symptoms.Brain stimulation reward is integrated by a network of electrically coupled GABA neurons.Mefloquine blockade of Pannexin1 currents: resolution of a conflict.Oocyte triplet pairing for electrophysiological investigation of gap junctional coupling.Meclofenamic acid improves the signal to noise ratio for visual responses produced by ectopic expression of human rod opsinOptogenetic mapping of cerebellar inhibitory circuitry reveals spatially biased coordination of interneurons via electrical synapsesEffects of proarrhythmic drugs on relaxation time and beating pattern in rat engineered heart tissue.Correlative studies of gating in Cx46 and Cx50 hemichannels and gap junction channels.Two functionally distinct networks of gap junction-coupled inhibitory neurons in the thalamic reticular nucleus.Neuron to astrocyte communication via cannabinoid receptors is necessary for sustained epileptiform activity in rat hippocampus.Triarylmethanes, a new class of cx50 inhibitors.Human connexin channel specificity of classical and new gap junction inhibitors.Spontaneous rhythmogenic capabilities of sympathetic neuronal assemblies in the rat spinal cord slice.
P2860
Q21034126-F3471BA4-7FBD-4DDB-83D7-39562069012CQ24307848-03236AFC-88C9-4731-8DAB-7EDF4AFA5999Q24548349-B90E7046-36D9-431F-9742-C5FB0D5335FBQ24632105-18982854-A3D7-44BA-84B0-410760713EECQ24644646-F960BC85-9F98-48A7-AC1A-9E1C22AC0452Q24647580-1852278A-9498-4AE2-9B4B-11357401D035Q24669824-A3B27B97-E868-4DAD-9BDA-ADB4CB0F9D98Q24675879-1160884A-C537-45B5-9852-59984C372BB2Q26770267-B910725B-44FF-4A99-A5D9-63A509777C1FQ26824488-FA14D6FF-824C-4909-BD13-BC372EBE98BEQ27002892-451833E3-921A-42E2-8ADA-174B58E38A96Q27023247-C671F55D-BB8F-4C98-B388-1CA3B235FB0CQ27027940-13380212-E479-4ECF-B89F-9A5C5FBDFA00Q27320042-CFE67C37-9B31-47D8-99A3-8360AA8B4927Q27336292-10C40C75-4442-4F46-8A7E-526515FDB710Q28307141-C3236C5E-DA36-4CAE-91C4-A42059B47B77Q28487997-1370010B-79AC-4109-8E15-1D0626A8B01CQ28972313-77C5AA0A-DBBE-410D-A335-C937779F078AQ30279302-F5B5D496-4449-474B-86DB-78984DC5FA97Q30370447-2FBF2BBB-E99B-461B-87C1-4D9904A88791Q30428037-F705894C-00A6-44CC-86F2-F640DD7CEF07Q30466244-2F5FDE58-D73A-401A-957A-20F7474E3EEEQ30484711-16F18A54-4B20-4068-8BB5-E4312D6EE86FQ30491922-391C6937-2554-406D-9BFC-AD51CBEB1B6DQ30492869-7D445D2F-7C65-4A22-BAFE-00AB17F5AF6AQ30493809-75B3BD6A-7E6B-499B-8437-0F389FEDB836Q33454205-BF01F7AE-CBC9-44C3-B774-8804E76A15BEQ33586541-E8A70E37-1E9B-4D34-8B2C-38C140E116A7Q33751955-B043E537-A67B-47AE-9FC4-AF1A7AA3A9D1Q33787904-A586AF84-1045-4FB2-9B67-A2CED941BD68Q33809613-064534F2-5969-4F26-B1D5-A2B5804FD469Q33822189-2B420F1C-711F-4620-9C33-572A2F42A75DQ33935123-39A50CD4-6487-41D5-8E70-F312CB8007C0Q34161831-5B3F31E1-C523-44D5-975E-0A85E6A4A1FDQ34189343-C7E5A529-94A1-4B4E-81C3-45F37E72C3F7Q34233478-E917559C-5A89-486A-A997-2F12766BCB8AQ34277978-B71BD746-2C93-44F2-85FB-5BEA19B6A7A9Q34299455-7ED77BB7-44FB-4676-9695-632368D9F42CQ34333979-0550E7B8-B93F-49E7-84D5-70D13476F136Q34339109-01C260A5-FE40-400F-B0D0-875511311194
P2860
Potent block of Cx36 and Cx50 gap junction channels by mefloquine.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 05 August 2004
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Potent block of Cx36 and Cx50 gap junction channels by mefloquine.
@en
Potent block of Cx36 and Cx50 gap junction channels by mefloquine.
@nl
type
label
Potent block of Cx36 and Cx50 gap junction channels by mefloquine.
@en
Potent block of Cx36 and Cx50 gap junction channels by mefloquine.
@nl
prefLabel
Potent block of Cx36 and Cx50 gap junction channels by mefloquine.
@en
Potent block of Cx36 and Cx50 gap junction channels by mefloquine.
@nl
P2093
P2860
P356
P1476
Potent block of Cx36 and Cx50 gap junction channels by mefloquine.
@en
P2093
David C Spray
Matthew Hopperstad
Miduturu Srinivas
Scott J Cruikshank
P2860
P304
12364-12369
P356
10.1073/PNAS.0402044101
P407
P577
2004-08-05T00:00:00Z