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From understanding cellular function to novel drug discovery: the role of planar patch-clamp array chip technologyA method for measuring electrical signals in a primary ciliumThe mechanosensitive ion channel Piezo1 is inhibited by the peptide GsMTx4End-plate acetylcholine receptor: structure, mechanism, pharmacology, and diseaseStretch-activated ion channels: what are they?Ion Channels in Native Chloroplast Membranes: Challenges and Potential for Direct Patch-Clamp StudiesMechanosensitive gating of Kv channelsSensory mechanotransduction at membrane-matrix interfacesCaveolae regulation of mechanosensitive channel function in myotubesThe role of MscL amphipathic N terminus indicates a blueprint for bilayer-mediated gating of mechanosensitive channelsAdaptive behavior of bacterial mechanosensitive channels is coupled to membrane mechanicsCardiac Mechano-Gated Ion Channels and Arrhythmias.Cell volume control in three dimensions: Water movement without solute movementOne-channel cell-attached patch-clamp recordingMolecular force transduction by ion channels: diversity and unifying principles.Differential effects of lipids and lyso-lipids on the mechanosensitivity of the mechanosensitive channels MscL and MscS.Cleaning patch-clamp pipettes for immediate reuse.Functional reconstitution of a voltage-gated potassium channel in giant unilamellar vesicles.Unsupervised Idealization of Ion Channel Recordings by Minimum Description Length: Application to Human PIEZO1-Channels.Stationary gating of GluN1/GluN2B receptors in intact membrane patchesA mechanosensitive ion channel regulating cell volume.Wild-type and brachyolmia-causing mutant TRPV4 channels respond directly to stretch force.Effects of GsMTx4 on bacterial mechanosensitive channels in inside-out patches from giant spheroplasts.Biophysical implications of lipid bilayer rheometry for mechanosensitive channels.Xerocytosis is caused by mutations that alter the kinetics of the mechanosensitive channel PIEZO1Gigaseal mechanics: creep of the gigaseal under the action of pressure, adhesion, and voltage.Analyses of gating thermodynamics and effects of deletions in the mechanosensitive channel TREK-1: comparisons with structural modelsProtonation of the human PIEZO1 ion channel stabilizes inactivationReconstitution of a transmembrane protein, the voltage-gated ion channel, KvAP, into giant unilamellar vesicles for microscopy and patch clamp studiesGd3+ and calcium sensitive, sodium leak currents are features of weak membrane-glass seals in patch clamp recordingsLipid bilayer mechanics in a pipette with glass-bilayer adhesionIntracellular ATP supports TRPV6 activity via lipid kinases and the generation of PtdIns(4,5) P₂.Expression and characterization of the bacterial mechanosensitive channel MscS in Xenopus laevis oocytesThe core domain as the force sensor of the yeast mechanosensitive TRP channel.Ionic Selectivity and Permeation Properties of Human PIEZO1 Channels.Modeling ion channels in the gigasealA Threshold Shear Force for Calcium Influx in an Astrocyte Model of Traumatic Brain Injury.A Conserved Residue Cluster That Governs Kinetics of ATP-dependent Gating of Kir6.2 Potassium ChannelsInfluence of Global and Local Membrane Curvature on Mechanosensitive Ion Channels: A Finite Element ApproachActivation of TRPV1 channels inhibits mechanosensitive Piezo channel activity by depleting membrane phosphoinositides.
P2860
Q21129290-5F33446C-0D7B-4152-B939-00D10C168C17Q22001112-FCD44897-CAE2-4114-8E88-F3AFC07FF98FQ24601391-E6FFE937-A168-4CF7-A0AE-E6B25D71DE65Q24618824-56226FEC-FE89-40DA-81FB-410AC6563A50Q24630314-EB718D67-4F3D-4195-90C1-FD8D9EC12FA5Q26770720-EAEC4680-1F41-4835-A637-26A3349487C2Q26866573-6785AAA6-9E6D-49F7-944E-151050BC0000Q27011942-FFA23E49-0F2F-4E21-B19A-9076581C11CEQ27308705-5AF04455-28B9-4397-A920-2F2C76EB332BQ27342278-5BDBFFFB-600E-46B4-9A62-69FF2C3214C8Q28283896-155D565C-180D-4B7E-ACE3-77B517FE2207Q28601309-A59B3FAC-9485-48B1-B56C-1C34C9F81F54Q28648373-09E873DA-E4E3-45AE-BEB7-676116904FA5Q28654944-EE15B231-8719-4B3B-835C-FE9D899CB7C0Q30419201-6C97E638-BDDC-41E8-9940-BF8355B4B134Q30514329-345A5FB9-B68E-490D-95D2-C58B46917A8CQ30820128-20E291B8-1FD0-4849-8BE1-04D198D52D61Q31037066-D32D4D2F-6240-4D35-A688-3CD91716A515Q33606996-125E5DFD-ACF7-445C-BA00-0D655040F4D7Q33767671-B261EE68-312B-4E42-8284-59912D0229B2Q33929776-504612C6-1E2C-4324-A007-3F27EA69C6DAQ34094517-4FAE7223-1FE9-483A-BF96-E904ABA83156Q34250731-E7872C1E-B250-426D-9053-AB607B492358Q34280899-D241745C-D7C2-46B7-8262-15442485E5E6Q34332832-C757AEBD-1609-4468-8959-1C6E3708A8DDQ34481824-418F1289-6578-4B7D-BD8D-8E7DF882E828Q34639490-AF801668-7429-44B1-814D-92578B836C36Q35104032-636ED0B6-5256-4A90-BCFC-D473D07CC76CQ35161992-F54D2901-A9DC-4EC2-96CE-F4341C1B79EFQ35191021-8C6204B3-F5F3-4A7E-991D-A64CEE1A37F4Q35342115-EEAFD391-605D-497A-8AC2-C401D193C189Q35497168-161F65C4-CE16-43E0-AC8F-FC65F13805BDQ35581369-3CC706C3-8EA6-47AA-B108-5F79F163995CQ35581381-3031C45F-BFDB-4DC0-9D25-2335084F8696Q35625483-15385FB4-4E4C-47B4-8228-EEA57DEAF0E3Q35815914-20E408CA-7346-42F1-9CB0-6BB07FD39C66Q35821702-9F3F3ADE-F505-46FE-A8D0-3D200FDC3C71Q35860617-9FE429D7-861B-4315-BD73-AAC82331596CQ35918955-DDF16B1F-8FFB-4BAB-9114-31DF4E577584Q35923122-C136DA47-1F67-4702-935C-C48BC60CC31B
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on August 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Biophysics and structure of the patch and the gigaseal.
@en
Biophysics and structure of the patch and the gigaseal.
@nl
type
label
Biophysics and structure of the patch and the gigaseal.
@en
Biophysics and structure of the patch and the gigaseal.
@nl
prefLabel
Biophysics and structure of the patch and the gigaseal.
@en
Biophysics and structure of the patch and the gigaseal.
@nl
P2093
P2860
P1433
P1476
Biophysics and structure of the patch and the gigaseal.
@en
P2093
Frederick Sachs
Thomas M Suchyna
Vladislav S Markin
P2860
P304
P356
10.1016/J.BPJ.2009.05.018
P407
P577
2009-08-01T00:00:00Z