Lipid nanopores can form a stable, ion channel-like conduction pathway in cell membrane.
about
Characterization of Pressure Transients Generated by Nanosecond Electrical Pulse (nsEP) Exposure.Electroporation-induced electrosensitization.Gadolinium blocks membrane permeabilization induced by nanosecond electric pulses and reduces cell deathPlasma membrane permeabilization by trains of ultrashort electric pulses.Dose-dependent thresholds of 10-ns electric pulse induced plasma membrane disruption and cytotoxicity in multiple cell lines.A theoretical analysis of the feasibility of a singularity-induced micro-electroporation systemDisassembly of actin structures by nanosecond pulsed electric field is a downstream effect of cell swelling.Calcium-mediated pore expansion and cell death following nanoelectroporationAnalysis of plasma membrane integrity by fluorescent detection of Tl(+) uptake.DNA electrophoretic migration patterns change after exposure of Jurkat cells to a single intense nanosecond electric pulseSelective cytotoxicity of intense nanosecond-duration electric pulses in mammalian cells.Cancellation of cellular responses to nanoelectroporation by reversing the stimulus polarity.Synergistic effects of nanosecond pulsed electric fields combined with low concentration of gemcitabine on human oral squamous cell carcinoma in vitro.Transient features in nanosecond pulsed electric fields differentially modulate mitochondria and viability.Manipulation of cell volume and membrane pore comparison following single cell permeabilization with 60- and 600-ns electric pulses.Thresholds for phosphatidylserine externalization in Chinese hamster ovarian cells following exposure to nanosecond pulsed electrical fields (nsPEF).An apoptosis targeted stimulus with nanosecond pulsed electric fields (nsPEFs) in E4 squamous cell carcinoma.Multiple nanosecond electric pulses increase the number but not the size of long-lived nanopores in the cell membrane.Gadolinium modifies the cell membrane to inhibit permeabilization by nanosecond electric pulses.Effects of nanosecond pulse electric fields on cellular elasticity.Inhibition of voltage-gated Na(+) current by nanosecond pulsed electric field (nsPEF) is not mediated by Na(+) influx or Ca(2+) signalingCell permeabilization and inhibition of voltage-gated Ca(2+) and Na(+) channel currents by nanosecond pulsed electric field.Diffuse, non-polar electropermeabilization and reduced propidium uptake distinguish the effect of nanosecond electric pulses.Electroporation of mammalian cells by nanosecond electric field oscillations and its inhibition by the electric field reversal.Picosecond and Terahertz Perturbation of Interfacial Water and Electropermeabilization of Biological Membranes.Oxidative effects of nanosecond pulsed electric field exposure in cells and cell-free mediaInactivation of Ricin Toxin by Nanosecond Pulsed Electric Fields Including Evidences from Cell and Animal Toxicity.Electric field exposure triggers and guides formation of pseudopod-like blebs in U937 monocytes.Impact of external medium conductivity on cell membrane electropermeabilization by microsecond and nanosecond electric pulsesElectrosensitization assists cell ablation by nanosecond pulsed electric field in 3D culturesHepatocellular carcinoma ablation and possible immunity in the age of nanosecond pulsed electric fields.Recruitment of the intracellular Ca2+ by ultrashort electric stimuli: the impact of pulse durationNon-thermal nanoelectroablation of UV-induced murine melanomas stimulates an immune response.Bipolar nanosecond electric pulses are less efficient at electropermeabilization and killing cells than monopolar pulses.Microsecond and nanosecond electric pulses in cancer treatments.Induction of Cell Death Mechanisms and Apoptosis by Nanosecond Pulsed Electric Fields (nsPEFs).Salinity tolerance in plants. Quantitative approach to ion transport starting from halophytes and stepping to genetic and protein engineering for manipulating ion fluxes.Selective susceptibility to nanosecond pulsed electric field (nsPEF) across different human cell types.Nanometer-Scale Permeabilization and Osmotic Swelling Induced by 5-ns Pulsed Electric Fields.Electroporation of DC-3F cells is a dual process.
P2860
Q30401230-DE82E34F-D6F7-428C-BEFB-06C633222EA1Q33828737-94C74159-C361-4AC5-BD19-B7FE29919022Q33838105-16166B3E-BC5A-4DA5-B4C6-A7849AF7056BQ33838386-32C3AE42-72F0-4023-9EF8-7E5E5115ACAFQ33841941-40E661B2-FD1C-467D-AFBF-8C296A04281AQ33873544-E5B9C760-E618-4F12-A1DB-7A6A4CA6EA4BQ33927421-0048801B-95E4-4314-BD72-299FDB649ABAQ34017211-6B19A1F7-FB46-4407-8F41-42DCC67D062AQ34070591-00F6F495-0796-4383-951A-9599F93BA6D5Q34099237-5416973E-6E13-4584-85CB-F142238A9A3BQ34107635-DBB89B34-7AFF-4CDC-A8B3-127223E93D0EQ34381508-64E896E5-B4B4-4E55-B39E-B0DE28672043Q34395614-3AC8DD4D-C5BA-4189-91BF-78C24C83F815Q34531804-073FA0A9-A00F-4024-B5DC-5E67FF4BC8B5Q34574588-AAC42583-CF3C-4DCB-824E-3DCA9507F9F4Q34712270-670B7AA9-8E2A-4F96-A635-019A8CCB564CQ34733999-DE78F474-AF01-46E0-804E-95F695ECD2BEQ35091306-65E1ADBD-F8D9-47E6-B13B-D1B1166FB10BQ35205446-7DEB3330-6419-4045-B0A4-1F526F8C2CAEQ35434311-5FE1FE1E-C2B9-48DA-9C21-339CEA298E96Q35899064-E78879C9-95A8-452B-9A12-E8C8E1095072Q35911454-D884DF1F-098F-4917-9ADF-F32F46364859Q36011792-5DBBB96C-DF72-43B9-BE92-ED5A214C87FAQ36035516-02895961-F6AD-437E-BC28-D7CBDE8A1F4AQ36047861-62932C06-2F6B-4860-AF4C-60B1000780B4Q36282236-AB16BD23-E175-4D41-9910-8B171136F4EDQ36427877-4610B5B8-3130-45EF-9767-AA7A65CB4580Q36432962-B70C06BE-0651-4D36-ACCB-E874F743E495Q36524788-3A1976E9-83E3-4290-905B-0B279545FF9CQ36699965-EB353893-0E9B-46A2-AC24-272CCC0A6566Q37031754-0D4AED68-774D-4770-AB7E-1651AC961692Q37138346-2AACCDFA-45D1-4E5D-B58B-FA9B88FA7015Q37140071-DFD66935-B61E-4C77-9D45-BEA3F847B375Q37606071-7EDC6ACC-F79A-41B2-B109-C4F237AD7DEBQ37910836-3288BA74-CB76-4D5F-B533-5978D46582D2Q38202810-60239759-F8FF-4624-A455-1442C6581D84Q38636854-1513356A-B66B-41FA-961A-412C0A667475Q38725765-1DB09781-DDDE-4BA7-ABBE-D52E8F549784Q38756926-F7DCE799-5785-48B6-9C6B-61CC7216C920Q38888616-7D2AB579-FA64-41E8-A3F4-AA850A55E9AE
P2860
Lipid nanopores can form a stable, ion channel-like conduction pathway in cell membrane.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 18 May 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Lipid nanopores can form a stable, ion channel-like conduction pathway in cell membrane.
@en
Lipid nanopores can form a stable, ion channel-like conduction pathway in cell membrane.
@nl
type
label
Lipid nanopores can form a stable, ion channel-like conduction pathway in cell membrane.
@en
Lipid nanopores can form a stable, ion channel-like conduction pathway in cell membrane.
@nl
prefLabel
Lipid nanopores can form a stable, ion channel-like conduction pathway in cell membrane.
@en
Lipid nanopores can form a stable, ion channel-like conduction pathway in cell membrane.
@nl
P2093
P2860
P1476
Lipid nanopores can form a stable, ion channel-like conduction pathway in cell membrane.
@en
P2093
Andrei G Pakhomov
Angela M Bowman
Bennett L Ibey
Franck M Andre
Karl H Schoenbach
Olga N Pakhomova
P2860
P304
P356
10.1016/J.BBRC.2009.05.035
P407
P577
2009-05-18T00:00:00Z