Effect of cell electroporation on the conductivity of a cell suspension.
about
Towards treatment planning and treatment of deep-seated solid tumors by electrochemotherapyThe effect of electroporation pulses on functioning of the heartAn e-learning application on electrochemotherapy.Adipose Stem Cells Display Higher Regenerative Capacities and More Adaptable Electro-Kinetic Properties Compared to Bone Marrow-Derived Mesenchymal Stromal Cells.Microwave frequency sensor for detection of biological cells in microfluidic channelsCell-cell proximity effects in multi-cell electroporation.Ex vivo and in silico feasibility study of monitoring electric field distribution in tissue during electroporation based treatments.Effect of blood vessel segmentation on the outcome of electroporation-based treatments of liver tumorsOn the thermal effect induced in tissue samples exposed to extremely low-frequency electromagnetic fieldElectrical Impedance Spectroscopy Study of Biological Tissues.The Influence of a Metal Stent on the Distribution of Thermal Energy during Irreversible Electroporation.Effects of Cisplatin Electrochemotherapy on Human Neuroblastoma Cells.Monitoring the permeabilization of a single cell in a microfluidic device, through the estimation of its dielectric properties based on combined dielectrophoresis and electrorotation in situ experiments.Fluorometric assay to compensate for non-viable cells during electroporation.A new spiral microelectrode assembly for electroporation and impedance measurements of adherent cell monolayers.Magnetic fields with frequency of 217 Hz can reduce cell apoptosis caused by electrochemotherapy.Modeling of electric field distribution in tissues during electroporationAnalytical and numerical quantification and comparison of the local electric field in the tissue for different electrode configurationsSingle-step electrical field strength screening to determine electroporation induced transmembrane transport parameters.Influence of Biphasic Stimulation on Olfactory Ensheathing Cells for Neuroprosthetic Devices.Microfluidic electroporation of tumor and blood cells: observation of nucleus expansion and implications on selective analysis and purging of circulating tumor cells.Kinetics of transmembrane transport of small molecules into electropermeabilized cells.Electroporator with automatic change of electric field direction improves gene electrotransfer in-vitro.Effect of different parameters used for in vitro gene electrotransfer on gene expression efficiency, cell viability and visualization of plasmid DNA at the membrane level.Permeabilization of plant tissues by monopolar pulsed electric fields: effect of frequency.The effects of pulsed magnetic field exposure on the permeability of leukemia cancer cells.Calcein Release from Cells In Vitro via Reversible and Irreversible Electroporation.Dielectrophoresis study of temporal change in internal conductivity of single CHO cells after electroporation by pulsed electric fields.Microscopic histological characteristics of soft tissue sarcomas: analysis of tissue features and electrical resistance.Cell Membrane Transport Mechanisms: Ion Channels and Electrical Properties of Cell Membranes.Atomistic Simulations of Electroporation of Model Cell Membranes.Dependence of Electroporation Detection Threshold on Cell Radius: An Explanation to Observations Non Compatible with Schwan's Equation Model.On-chip electroporation, membrane repair dynamics and transient in-cell recordings by arrays of gold mushroom-shaped microelectrodes.Effect of Electrode Distance in Grid Electrode: Numerical Models and In Vitro Tests.Evidence for electro-induced membrane defects assessed by lateral mobility measurement of a GPi anchored protein.
P2860
Q21245874-069DA358-FB7A-4BBB-975B-235F9925B6E9Q24652659-80531349-6820-4584-96EE-2E618835F44FQ30491302-15C6049D-ECA1-45AD-B27A-A9AF119A4B63Q30829638-06EBEAAD-1B7F-49E3-90DB-0E7230E9A58DQ33714043-412809F4-2ED8-4077-875A-A8CEAE0689D9Q34305031-483C01FE-CAEC-4733-8210-045E302AFD92Q34429930-96C88623-9AFB-404D-9F0F-B42F12785A95Q35622283-F06B9C35-0BA3-425C-8559-9D4282DB2AEAQ36379842-13366207-6318-4367-8AEE-536F8909AECDQ37004322-F184769C-1A70-4FE6-BD75-463A320BC316Q38263247-CF67920E-0D9A-4096-902D-8957912748E5Q38782790-6368D548-F819-4EF1-A18A-3078E0C63237Q38914120-6530E588-A3A2-4FD1-9097-777CF45B9D3AQ38929146-B1BA99E1-C928-4EC0-9148-8511A000B780Q39010137-8B61D9CF-EFAA-403D-A38D-B0754415E04AQ39210154-13E27B5F-189A-493D-B3A8-5B7DE791DAACQ39518282-EB23B6DF-94F4-471B-846F-5D476083E1F8Q40829489-AE7D47A6-92A5-4A6C-B573-62DFEBB8E177Q41006691-98CBA1C2-C905-4617-97D1-247F47ADE75BQ41289789-88DA0072-F469-4E52-A915-505C842C24ABQ42041340-27CF7E82-C971-4803-A96E-A3A40ECD0F36Q42423765-4C0700A7-C9E9-4D7B-97F1-5264FCA05414Q42425117-1C2AB849-2B79-4856-A02E-5E033B680B22Q44939380-CEE162B4-8DCD-4D59-9D5B-152D5C016657Q46441407-027C0456-5B86-49CD-987B-3E56FEEBC119Q46824866-510D2077-9451-4190-9B41-D433A9ED285BQ48048861-B725436A-59BC-4428-B032-C5918C71B629Q48133183-D3C4AFE2-FD2F-4C42-A218-074C2895C70EQ48325548-F1E69D58-85CB-4983-AAB3-4D4233A84DF4Q49589400-AD74670E-0783-4A3F-8F9C-5922C5D1A3C9Q49589507-E47CE6B2-6D5E-4E28-AFAC-FF8BFC606ABEQ50648094-9CFE95F5-1FFB-429C-92BC-DC8CDCEFFD29Q51539473-FD80B1DE-6AE9-4C88-8A27-8CB51441A2A4Q51556604-30012413-7553-45D3-911A-68FD0925E3CFQ51748989-5625CF83-BCAD-4FD4-B6F4-0A680867767B
P2860
Effect of cell electroporation on the conductivity of a cell suspension.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
2005年论文
@zh
2005年论文
@zh-cn
name
Effect of cell electroporation on the conductivity of a cell suspension.
@en
type
label
Effect of cell electroporation on the conductivity of a cell suspension.
@en
prefLabel
Effect of cell electroporation on the conductivity of a cell suspension.
@en
P2093
P2860
P1433
P1476
Effect of cell electroporation on the conductivity of a cell suspension.
@en
P2093
Francis X Hart
Gorazd Pucihar
Masa Kanduser
Matej Rebersek
Mojca Pavlin
Ratko Magjarevic
P2860
P304
P356
10.1529/BIOPHYSJ.104.048975
P407
P577
2005-03-25T00:00:00Z