A Transient Impedance Approach to Nonfaradaic Electrochemical Kinetics at Living Cell Membranes

Robert Schmukler; Arthur A. Pilla

doi:10.1149/1.2123893

A Transient Impedance Approach to Nonfaradaic Electrochemical Kinetics at Living Cell Membranes

Robert Schmukler
, Arthur A. Pilla

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

This study describes a new high resolution impedance technique by which electrochemical kinetic parameters of physiological relevance for living cell surfaces can be obtained. Isolated cells are forced, via hydrostatic pressure, into the pores of an insulation filter membrane, minimizing extracellular current pathways. Cell surface relaxations are thereby observable in the transient response which is interpreted via electrochemical models involving dielectric charging and specific adsorption. Application to the human red blood cell has isolated a transient current pathway which appears to be related to the kinetics of membrane bound enzyme activity.

Original language	English
Pages (from-to)	526-528
Number of pages	3
Journal	Journal of the Electrochemical Society
Volume	129
Issue number	3
DOIs	https://doi.org/10.1149/1.2123893
State	Published - Mar 1982
Externally published	Yes

Keywords

cell membranes
enzyme activity
transient response

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10.1149/1.2123893

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title = "A Transient Impedance Approach to Nonfaradaic Electrochemical Kinetics at Living Cell Membranes",

abstract = "This study describes a new high resolution impedance technique by which electrochemical kinetic parameters of physiological relevance for living cell surfaces can be obtained. Isolated cells are forced, via hydrostatic pressure, into the pores of an insulation filter membrane, minimizing extracellular current pathways. Cell surface relaxations are thereby observable in the transient response which is interpreted via electrochemical models involving dielectric charging and specific adsorption. Application to the human red blood cell has isolated a transient current pathway which appears to be related to the kinetics of membrane bound enzyme activity.",

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N2 - This study describes a new high resolution impedance technique by which electrochemical kinetic parameters of physiological relevance for living cell surfaces can be obtained. Isolated cells are forced, via hydrostatic pressure, into the pores of an insulation filter membrane, minimizing extracellular current pathways. Cell surface relaxations are thereby observable in the transient response which is interpreted via electrochemical models involving dielectric charging and specific adsorption. Application to the human red blood cell has isolated a transient current pathway which appears to be related to the kinetics of membrane bound enzyme activity.

AB - This study describes a new high resolution impedance technique by which electrochemical kinetic parameters of physiological relevance for living cell surfaces can be obtained. Isolated cells are forced, via hydrostatic pressure, into the pores of an insulation filter membrane, minimizing extracellular current pathways. Cell surface relaxations are thereby observable in the transient response which is interpreted via electrochemical models involving dielectric charging and specific adsorption. Application to the human red blood cell has isolated a transient current pathway which appears to be related to the kinetics of membrane bound enzyme activity.

KW - cell membranes

KW - enzyme activity

KW - transient response

UR - https://www.scopus.com/pages/publications/0020099325

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DO - 10.1149/1.2123893

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JO - Journal of the Electrochemical Society

JF - Journal of the Electrochemical Society

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ER -

A Transient Impedance Approach to Nonfaradaic Electrochemical Kinetics at Living Cell Membranes

Abstract

Keywords

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