Single calcium channel currents of arterial smooth muscle at physiological calcium concentrations

M. Gollasch; J. Hescheler; J. M. Quayle; J. B. Patlak; M. T. Nelson

Single calcium channel currents of arterial smooth muscle at physiological calcium concentrations

M. Gollasch, J. Hescheler, J. M. Quayle, J. B. Patlak, M. T. Nelson

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

Abstract

Entry of Ca through voltage-dependent Ca channels is an important regulator of the function of smooth muscle, cardiac muscle, and neurons. Although Ca channels have been extensively studied since the first descriptions of Ca action potentials (P. Fatt and B. Katz. J. Physiol. Lond. 120: 171-204, 1953), the permeation rate of Ca through single Ca channels has not been measured directly under physiological conditions. Instead, single Ca channels have typically been examined using high concentrations (80-110 mM) of another divalent charge carrier, Ba, so as to maximize the amplitude of the single-channel currents. Calculations of unitary currents at 2 mM Ca indicated that the single-channel currents would be immeasurably small (i.e.,

Original language	English
Pages (from-to)	C948-C952
Journal	American Journal of Physiology: Cell Physiology
Volume	263
Issue number	5
Publication status	Published - 1992

Keywords

arteries
barium
dihydropyridines

Cite this

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title = "Single calcium channel currents of arterial smooth muscle at physiological calcium concentrations",

abstract = "Entry of Ca through voltage-dependent Ca channels is an important regulator of the function of smooth muscle, cardiac muscle, and neurons. Although Ca channels have been extensively studied since the first descriptions of Ca action potentials (P. Fatt and B. Katz. J. Physiol. Lond. 120: 171-204, 1953), the permeation rate of Ca through single Ca channels has not been measured directly under physiological conditions. Instead, single Ca channels have typically been examined using high concentrations (80-110 mM) of another divalent charge carrier, Ba, so as to maximize the amplitude of the single-channel currents. Calculations of unitary currents at 2 mM Ca indicated that the single-channel currents would be immeasurably small (i.e.,",

keywords = "arteries, barium, dihydropyridines",

author = "M. Gollasch and J. Hescheler and Quayle, {J. M.} and Patlak, {J. B.} and Nelson, {M. T.}",

year = "1992",

language = "English",

volume = "263",

pages = "C948--C952",

journal = "American Journal of Physiology: Cell Physiology",

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publisher = "American Physiological Society",

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TY - JOUR

T1 - Single calcium channel currents of arterial smooth muscle at physiological calcium concentrations

AU - Gollasch, M.

AU - Hescheler, J.

AU - Quayle, J. M.

AU - Patlak, J. B.

AU - Nelson, M. T.

PY - 1992

Y1 - 1992

N2 - Entry of Ca through voltage-dependent Ca channels is an important regulator of the function of smooth muscle, cardiac muscle, and neurons. Although Ca channels have been extensively studied since the first descriptions of Ca action potentials (P. Fatt and B. Katz. J. Physiol. Lond. 120: 171-204, 1953), the permeation rate of Ca through single Ca channels has not been measured directly under physiological conditions. Instead, single Ca channels have typically been examined using high concentrations (80-110 mM) of another divalent charge carrier, Ba, so as to maximize the amplitude of the single-channel currents. Calculations of unitary currents at 2 mM Ca indicated that the single-channel currents would be immeasurably small (i.e.,

AB - Entry of Ca through voltage-dependent Ca channels is an important regulator of the function of smooth muscle, cardiac muscle, and neurons. Although Ca channels have been extensively studied since the first descriptions of Ca action potentials (P. Fatt and B. Katz. J. Physiol. Lond. 120: 171-204, 1953), the permeation rate of Ca through single Ca channels has not been measured directly under physiological conditions. Instead, single Ca channels have typically been examined using high concentrations (80-110 mM) of another divalent charge carrier, Ba, so as to maximize the amplitude of the single-channel currents. Calculations of unitary currents at 2 mM Ca indicated that the single-channel currents would be immeasurably small (i.e.,

KW - arteries

KW - barium

KW - dihydropyridines

M3 - Article

SN - 0363-6143

VL - 263

SP - C948-C952

JO - American Journal of Physiology: Cell Physiology

JF - American Journal of Physiology: Cell Physiology

IS - 5

ER -

Single calcium channel currents of arterial smooth muscle at physiological calcium concentrations

Abstract

Keywords

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