Glossary of Physiology Terms
There are
20 glossary search results for:
membrane potential
Definition:
The action potential is a rapid and reversible reversal of the electrical potential difference across the plasma membrane of excitable cells such as neurons, muscle cells and some endocrine cells. In a neuronal action potential, the membrane potential rapidly changes from its resting level of approximately -70 mV to around +50 mV and, subsequently, rapidly returns to the resting level again. The neuronal action potential forms an important basis for information processing, propagation, and transmission. In muscle cells, the action potential precedes, and is necessary to bring about, muscle contraction. Some endocrine cells also exhibit action potentials, where the excitation leads to hormone secretion.
The action potential is also referred to as the electrical impulse or nervous impulse.
Related glossary terms/phrases:
Graded potentialSee also:
Neuronal Action Potential
Definition:
The voltage difference across a cell plasma membrane.
The membrane potential is generally inside negative with respect to the outside, where the outside potential is generally set as the reference value. In electrically excitable cells, the value of the membrane potential can be positive (inside with respect to the outside) during electrical activity (i.e., during action potentials).
Related glossary terms/phrases:
Resting membrane potentialSee also:
Resting membrane potential
Definition:
The voltage difference across a cell plasma membrane in the resting or quiescent state. It is also simply referred to as the resting potential (
Vrest). The value of the resting membrane potential varies from cell to cell. Depending on the cell type, it can range from −90 mV to −20 mV.
For example,
Vrest is −90 mV in skeletal and cardiac muscle cells as well as in astrocytes. In a typical neuron,
Vrest is approximately −70 mV. In many non-excitable cells,
Vrest ranges from −60 to −50 mV. In photoreceptors,
Vrest is about −20 mV.
See also:
Resting membrane potential
Abbreviation:
CI
−Definition:
The main anion (negatively charged ion) of the extracellular fluid.
Cloride (Cl
−) plays an important role in several physiological processes such as the action potential of skeletal muscle cells, CO
2 transport in blood (via Cl
−/bicarbonate exchange across the plasma membrane of red blood cells), and many other processes.
The extracellular concentration of Cl
− is about 110 mM. The intracellular concentration of Cl
− is about 10 mM.
Definition:
Electrophysiology is the study of the electrical properties of biological macromolecules, cells, tissues, and organs. Electrical signals such as voltage and/or current are generally measured. Examples include measuring changes in the membrane voltage of excitable cells (e.g., neurons, muscle cells, and some endocrine cells) during an
action potential. The current carrried by ions as they permeate the pore of ion channels can also be measured - both at the single-channel level (single-channel current), as well as the macroscopic current resulting from the activity of a population of channels. As another example, electrical measurements may involve recording voltage changes at the surface of the skin that result from the activity of skeletal muscles (electromyogram, EMG), cardiac myocytes (electrocardiogram, ECG), or neurons in the brain (electroencephalogram, EEG).
Definition:
The Hodgkin cycle represents a positive feedback loop in neurons, where an initial membrane depolarization from the resting value (∼ −70 mV) to the threshold value (∼ −50 mV) leads to rapid depolarization of the membrane potential to approach the equilibrium potential for Na
+ (
VNa ≈ +60 mV). The voltage-gated Na
+ channels of neurons are responsible for the Hodgkin cycle.
See the
figure depicting the Hodgkin cycle.
See also:
Important Features of the Neuronal Action Potential
Definition:
An equation used to calculate the equilibrium potential (
Veq.) of an ion. The equilibrium potential for an ion is also referred to as the Nernst potential for that ion. It is the membrane potential at which no net movement of the ion in question occurs across the membrane.
where
Veq. is the equilibrium potential,
R is the
universal gas constant,
T is the temperature in Kelvin,
z is the valence of the ionic species,
F is the
Faraday's constant, and [
X]
o and [
X]
i are the extracellular and intracellular, respectively, concentrations of the ion in question.
See also:
Resting Membrane Potential - Nernst Equilibrium PotentialDerivation of the Nernst Equation
Abbreviation:
Na
+Definition:
The main cation (positively charged ion) of the extracellular fluid.
Sodium (Na
+) plays an important role in several physiological processes such as the
action potential of neurons and muscle cells,
secondary active, sodium-coupled transport of ions, nutrients, neurotransmitters across the plasma membrane of cells, and many other processes.
The extracellular concentration of Na
+ is about 145 mM. The intracellular concentration of Na
+ is about 15 mM.
Definition:
The membrane voltage that must be reached in an excitable cell (e.g., neuron or muscle cell) during a depolarization in order to generate an action potential. At the threshold voltage, voltage-gated channels become activated. Threshold is approximately −50 to −40 mV in most excitable cells.
Related glossary terms/phrases:
Sub-thresholdSupra-thresholdSee also:
Neuronal Action Potential - Introduction
Posted: Sunday, March 31, 2013
Last updated: Friday, August 28, 2015