What is the relationship between the sodium-potassium pump and a neuron's resting membrane potential? The sodium-potassium pump allows three negatively charged sodium ions out of the cell for every two negatively charged potassium ions allowed into the cell, thereby keeping the cell positively charged and at a resting membrane potential The sodium-potassium pump allows three positively charged potassium ions out of the cell for every two positively charged sodium ions allowed into the cell, thereby keeping the cell negatively charged and at a resting membrane potential The sodium-potassium pump allows three positively charged sodium ions out of the cell for every two positively charged potassium ions allowed into the cell, thereby keeping the cell negatively charged and at a resting membrane potential The sodium-potassium pump allows three negatively charged potassium ions out of the cell for every two negatively charged sodium ions allowed into the cell, thereby keeping the cell positively charged and at a resting membrane potential
What is the relationship between the sodium-potassium pump and a neuron's resting membrane potential? The sodium-potassium pump allows three negatively charged sodium ions out of the cell for every two negatively charged potassium ions allowed into the cell, thereby keeping the cell positively charged and at a resting membrane potential The sodium-potassium pump allows three positively charged potassium ions out of the cell for every two positively charged sodium ions allowed into the cell, thereby keeping the cell negatively charged and at a resting membrane potential The sodium-potassium pump allows three positively charged sodium ions out of the cell for every two positively charged potassium ions allowed into the cell, thereby keeping the cell negatively charged and at a resting membrane potential The sodium-potassium pump allows three negatively charged potassium ions out of the cell for every two negatively charged sodium ions allowed into the cell, thereby keeping the cell positively charged and at a resting membrane potential
Human Anatomy & Physiology (11th Edition)
11th Edition
ISBN:9780134580999
Author:Elaine N. Marieb, Katja N. Hoehn
Publisher:Elaine N. Marieb, Katja N. Hoehn
Chapter1: The Human Body: An Orientation
Section: Chapter Questions
Problem 1RQ: The correct sequence of levels forming the structural hierarchy is A. (a) organ, organ system,...
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Transcribed Image Text:What is the relationship between the sodium-potassium pump and a neuron's resting membrane
potential?
The sodium-potassium pump allows three negatively charged sodium ions out of the cell for every
two negatively charged potassium ions allowed into the cell, there by keeping the cell positively
charged and at a resting membrane potential
The sodium-potassium pump allows three positively charged potassium ions out of the cell for
every two positively charged sodium ions allowed into the cell, thereby keeping the cell negatively
charged and at a resting membrane potential
100
The sodium-potassium pump allows three positively charged sodium ions out of the cell for every
two positively charged potassium ions allowed into the cell, thereby keeping the cell negatively
charged and at a resting membrane potential
The sodium-potassium pump allows three negatively charged potassium ions out of the cell for
every two negatively charged sodium ions allowed into the cell, thereby keeping the cell positively
charged and at a resting membrane potential
Expert Solution
Step 1: Sodium Potassium Pump
The sodium-potassium pump (Na,K-ATPase) was discovered in 1957. It is required for nerve transmission, kidney function, and heart muscle contraction. The sodium-potassium pump's duty is to maintain the proper concentrations of potassium ions (K+) and sodium ions (Na+) within and outside the cell.
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