draw and denote the configuration/shape of the voltage-gated Na+ and K+ channels at: resting potential just...
choices for A: Na+/K+ pumps, voltage gated K+ channels, voltage gated Ca+ channels, voltage gated Na+ channels choices for B: bidirectionally, unidirectionally choices for C: Na+/K+ pumps, voltage gated K+ channels, voltage gated Ca+ channels, voltage gated Na+ channels choices for D: Na+/K+ pumps, voltage gated K+ channels, voltage gated Ca+ channels, voltage gated Na+ channels Consider this graph illustrating the generation of an action potential across the plasma membrane of a stimulated neuron. +40 ACTION POTENTIAL plasma membrane potential...
3. Many neurons contain "delayed K channels". Like voltage-gated Nat channels, these voltage-gated K+ channels open in response to a rise in membrane potential and then undergo inactivation. However, opening of the voltage-gated K channels lags behind opening of the voltage-gated Na channels. a) Why does neuronal function require the voltage-gated K channels to open more slowly than the voltage-gated Na channels? b) Compared to a neuron that lacks voltage-gated K channels, what differences would you expect in the shape...
After a fraction of a second, K+ voltage gated channels at the site of the original stimulus open. K+ is more concentrated (outside/inside) the cell; therefore, K+ diffused (in/out). This causes the inside of the membrane to become more negative and return to its resting potential of -70 mV. The process is known as (de/re) polarization. In fact, outflow of K+ may be so great that (de/re/hyper) polarization occurs in which membrane potential becomes closer to (-50, -90 ) mV....
Question 4 2 pts During and action potential, sodium (Na+) rushes into the cell causing of the cell. Then sodium channels close and potassium (K+) rushes out of the cell, causing of the cell. However, the potassium overshoots and causes Question 5 2 pts During the refractory period, the pumps Na+ ions out of the cell and K+ions into the cell, re-establishing the resting membrane potential and concentration gradient. Serotonin Acetylcholine Glutamate Endorphins Barbiturates GABA Dopamine Cocaine Sodium Potassium Calcium...
CNCORA 6 of 10 > Action potentials in neurons involve opening and closing of voltage-gated Nat and K ion channels. Place the events of an action potential in order, starting and ending with a cell at its resting membrane potential. Resting state Return to resting state Answer Bank A graded potential brings the membrane to threshold potential. Fast Na+ and slow K* channels are activated. Nat rushes into the cell, causing membrane depolarization. K channels close slowly, resulting in hyperpolarization....
Q3 During the action potential, the cell depolarizes and goes back to the resting potential after a little hyperpolarization caused by O A The enter of Na+ through the Na+ channels OBThe enter of Na+ through the voltage-gated Na+ channels O cThe exit of K+ through the voltage-gated K+ channels O D The enter of Ca+ through the voltage-gated Ca+ channels
Which statements describe the action potential in cardiomyocytes (heart muscle cells)? Depolarization stimulates voltage-gated, slow calcium channels to open. The absolute refractory period can last for about 200 ms. Rapid sodium influx causes the membrane to rapidly depolarize. Repolarization occurs immediately after the initial depolarization.
What's the role of Na+/K+-ATPase versus voltage gated Na+ & K+ channels?
What's the role of Na+/K+-ATPase versus voltage gated Na+ & K+ channels?
Compare the roles that Na+-gated and K+-gated ion channels play in an action potential.