Question 1

The length constant of an unmyelinated axon increases as the diameter of the axon increases.This is primarily a result of:&#10;A)Increasing membrane capacitance.&#10;B)Decreasing membrane capacitance.&#10;C)Increasing membrane resistance.&#10;D)Decreasing membrane resistance.&#10;E)Decreasing axoplasmic resistance.

Accepted Answer

The length constant of an axon, which determines how far along an axon an electrical impulse can travel, increases with the diameter of the axon primarily due to decreasing axoplasmic resistance. A larger diameter reduces the resistance to current flow within the axon, allowing the electrical signal to travel further.

Question 2

Which of the following events is common to all types of sensory receptors?&#10;A)The generation of a receptor potential.&#10;B)The generation of an action potential.&#10;C)The binding of a stimulus to a receptor.&#10;D)The binding of a stimulus to a membrane channel.&#10;E)Membrane depolarization.

Accepted Answer

All sensory receptors generate a receptor potential in response to a stimulus. This potential may lead to the generation of an action potential which will transmit the information to the central nervous system. The binding of a stimulus to a receptor or membrane channel may be specific to certain types of receptors, and membrane depolarization may occur but is not always necessary in sensory reception.

Question 3

The axon membrane responds to an intracellular injection of a subthreshold positive current with: A)Transient depolarization only in the region where the current is injected. B)Maintained depolarization until negative current is injected. C)Maximal depolarization locally and attenuated depolarization along the axon. D)Immediately opening K⁺ channels to maintain resting potential. E)Firing an action potential.

Accepted Answer

C

Question 4

Which of the following is not a true statement about the conduction of action potentials (APs)in axons? A)The inward Na⁺ current of an AP generates an AP in the neighboring node of a myelinated axon. B)All APs in a given axon typically are identical in magnitude and duration. C)An action potential experimentally generated by a depolarization in the middle of an axon is conducted in only one direction from the site of initiation. D)The velocity of AP conduction is positively correlated with axon diameter. E)The frequency of APs is limited by the length of the refractory period.

Accepted Answer

Action potentials (APs) are conducted in both directions from the site of initiation, not just in one direction. This bidirectional conduction occurs unless there are mechanisms in place to prevent backward propagation, such as the refractory period following an AP that temporarily makes the neuron unable to fire another AP in the same region.

Question 5

At the threshold for generating an action potential: A)The membrane is at the K⁺ equilibrium potential. B)The conductances for Na⁺ and K⁺ are equal. C)There is a rapid opening of voltage-gated Na⁺channels. D)K⁺conductance is maximal. E)The transmembrane voltage is zero.

Accepted Answer

At the threshold for generating an action potential, there is a rapid opening of voltage-gated Na+ channels. This allows for a temporary influx of Na+ ions, which depolarizes the membrane and triggers the action potential. Choices A, B, D, and E are not accurate descriptions of the threshold for generating an action potential.

Question 6

The afterhyperpolarization that follows the action potential: A)Results primarily from to the inactivation of voltage-gated Na⁺ channels. B)Makes it easier to trigger another action potential. C)Is the main cause of the relative refractory period. D)Makes it impossible to fire another action potential. E)Is the consequence of continuing K⁺ influx.

Accepted Answer

The afterhyperpolarization is a period of hyperpolarization that follows the action potential and makes it more difficult to trigger another action potential. This is known as the relative refractory period. The afterhyperpolarization is caused by the efflux of K+ ions from the cell, which causes the membrane potential to become more negative than the resting potential. It is not caused by the inactivation of voltage-gated Na+ channels, the influx of K+ ions, or the impossibility of firing another action potential.

Question 7

Which of the following stimulus parameters is not encoded in the pattern of action potentials in a sensory axon?&#10;A)Threshold&#10;B)Frequency&#10;C)Modality&#10;D)Duration&#10;E)Intensity

Accepted Answer

Modality is the type of sensory information being detected, such as light or sound, and is encoded by the specific sensory receptor that is activated, not by the pattern of action potentials in the sensory axon. Threshold, frequency, duration, and intensity of stimuli are all parameters that can be encoded in the pattern of action potentials.

Question 8

Myelination increases AP conduction velocity by: A)Increasing the axonal diameter. B)Increasing membrane capacitance. C)Limiting voltage-gated K⁺ channels to the nodes. D)Decreasing the membrane resistance. E)Increasing the length constant and decreasing the membrane capacitance between the nodes.

Accepted Answer

Myelination increases the length constant and decreases membrane capacitance between the nodes, allowing faster action potential propagation by saltatory conduction.

Question 9

Which of the following statements about a compound action potential recording is not true?&#10;A)Each peak represents a group of axons of similar conduction velocity.&#10;B)Each peak represents a group of axons of similar diameter.&#10;C)The magnitude of each peak reflects the number of axons in that category.&#10;D)The magnitude of a peak is negatively correlated with axonal conduction velocity.&#10;E)The profiles of peaks are characteristic of and different for different peripheral nerves.

Accepted Answer

The magnitude of a peak is positively correlated with axonal conduction velocity, not negatively correlated.

Question 10

Which of the following is responsible for the repolarization of the membrane after the peak of the action potential? A)The membrane potential reaches the Na⁺ equilibrium potential. B)The voltage-gated Na⁺ channels begin to inactivate. C)The slowly opening voltage-gated K⁺ channels allow K⁺ to enter. D)The influx of Na⁺and the outflow of K⁺are equal. E)There is no longer a gradient to drive K⁺ out of the cell.

Accepted Answer

The inactivation of voltage-gated Na⁺ channels and the opening of voltage-gated K⁺ channels allow K⁺ to exit the cell, leading to repolarization.

Deck 5: Generation and Conduction of Action Potentials