Animal Physiology Chapter 12 PDF

Summary

This document provides multiple-choice questions and answers on animal physiology, specifically focused on neurons.

Full Transcript

Test Bank
to accompany
Animal Physiology, Fourth Edition
Hill Wyse Anderson

Chapter 12: Neurons

TEST BANK QUESTIONS

Multiple Choice

1. Initiation of the action potential usually occurs _______ of the neuron.
a. in the cell body
b. on the dendrites
c. at the axon initial segment
d. on the axon
Answer: c
Textbook Reference: The Physiology of Control: Neurons and Endocrine Cells
Compared
Bloom’s Category: 1. Remembering

2. Which statement about an animal’s nervous system is true?
a. Neurotransmitter is released throughout the body via the blood.
b. Signal transmission rate is relatively slow.
c. Neurons form highly discrete lines of communication.
d. Action potential signals degrade over distance.
Answer: c
Textbook Reference: The Physiology of Control: Neurons and Endocrine Cells
Compared
Bloom’s Category: 2. Understanding

3. For a hormone to elicit a specific response from a cell, the cell must possess
a. a synapse.
b. a cell body.
c. dendrites specific to the hormone.
d. receptor proteins specific to the hormone.
Answer: d
Textbook Reference: The Physiology of Control: Neurons and Endocrine Cells
Compared
Bloom’s Category: 2. Understanding

4. Which statement about the startle response of the cockroach is true?
a. Vibrations of hairs generate nerve impulses in sensory neurons.
b. Sound waves or air currents synapse with the filiform hairs.
c. Sensory neurons synapse with and excite the dorsal hollow spinal cord.

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d. At the metathoracic ganglion, the interneurons synaptically inhibit leg motor neurons.
Answer: a
Textbook Reference: Neurons Are Organized into Functional Circuits in Nervous
Systems
Bloom’s Category: 5. Evaluating

5. Which glial cells are found in the peripheral nervous system?
a. Oligodendrocytes
b. Schwann cells
c. Astrocytes
d. Microglial cells
Answer: b
Textbook Reference: The Cellular Organization of Neural Tissue
Bloom’s Category: 1. Remembering

6. Which statement about glial cells is true?
a. They integrate cell membrane potentials to enhance or inhibit action potentials.
b. They decrease the velocity of nerve-impulse propagation.
c. They help supply metabolic substrates to neurons.
d. They act as metabolic intermediaries between epithelial cells and neurons.
Answer: c
Textbook Reference: The Cellular Organization of Neural Tissue
Bloom’s Category: 2. Understanding

7. The separation of positive and negative charges constitutes
a. resistance.
b. an electric current.
c. a voltage.
d. capacitance.
Answer: c
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 1. Remembering

8. Which statement about membrane capacitance is true?
a. It is in series with membrane resistance.
b. In a cell, the membrane separates only similarly charged ions.
c. It is measured in ohms.
d. It is a function of the permeability of the membrane.
Answer: a
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 2. Understanding

9.–10. Refer to the figure below.

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9. What is occurring at the membrane?
a. Depolarization
b. Hyperpolarization
c. Increase in resistance
d. Decrease in capacitance
Answer: a
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 4. Analyzing

10. In the lower panel, the difference between the dashed line and the solid red line is due
to
a. membrane resistance.
b. the fact that one represents a depolarization and the other represents a
hyperpolarization.
c. the capacitive properties of the membrane.
d. the difference in applied voltage.
Answer: c
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 4. Analyzing

11.–13. Refer to the figure below.

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11. In the figure, the _______ decreases with distance.
a. graded potential
b. action potential
c. membrane current
d. membrane capacitance
Answer: a
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 4. Analyzing

12. Which statement offers the best explanation for the difference between the middle
panel and the lower panel?
a. The membrane in the lower panel is producing a lower current.
b. There is a lower resistance in the lower panel at the point where voltage is measured.
c. There is a greater capacitance in the lower panel at the point where voltage is
measured.
d. The membrane voltage measured in the lower panel is farther away from the current
pulse.
Answer: d
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 4. Analyzing

13. The properties shown in the figure can be measured in
a. neurons.
b. neurons and pacemaker cells.
c. muscle cells.
d. neurons, pacemaker cells, and muscle cells

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Answer: d
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 4. Analyzing

14. Which variable does not contribute to the passive electrical properties of a cell?
a. Membrane resistance
b. Membrane capacitance
c. The resting membrane current
d. The time constant
Answer: c
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 4. Analyzing

15.–16. Refer to the figure below.

15. The figure shows that the membrane potential results from
a. the six pairs of ions sitting on the membrane.
b. the thousands of ions sitting on the membrane.
c. the overall difference intra- and extra cellular ion concentrations in the volume of cell
shown.
d. movement of ions across the cell membrane.
Answer: a
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 3. Applying

16. In the figure, _______in the center of the cell.
a. there would be a slight negative charge

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b. there would be a strong negative charge
c. the overall charge neutrality would be maintained independently of the membrane
potential
d. there would be a slight positive charge
Answer: c
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 4. Analyzing

17. Which characteristic is not a factor in the Nernst Equation?
a. Capacitance
b. Temperature
c. The valence of the ion species
d. The ion concentrations on the two sides of the membrane
Answer: a
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 4. Analyzing

18. In a cell, the difference in ion concentration between the intracellular and
extracellular fluids results from
a. active ion transport.
b. passive diffusion of ions.
c. bulk movements of intracellular and extracellular fluids.
d. both active ion transport and passive diffusion of ions.
Answer: d
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 2. Understanding

19. According to the Nernst equation, which change will depolarize Vm, the membrane
potential?
a. A decrease in temperature
b. An increase in the valence of the ion species involved
c. A decrease in the concentration of anions inside the membrane
d. A decrease in the electromotive force of the ion
Answer: c
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 3. Applying

20. Which statement regarding the ions in intracellular and extracellular fluids in a
standard animal cell is true?
a. Na+ leaks into the cell rapidly because its electrochemical gradient is large.
b. K+ leaks out of the cell slowly because the electrochemical gradient is small.
c. Cl– leaks into the cell rapidly because its electrochemical gradient is large.
d. Negatively charged proteins leak out of the cell slowly because their electrochemical
gradient is small.
Answer: b
Textbook Reference: The Ionic Basis of Membrane Potentials

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Bloom’s Category: 2. Understanding

21. According to the Goldman equation, the contribution of each ion to the membrane
potential depends most on
a. its size.
b. its membrane permeability.
c. its activation energy.
d. the resting membrane potential.
Answer: b
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 2. Understanding

22. Which structure is most responsible for the all-or-none property of the action
potential?
a. Myelin
b. Voltage-gated K+ channels
c. Voltage-gated Na+ channels
d. Leakage of K+ channels
Answer: c
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

23.–26. Refer to the figure below.

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23. Which arrow best represents the point where permeability to sodium is the highest?
a. I
b. II
c. III
d. IV
Answer: a
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

24. Which arrow best represents the point where the voltage-gated sodium channels are
inactivated?
a. I
b. III
c. IV
d. III and IV
Answer: d
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

25. _______ channels are responsible for the undershoot at point D of the figure.
a. Voltage-gated sodium
b. Voltage-gated potassium
c. Ligand-gated potassium
d. Voltage-gated calcium
Answer: b
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

26. What occurs when the membrane is clamped at –100 mV?
a. Voltage-gated ion channels behave in a similar manner as in the diagram.
b. Voltage-gated ion channels do not open at all.
c. There is a brief shift in ions and then a flat current at –100 mV.
d. Only ligand-gated channels work at this point.
Answer: b
Textbook Reference: The Action Potential
Bloom’s Category: 3. Applying

27.–29. Refer to the figure below.

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27. How many separate current pulses cause the membrane potential to reach the
threshold?
a. 1
b. 2
c. 3
d. 5
Answer: c
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

28. What would likely occur if stimulus 3 and 6 were performed simultaneously?
a. An action potential would likely occur.
b. An action potential would likely not occur.
c. Multiple action potentials would likely occur.
d. The threshold voltage would likely decrease.
Answer: b
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

29. If stimulating current pulse 9 (not shown) was both stronger and longer than
stimulating current pulse 8, then
a. the train of action potentials would continue for the length of the stimulating current.
b. action potentials would increase in amplitude.
c. action potentials would first increase in frequency and then decrease.
d. the line at stimulus 9 would look exactly same as the line at stimulus 8.
Answer: a
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

30. For an axon at resting membrane potential, the K+ leak channel is _______, the
voltage-gated Na+ channel is _______, and the voltage-gated K+ channel is _______.
a. open; inactivated; closed
b. closed; inactivated; closed

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c. open; inactivated; open
d. open; closed; closed
Answer: d
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

31. During the falling phase of an action potential, the K+ leak channel on the axon is
_______, the voltage-gated Na+ channel is _______, and the voltage-gated K+ channel is
_______.
a. open; inactivated; closed
b. closed; inactivated; closed
c. open; inactivated; open
d. open; closed; closed
Answer: c
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

32.–34. Refer to the figure below.

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32. Which technique was used to collect the data in the bottom panel?
a. Patch-clamp
b. Voltage-clamp
c. Current-clamp
d. Hodgkin clamp
Answer: a
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

33. On the figure, I represents _______ currents through voltage-gated _______ channels.
a. outward; Na+
b. inward; Na+
c. outward; K+

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d. inward; K+
Answer: b
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

34. Why do the channels at II on the figure stay open longer than those at I?
a. Channels at I are responding to a depolarization, whereas channels at II are responding
to a hyperpolarization.
b. The depolarization is a faster event compared to the repolarization.
c. Channels at I are less sensitive to voltage compared to channels at II.
d. Channels at I become inactivated, whereas channels at II close due to membrane
voltage.
Answer: d
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

35.–37. Refer to the figure below:

35. Which technique was used to collect the data shown in the figure?
a. Patch-clamp
b. Hodgkin clamp
c. Current-clamp
d. Voltage-clamp
Answer: d
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

36. The treatment difference between the membranes shown in the graphs is that the
membrane on the left is being _______, while the membrane on the right is being
_______.
a. depolarized; depolarized in Na+-free seawater
b. hyperpolarized; hyperpolarized in an isoionic Na+ solution
c. hyperpolarized; depolarized
d. depolarized; hyperpolarized

© 2016 Sinauer Associates, Inc.
Answer: c
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

37. How would the trace on the right look if the neuron was soaking in TEA?
a. The inward ionic current would disappear.
b. The outward ionic current would disappear.
c. The trace would look exactly like the trace in the left panel.
d. The outward ionic current would be amplified.
Answer: b
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

38. Which statement about a voltage clamp of a neuron at 0 mV is true?
a. Once clamped, the membrane depolarizes then returns to resting potential.
b. Voltage-gated potassium channels open.
c. Apart from the initial current shift from the clamp, no other current is produced.
d. Voltage-gated sodium channels close
Answer: b
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

39. Which statement regarding the structure of the voltage-gated Na+ channels is false?
a. P loops mediate ion selectivity.
b. It has four domains with extensive sequence homology.
c. The channel protein changes its primary structure in response to membrane
depolarization.
d. A cytoplasmic loop is thought to inactivate the channel by blocking the opening.
Answer: c
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

40. A spiking neuron and a nonspiking neuron share which characteristic?
a. High concentration of voltage-gated Na+ channels at the axon hillock
b. A graded potential down the entire length of the axon
c. An action potential down the entire length of the axon
d. Neurotransmitter secretion based on a change in membrane potential
Answer: d
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

41. How do nonspiking neurons function even though their depolarization signal
significantly degrades with distance?
a. Voltage-gated Na+ channels are replaced by ligand-gated Na+ channels.
b. These neurons are very short, so there is no major signal decrement.

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c. There are sufficient numbers of voltage-gated Na+ channels to convey the signal
without major decrement.
d. Voltage-gated K+ channels compensate for the lack of voltage-gated Na+ channels.
Answer: b
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

42.–44. Refer to the figure below.

42. The figure depicts a
a. neuronal action potential.
b. cardiac action potential.
c. pacemaker potential.
d. graded potential.
Answer: b
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

43. What is the best explanation for the plateau shown in the figure?
a. Voltage-gated Na+ channels remain open.
b. Voltage-gated Ca2+ channels remain open.
c. Voltage-gated K+ channels close.
d. Leaky K+ channels remain open.
Answer: b
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

44. Which statement about ion permeability as shown in the figure is true?
a. K+ permeability is at its lowest very close to the membrane potential peak.

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b. K+ permeability is at its highest very close to the membrane potential peak.
c. Na+ permeability is at its lowest very close to the membrane potential peak.
d. Na+ permeability is at its highest very close to the membrane potential peak.
Answer: d
Textbook Reference: The Action Potential
Bloom’s Category: 4. Analyzing

45. The absolute refractory period of the action potential is best explained by
a. inactivated voltage-gated sodium channels.
b. closed voltage-gated sodium channels.
c. open slow calcium channels.
d. inactivated voltage-gated potassium channels.
Answer: a
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

46. Which statement about a local circuit in an axon is false?
a. Ions flow in intracellular fluid, carrying current to more distant parts of the membrane.
b. At the membrane, the ion movements change the distribution of charges on the
membrane capacitance.
c. An ionic current completes the local circuit as cations move toward the locus of the
action potential and anions move away.
d. Anions migrate into the membrane interior.
Answer: d
Textbook Reference: The Propagation of Action Potentials
Bloom’s Category: 4. Analyzing

47. _______ prevents bidirectional propagation of action potentials.
a. The inactivation of Na+ channels
b. A decrease in membrane resistance
c. Myelination
d. The K+ channel
Answer: a
Textbook Reference: The Propagation of Action Potentials
Bloom’s Category: 2. Understanding

48. Conduction velocity shows _______ axon diameter.
a. a proportional relationship to
b. a proportional relationship to the square root of
c. an exponential relationship to
d. either a proportional relationship to, or a proportional relationship to the square root of
Answer: d
Textbook Reference: The Propagation of Action Potentials
Bloom’s Category: 2. Understanding

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49. Considering neurons in living systems, which variable affects conduction velocity the
most?
a. Myelination
b. Temperature
c. Length
d. Diameter
Answer: a
Textbook Reference: The Propagation of Action Potentials
Bloom’s Category: 5. Evaluating

50. Myelination by Schwann cells increases the velocity of action potential propagation
by
a. increasing the resistance and decreasing the capacitance, allowing the action potential
to “jump” over the myelinated area.
b. decreasing the resistance and increasing the capacitance, allowing the action potential
to “jump” over the myelinated area.
c. increasing the resistance and increasing the capacitance, allowing the action potential
to “jump” over the myelinated area.
d. increasing the diameter of the neuron.
Answer: a
Textbook Reference: The Propagation of Action Potentials
Bloom’s Category: 2. Understanding

Short Answer

1. Compare and contrast nervous systems and endocrine systems.
Answer: Neural and endocrine systems are both systems for communication within the
body. Nervous systems are faster and capable of much finer temporal and spatial control,
whereas endocrine systems typically control more widespread and prolonged activities.
Textbook Reference: The Physiology of Control: Neurons and Endocrine Cells
Compared
Bloom’s Category: 2. Understanding

2. Describe the startle response in the cockroach.
Answer: The cockroach’s startle response is a reflex. Sound waves or air vibrate the
filiform hair receptors, which generate impulses in sensory neurons. The sensory neurons
excite the giant interneurons that synapse with leg motor neurons. Once excited, the leg
motor neurons activate the leg muscles.
Textbook Reference: Neurons Are Organized into Functional Circuits in Nervous
Systems
Bloom’s Category: 2. Understanding

3. What are glial cells and how do they aid in the function of the nervous system?
Answer: Glial cells are the support cells of the nervous system. They form the myelin
around neurons, which increases action potential velocity. They surround capillaries and

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act as metabolic intermediaries between neurons and their circulatory supply. They also
serve immune and scavenging functions in order to protect surrounding neurons.
Textbook Reference: The Cellular Organization of Neural Tissue
Bloom’s Category: 2. Understanding

4. Compare and contrast current and voltage with respect to the cell membrane.
Answer: The net movement of charge constitutes an electric current. The separation of
positive and negative charges constitutes a voltage. In terms of the cell membrane, the
current would be a flow of ions through channels in the membrane, whereas the voltage
would be the separation of charges across the membrane.
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 2. Understanding

5. Since the bulk solutions that make up the intracellular and extracellular fluids maintain
charge neutrality, how does the cell produce membrane potentials?
Answer: The charge separation producing the membrane potential is an extraordinarily
local phenomenon. According to Figure 12.11, in any given 1 µm3 section around each
side of the membrane, only six pairs of ions, from the 110,000 cations and 110,000
anions in each fluid compartment, need to sit on the membrane to charge its capacitance,
producing a membrane potential of –90 mV.
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 2. Understanding

6. Explain in mechanistic terms how the action potential is an all-or-none phenomenon.
Answer: The action potential is initiated only when a threshold depolarization is reached
near the axon hillock. That is, a certain critical number of voltage-gated Na+ channels
have to open in order to cause a depolarization that is strong enough to initiate the
Hodgkin cycle and, by definition, perpetuate the further opening of voltage-gated Na+
channels via their own depolarization. If the threshold is not reached, there will be no
Hodgkin cycle or action potential.
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

7. Compare and contrast the techniques of patch clamping and voltage clamping.
Answer: Both patch clamping and voltage clamping provide experimental information
about membrane currents, especially during an action potential. The patch-clamp
technique uses a micropipette to record single channel currents, whereas the voltage-
clamp technique shows whole cell ionic currents.
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

8. What are the similarities and differences among the channels in the voltage-gated
channel superfamily?
Answer: All the voltage-gated channels have principal subunits with extensive sequence
homology and thus are evolutionarily related. Voltage-gated Na+ and Ca2+ channels have

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four domains, whereas the voltage-gated K+ channel has one domain that is homologous
to one of the domains on the Na+ channel.
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

9. Explain in mechanistic terms why the action potential can travel a great distance along
an axon without degrading.
Answer: The same mechanism that is responsible for the rising phase of the action
potential also aids in its perpetuation along the axon without degradation. The action
potential on one location on the axon can itself initiate an action potential at a
neighboring location, and the induced action potential will have the same all-or-none
amplitude as the original.
Textbook Reference: The Propagation of Action Potentials
Bloom’s Category: 2. Understanding

10. Describe the significance of myelination.
Answer: Myelination greatly increases conduction velocity of an axon by increasing the
membrane resistance while decreasing the membrane capacitance. In other words,
conduction velocity is increased by increasing the length constant without increasing the
time constant. Action potentials occur only at the nodes of Ranvier, in a process that is
called saltatory conduction.
Textbook Reference: The Propagation of Action Potentials
Bloom’s Category: 2. Understanding

ONLINE QUIZ QUESTIONS

1. The neuron converts an electrical signal to a chemical signal in the
a. dendrite.
b. presynaptic terminal.
c. cell body.
d. axon hillock.
Answer: b
Textbook Reference: The Physiology of Control: Neurons and Endocrine Cells
Compared
Bloom’s Category: 1. Remembering

2. Neurons that relay sensory signals to integrative centers of the CNS are called
a. interneurons.
b. afferent neurons.
c. synaptic neurons.
d. efferent neurons.
Answer: b
Textbook Reference: The Physiology of Control: Neurons and Endocrine Cells
Compared

© 2016 Sinauer Associates, Inc.
Bloom’s Category: 1. Remembering

3. Which glial cells function as metabolic intermediaries between capillaries and
neurons?
a. Schwann cells
b. Oligodendrocites
c. Astrocytes
d. Microglial cells
Answer: c
Textbook Reference: The Cellular Organization of Neural Tissue
Bloom’s Category: 1. Remembering

4. Which term best describes the movement of ions across a membrane?
a. Current
b. Voltage
c. Resistance
d. Capacitance
Answer: a
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 1. Remembering

5. A decrease in the absolute value of the membrane potential toward zero is called
a. depolarization.
b. an action potential.
c. hyperpolarization.
d. a membrane potential.
Answer: a
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 1. Remembering

6. Which of the following actively contributes to the cell’s membrane potential?
a. Permeability to K+
b. Permeability to Na+
c. The overall resistance of the membrane
d. Electrogenic ion pumps
Answer: d
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 5. Evaluating

7. The time constant (τ) depends on the _______ of the membrane.
a. resistance
b. capacitance
c. resistance and voltage
d. resistance and capacitance
Answer: d
Textbook Reference: The Ionic Basis of Membrane Potentials

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Bloom’s Category: 2. Understanding

8. If a current pulse is generated on the membrane and creates a passive potential, which
statement will be true?
a. The change in the membrane potential will increase as the distance from the current
pulse increases.
b. The change in the membrane potential will decrease as the distance from the current
pulse increases.
c. The change in the membrane potential will remain constant throughout the length of
the membrane.
d. The change in the membrane potential will fluctuate depending on the strength of the
initial current pulse.
Answer: b
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 3. Applying

9. The plasma membrane of a resting neuron is most permeable to which ion?
a. Na+
b. K+
c. Cl–
d. Ca2+
Answer: b
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 2. Understanding

10. If ouabain was used to block Na+–K+-ATPase pumps,
a. Na+ would go to equilibrium across the cell membrane.
b. the membrane potential would become more negative.
c. the concentration of K+ would be equal on both sides of the membrane.
d. the cell would maintain steady state with a different membrane potential.
Answer: a
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 3. Applying

11. In a typical neuron, which ion is in passive equilibrium across the cell membrane?
a. Na+
b. K+
c. Cl–
d. Both Na+ and K+
Answer: c
Textbook Reference: The Ionic Basis of Membrane Potentials
Bloom’s Category: 2. Understanding

12. A stimulating depolarizing current that depolarizes the axon hillock just slightly
negative to the threshold will
a. not change the overall membrane potential at all.

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b. produce an action potential.
c. produce a very small action potential.
d. produce a temporary graded potential.
Answer: d
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

13. _______ channels govern the generation of an action potential.
a. Ligand-gated Na+
b. Ligand-gated K+
c. Voltage-gated Na+
d. Voltage-gated K+
Answer: c
Textbook Reference: The Action Potential
Bloom’s Category: 1. Remembering

14. Considering the cycle of an action potential, when is the permeability to K+ at its
greatest?
a. During the resting membrane potential
b. During the rising phase of the action potential
c. At the peak of the action potential
d. During the falling phase of the action potential
Answer: d
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

15. Which statement regarding the action potential is false?
a. In an extremely long axon, the action potential eventually will degrade.
b. During the “falling” phase, K+ permeability increases.
c. During the “rising” phase, Na+ moves into the neuron.
d. In the recovery phase, Na+ channels are closed.
Answer: a
Textbook Reference: The Action Potential
Bloom’s Category: 5. Evaluating

16. What allows the action potential to return to a repolarized state?
a. Voltage-gated Na+ channels become inactivated.
b. Voltage-gated K+ channels become inactivated.
c. Na+ reaches equilibrium across the neural membrane and stops leaking in.
d. Voltage-gated Na+ channels close.
Answer: a
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

17. Which statement regarding cardiac pacemaker cells is false?
a. They spontaneously generate action potentials.

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b. The frequency of action potential generation can be modified by neural input.
c. The pacemaker cells are modified neural tissue.
d. They are connected to myocardium via gap junctions.
Answer: c
Textbook Reference: The Action Potential
Bloom’s Category: 5. Evaluating

18. _______ are responsible for extending the time of the cardiac action potential relative
to a neural action potential.
a. Slow Ca2+ channels
b. Slow Na+ channels
c. Slow K+ channels
d. Voltage-gated Na+ channels
Answer: a
Textbook Reference: The Action Potential
Bloom’s Category: 2. Understanding

19. Which character of neurons affects conduction velocity the least?
a. Axon diameter
b. Myelination
c. Axon length
d. Temperature
Answer: c
Textbook Reference: The Propagation of Action Potentials
Bloom’s Category: 5. Evaluating

20. In myelinated axons, action potentials occur
a. all along the axon.
b. only at the internodes.
c. only at the initial segment of the axon.
d. only at the nodes of Ranvier.
Answer: d
Textbook Reference: The Propagation of Action Potentials
Bloom’s Category: 2. Understanding

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