Deck 43: Animal Nervous Systems

A) The axon hillock has a higher membrane potential than the terminals of the axon.
B) Voltage- gated channels for both Na+ and K+ open in only one direction.
C) The brief refractory period prevents reopening of voltage- gated Na+ channels.
D) Ions can flow along the axon in only one direction.
E) The nodes of Ranvier conduct potentials in one direction.

A) Na⁺
B) Mg⁺⁺
C) Cl^-
D) Ca⁺⁺
E) K⁺

A) A
B) B
C) C
D) D
E) E

A) slow decrease of resting potential
B) immediate loss of resting potential
C) immediate loss of action potentials
D) no effect

A) opening of K⁺ channels in the membrane.
B) opening of Na⁺ channels in the membrane.
C) a K⁺ concentration gradient across the membrane.
D) a Na⁺ concentration gradient across the membrane.
E) both B and D

A) no effect; the substances counteract each other
B) slow decrease of resting potential and action potential amplitudes
C) immediate loss of action potential with gradual loss of resting potential
D) immediate loss of resting potential

A) They increase the permeability of Na⁺ ions in the plasma membrane.
B) They cause action potentials to "jump" down the axon rather than travel in a continuous path along every site on the axon.
C) They amplify the action potential by increasing sodium influx along the entire distance of the neuron.
D) All of the above answers apply.

A) A
B) B
C) C
D) D
E) E

A) Movement of ions during the action potential occurs mostly through the sodium pump.
B) The frequency of action potentials, not their size, is the meaningful signal.
C) Action potentials are propagated down the length of the axon.
D) All action potentials for a given neuron are identical in magnitude.
E) All action potentials for a given neuron are identical in duration.

A) A
B) B
C) C
D) D
E) E

A) it can transmit action potentials much faster than small axons can.
B) it can transmit action potentials at a higher frequency i.e., fire faster) than small axons can.
C) It can generate larger amplitude action potentials than small axons can.
D) It can generate longer duration action potentials than small axons can.
E) Answers A and C are both correct.

A) sodium- potassium pumps.
B) osmosis.
C) diffusion.
D) symports and antiports.

A) Neurons would not be able to undergo normal action potentials.
B) Action potentials would occur with greater frequency.
C) Neurons would all be depolarized.
D) Neurons would remain refractory following closure of voltage- gated sodium channels.
E) K⁺ channels would open to compensate for changes in membrane potential.

A) because the Na⁺ concentration is much higher outside the cell than it is inside
B) because the Na⁺ ions are attracted to the negatively charged interior
C) because the Na⁺ ions are actively transported by the sodium- potassium pump into the cell
D) both A and B
E) both A and C

A) interneuron
B) motor neuron
C) sensory neuron
D) A and B
E) all of the above

A) The membrane potential would become more negative.
B) The membrane potential would remain the same.
C) The membrane potential would become less negative.

A) The fish's axons are smaller in diameter; small axons transmit action potentials faster than large axons do.
B) Unlike the crab, the fish's axons are wrapped in myelin.
C) There are more ion channels in the axons of the crab compared with fish axons.
D) Answers A and B are both correct.

A) The signal would fade because it is not renewed by the opening of more sodium channels.
B) There could be no action potential generated at the axon hillock.
C) The action potential would be propagated nearly instantaneously to the synapse.
D) None of the above could happen.

A) prevent the hyperpolarization phase of the action potential.
B) prevent the depolarization phase of the action potential.
C) increase the release of neurotransmitter molecules.
D) have most of its effects on the dendritic region of a neuron.
E) prevent graded potentials.

A) the gallbladder is stimulated to release bile
B) pupils dilate
C) heartbeat is slowed
D) digestive activity is stimulated

A) yes
B) no

A) structural support for both hemispheres
B) transport of proteins between the hemispheres
C) source of nutrients for both hemispheres
D) communication between the hemispheres

A) parasympathetic nerves
B) somatic nerves
C) sympathetic nerves
D) both B and C

A) changes to the chemical structure of neurotransmitters
B) molecular and structural changes at synapses
C) changes in myelination of axons
D) structural changes to ion channels in axon
E) changes in the concentration of ions in the extracellular fluid surrounding neurons

A) membrane potential was reached
B) threshold potential was reached
C) resting potential was reached

A) when enough voltage- gated sodium channels open.
B) when threshold potential is reached.
C) in response to an action potential depolarizing the presynaptic membrane.

A) stomach activity.
B) pupil dilation and constriction.
C) airway diameter.
D) heart rate.
E) contraction of skeletal muscle.

A) Increase K⁺ permeability.
B) Increase the influx of calcium.
C) Increase sodium- potassium pump activity.
D) All of the above apply.

A) addition of tetrodotoxin to the extracellular fluid at the axon terminal
B) increase in extracellular sodium and potassium ion concentrations at the axon terminal
C) reduction in extracellular calcium ion concentration at the axon terminal
D) All of the above manipulations would reduce the release of neurotransmitter.

A) increased heartbeat
B) constriction of airways
C) dilation of pupils
D) all of the above
E) only A and C

A) axon dendrite
B) axon hillock
C) axon terminal
D) axon cell body

A) replenishing missing ion channels.
B) preventing temporal lobe seizures.
C) repairing sites of traumatic brain injury.
D) secreting the neurotransmitter dopamine.
E) both A and D.

A) PNS efferent division CNS interneuron PNS afferent division effector
B) CNS efferent division CNS interneuron PNS afferent division effector
C) CNS afferent division CNS interneuron PNS efferent division effector
D) PNS afferent division CNS interneuron PNS efferent division effector

A) lesion studies of individuals with damage to particular brain regions.
B) direct electrical stimulation of regions of cerebral cortex.
C) recording from single neurons during memory tasks.
D) both A and B.
E) all of the above.

A) gamma- aminobutyric acid
B) dopamine
C) acetylcholine
D) glutamate

A) An action potential would be generated that would travel to the synapse with the next neuron.
B) An action potential would be generated that would travel back towards the cell body.
C) No action potential could be generated at this location.
D) Answers A and B both apply.

A) sense of touch
B) sense of hearing
C) sense of taste
D) sense of sight

A) close potassium channels.
B) close chloride channels.
C) act independently of their receptor proteins.
D) open sodium channels.
E) hyperpolarize the membrane.