Deck 48: Electrical Signals in Animals

A) I
B) II
C) IV
D) V

A) sensory neurons
B) motor neurons
C) interneurons
D) peripheral neurons

A) a graded potential
B) a threshold potential
C) an equilibrium potential
D) an action potential

A) dendrites
B) nerve cell bodies
C) synapses
D) axons

A) Cl-
B) Ca++
C) Na+
D) K+

A) The sodium and potassium channels would all be closed.
B) The membrane would become more permeable to sodium.
C) The "resting" distribution of potassium and sodium ions would be altered.
D) The physical structure of the plasma membrane would break down.

A) The channels are always open, but the concentration gradients of ions frequently change.
B) The channels are always closed, but ions move closer to the channels during excitation.
C) The channels are open or closed depending on their type, and are specific as to which ion can traverse them.
D) The channels are open in response to stimuli, and then they close simultaneously.

A) increase
B) decrease
C) repolarize
D) remain unchanged

A) The membrane is also slightly permeable to sodium ions.
B) The membrane is also fully permeable to calcium ions.
C) The membrane is also impermeable to sodium ions.
D) The membrane is also highly permeable to chloride ions.

A) highly branched dendrites
B) highly branched axons
C) a highly branched cell body
D) thousands of axons

A) The membrane potential would become more negative.
B) The membrane potential would become less negative.
C) The membrane potential would be unaffected.
D) The membrane potential would become positive.

A) hydrostatic pressure
B) the ion concentration gradient
C) the osmotic gradient
D) the temperature (thermal) gradient

A) the presynaptic cell
B) the postsynaptic cell
C) axon hillocks
D) cell bodies

A) inside of an axon hillock
B) along the length of a dendrite
C) in a chemical synapse
D) in the cell body of a neuron

A) osmosis
B) diffusion of chloride ions
C) sodium-potassium pumps
D) exocytosis and endocytosis

A) I
B) II
C) III
D) IV

A) It pumps sodium and potassium ions into the cell.
B) It pumps sodium and potassium ions out of the cell.
C) It pumps sodium ions into the cell and potassium ions out of the cell.
D) It pumps sodium ions out of the cell and potassium ions into the cell.

A) I
B) II
C) IV
D) V

A) integration, sensory input, motor output
B) motor output, integration, sensory input
C) sensory input, motor output, integration
D) sensory input, integration, and motor output

A) I
B) II
C) IV
D) V

A) no action potential will be initiated
B) an action potential will be initiated and proceed only in the normal direction toward the axon terminal
C) an action potential will be initiated and proceed only back toward the axon hillock
D) two action potentials will be initiated and will proceed in opposite directions

A) thin, unmyelinated axons
B) thin, myelinated axons
C) thick, unmyelinated axons
D) thick, myelinated axons

A) increasing its permeability to Na+
B) decreasing its permeability to Cl-
C) increasing its permeability to Ca++
D) increasing its permeability to K+

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

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

A) depolarization of the neuron
B) hyperpolarization of the neuron
C) replacement of potassium ions with sodium ions
D) replacement of potassium ions with calcium ions

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

A) Action potentials for a given neuron vary in magnitude.
B) Action potentials for a given neuron vary in duration.
C) Action potentials propagate towards the synaptic terminal of an axon.
D) Movement of ions during the action potential occurs mostly through the sodium pump.

A) voltage-gated potassium channels opening and sodium channels inactivating
B) a decrease in the membrane's permeability to potassium and chloride ions
C) a brief inhibition of the sodium-potassium pump
D) the opening of more voltage-gated sodium channels

A) action potentials
B) graded hyperpolarizations
C) excitatory postsynaptic potentials
D) threshold potentials

A) become hyperpolarized during an action potential
B) not repolarize during an action potential
C) not be able to open potassium channels
D) not release neurotransmitter molecules

A) the rate at which action potentials are produced
B) the type of neurotransmitter involved in the signal
C) the types of ions involved in conveying the action potential
D) the degree of depolarization and repolarization of the membrane

A) the slow opening of voltage-gated sodium channels
B) the sustained opening of voltage-gated potassium channels
C) the rapid opening of voltage-gated calcium channels
D) the slow restorative actions of the sodium-potassium ATPase

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

A) The fish's axons are smaller in diameter than the axons in the crab.
B) The fish's axons are myelinated. The crab's axons are not myelinated.
C) The fish's axons are not myelinated. The crab's axons are myelinated.
D) There is a higher percentage of ion channels in the axons of the crab compared with the percentage of ion channels in fish axons.

A) osmosis
B) active transport
C) diffusion
D) exocytosis

A) more slowly in axons of large diameter than in axons of small diameter
B) by activating the sodium-potassium "pump" at each point along the axonal membrane
C) more rapidly in myelinated than in unmyelinated axons
D) by reversing the concentration gradients for sodium and potassium ions

A) in a graded potential
B) in an action potential
C) during hyperpolarization
D) during depolarization

A) Action potentials move in the opposite direction on the axon.
B) Action potentials move more slowly along the axon.
C) No action potentials are transmitted.
D) Action potentials grow stronger as they move down an axon.

A) acetylcholine
B) epinephrine
C) nitric oxide
D) GABA

A) presynaptic release of acetylcholine
B) absorption of acetylcholine
C) binding of acetylcholine on the postsynaptic membrane
D) synthesis of acetylcholine receptors

A) a voltage-gated channel
B) a ligand-gated channel
C) a second-messenger-gated channel
D) a chemical that inhibits action potentials

A) 1 → 2 → 3 → 4 → 5
B) 2 → 3 → 5 → 4 → 1
C) 3 → 2 → 5 → 1 → 4
D) 4 → 3 → 1 → 2 → 5

A) acetylcholine
B) endorphin
C) nitric oxide
D) GABA

A) electrical synapses in a vertebrate heart
B) acetylcholine receptors at a neuromuscular junction
C) the breakdown of acetylcholine in a neuromuscular synapse
D) the action of NO on smooth muscle

A) acetylcholine
B) endorphin
C) nitric oxide
D) GABA

A) the presynaptic membrane
B) axon hillocks
C) cell bodies
D) the smooth endoplasmic reticulum

A) There is a net diffusion of Na+ out of the cell.
B) The equilibrium potential for K+(Ek) becomes more positive.
C) The neuron's membrane voltage becomes more positive.
D) The cell's inside becomes more negative than the outside.

A) the muscle cell would not be able to contract
B) the muscle cell would receive constant stimulation
C) there would be a decrease in the frequency of action potentials
D) there would be no effect on the muscle cell function

A) the nuclear membrane
B) region of the cell body where dendrites converge
C) the presynaptic terminals of the longest axon
D) the axon hillock

A) the nuclear membrane
B) the nodes of Ranvier
C) the postsynaptic membrane
D) synaptic vesicle membranes

A) temporal summation
B) spatial summation
C) highly branched dendrites
D) the generation of substance P

A) cause the membrane to hyperpolarize and then depolarize
B) can undergo temporal and spatial summation
C) are triggered by a depolarization that reaches threshold
D) move at the same speed along all axons

A) activate G proteins
B) close potassium channels
C) open sodium channels
D) hyperpolarize the membrane

A) gap junctions
B) acetylcholine
C) G protein-coupled receptors
D) summation

A) a stronger action potential
B) a weaker action potential
C) no action potential
D) many action potentials

A) Only dendrites can respond to electrical signals.
B) The postsynaptic cell contains most of the synaptic vesicles.
C) Receptors for neurotransmitters are mostly found on the postsynaptic membrane.
D) Myelination prevents two-way transmission of signals.

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

A) potassium ions
B) sodium ions
C) ATP
D) all neurotransmitter molecules

A) Voltage-gated calcium channels in the membrane open.
B) Synaptic vesicles fuse with the membrane.
C) Ligand-gated channels open, allowing neurotransmitters to enter the synaptic cleft.
D) An EPSP or IPSP is generated in the postsynaptic cell.

A) the threshold value in the postsynaptic membrane for cell X is different from that for cell Y
B) the axon of cell X is myelinated, but that of cell Y is not
C) only cell Y produces an enzyme that terminates the activity of the neurotransmitter
D) cells X and Y express different receptor molecules for this particular neurotransmitter