Deck 8: Neurons: Cellular and Network Properties

A) central nervous system.
B) autonomic division system.
C) somatic motor division of the nervous system.
D) peripheral nervous system.
E) visceral nervous system.

A) central nervous system.
B) autonomic division system.
C) somatic motor division of the nervous system.
D) peripheral nervous system.
E) visceral nervous system.

A) myelin sheath.
B) axon terminal.
C) collaterals.
D) axon hillock.
E) synapse.

A) fast
B) slow
C) Neither of these

A) cell bodies.
B) axons.
C) dendrites.
D) somata.
E) None of the answers are correct.

A) protrusions.
B) processes.
C) prostheses.
D) projections.

A) 90% of the cell volume.
B) 50% of the cell volume.
C) 10% of the cell volume.
D) found in the same position on every neuron.

A) collateral.
B) hillock.
C) synapse.
D) nerve.
E) dendrites.

A) central nervous system.
B) autonomic nervous system.
C) somatic motor division.
D) peripheral nervous system.
E) enteric nervous system.

A) reproduction.
B) digestion.
C) excretion, particularly urination.
D) the skeletal system.
E) the endocrine system.

A) afferent
B) sensory
C) efferent
D) afferent and sensory
E) sensory and efferent

A) visceral and somatic divisions.
B) sympathetic and parasympathetic divisions.
C) central and peripheral divisions.
D) visceral and enteric divisions.
E) somatic and enteric divisions.

A) 1 and 2
B) 1 and 3
C) 2 and 4
D) 3 and 4
E) 3 and 5

A) only in the brain.
B) only in the spinal cord.
C) only in the CNS.
D) throughout the nervous system.
E) only in spinal nerves.

A) dendrites.
B) axon terminals.
C) collaterals.
D) axon hillocks.
E) synapses.

A) axon hillock.
B) varicosity.
C) axon.
D) dendrite.
E) nerve.

A) the release of neurotransmitter molecules from the axon.
B) the transport of microtubules to the axon for structural support.
C) vesicle transport of proteins and organelles down the axon.
D) the movement of the axon terminal to synapse with a new postsynaptic cell.
E) None of the answers are correct.

A) axon terminals only.
B) axon varicosities only.
C) dendritic spines only.
D) cell bodies only.
E) axon terminals and axon varicosities.

A) only provide structural and metabolic support.
B) only guide neurons during growth and repair.
C) only help maintain homeostasis of the brain's extracellular fluid.
D) provide structural and metabolic support and help maintain homeostasis of the brain's extracellular fluid.
E) All of the answers are correct.

A) the amplitude of the action potential.
B) the length of the axon.
C) the total number of action potentials.
D) the amplitude of the graded potential.

A) dendrites
B) cell body
C) axon hillock
D) synaptic cleft
E) synaptic bouton

A) electrical signals only.
B) chemical signals only.
C) neurotransmitters only.
D) neuromodulators only.
E) electrical signals and chemical signals.

A) inactivation gate - closed at rest
B) activation gate - open at rest
C) inactivation gate - closed during repolarization
D) activation gate - opens during depolarization
E) All of the answers are incorrectly matched.

A) axons only.
B) Schwann cells only.
C) oligodendrocytes only.
D) Schwann cells and oligodendrocytes.

A) intracellular ion concentrations.
B) extracellular ion concentrations
C) the membrane potential resulting from all permeable ions.
D) the membrane potential resulting from permeability to a single ion.
E) the threshold membrane potential.

A) microglia.
B) neuroglia.
C) glia.
D) ganglia.
E) nodes.

A) Na⁺ flow in the cell only.
B) Na⁺ flow out of the cell only.
C) K⁺ flow out of the cell only.
D) K⁺ flow into the cell only.
E) Na⁺ flow out of the cell and K⁺ flow into the cell.

A) potassium
B) sodium
C) chloride
D) calcium
E) More than one of the answers is correct.

A) Schwann cells
B) astrocytes
C) microglia
D) oligodendrocytes
E) ependymal cells

A) uneven distribution of ions across the cell membrane only.
B) differences in membrane permeability to Na⁺ and K⁺ only.
C) activity of the sodium/potassium pump only.
D) uneven distribution of ions across the cell membrane and differences in membrane permeability to Na⁺ and K⁺.
E) None of the answers are correct.

A) depolarization.
B) rising phase.
C) falling phase.
D) overshoot.
E) peak.

A) sodium
B) potassium
C) calcium
D) chloride
E) sodium, potassium, or calcium

A) Schwann cells
B) astrocytes
C) microglia
D) oligodendrocytes
E) ependymal cells

A) closing of the channel in response to decrease in the stimulus.
B) closing of the channel even when the stimulus continues.
C) any type of channel closing.
D) None of the answers are correct.

A) 61/z × log [ion]_out / [ion]_in
B) 61/z × log [ion]_in / [ion]_out
C) log 61/z × [ion]_in / [ion]_out
D) log 61/z × [ion]_out / [ion]_in

A) only ensures one-way travel down an axon.
B) only allows a neuron to ignore a second signal sent that closely follows the first.
C) only prevents summation of action potentials.
D) ensures one-way travel down an axon and allows a neuron to ignore a second signal sent that closely follows the first.
E) ensures one-way travel down an axon, allows a neuron to ignore a second signal sent that closely follows the first, and prevents summation of action potentials.

A) Na⁺ flow into the cell only.
B) Na⁺ flow out of the cell only.
C) K⁺ flow out of the cell only.
D) K⁺ flow into the cell only.
E) Na⁺ flow out of the cell and K⁺ flow into the cell.

A) the electrical charges of the ions
B) the permeabilities of the ions
C) the solubilities of the ions
D) the sizes of the ions
E) the temperature

A) must re-establish ion concentrations after each action potential.
B) transports sodium ions into the cell during depolarization.
C) transports potassium ions out of the cell during repolarization.
D) moves sodium and potassium in the direction of their chemical gradients.
E) requires ATP to function.

A) within the cytosol only.
B) in the membranes of dendrites only.
C) in the membranes of axons only.
D) on the neuron cell body only.
E) in the membranes of dendrites, in the membranes of axons, and on the neuron cell body.

A) 1, 2, 3, 4, 5
B) 1, 2, 3, 4
C) 2, 3, 4
D) 2, 3, 4, 5
E) 1, 3, 4

A) Increase the diameter of the axon, decrease the resistance of the axon membrane to ion leakage.
B) Increase the diameter of the axon, increase the resistance of the axon membrane to ion leakage.
C) Decrease the diameter of the axon, decrease the resistance of the axon membrane to ion leakage.
D) Decrease the diameter of the axon, increase the resistance of the axon membrane to ion leakage.

A) dendrites only.
B) cell bodies only.
C) axons only.
D) dendrites and axons.
E) cell bodies and axons.

A) chemical
B) electrical
C) mechanical
D) processing
E) radiative

A) initiate an action potential.
B) depolarize the membrane to the threshold voltage.
C) hyperpolarize the membrane.
D) be called EPSPs or IPSPs.
E) All of the statements are true.

A) all stimuli will produce identical action potentials.
B) all stimuli great enough to bring the membrane to threshold will produce action potentials of identical magnitude.
C) the greater the magnitude of the stimuli, the greater the intensity of the action potential.
D) only sensory stimuli can activate action potentials.
E) only motor stimuli can activate action potentials.

A) send action potentials with higher voltage (higher amplitude).
B) send action potentials with longer durations.
C) send action potentials with higher frequency.
D) do nothing; no change is possible since the all-or-none law is in effect.

A) inactivate the enzyme that destroys the neurotransmitter only.
B) bind to Na⁺ channels and inactivate them only.
C) prevent depolarization by blocking Na⁺ entry into the cell only.
D) inactivate the enzyme that destroys the neurotransmitter and bind to Na⁺ channels and inactivate them.
E) bind to Na⁺ channels and inactivate them and prevent depolarization by blocking Na⁺ entry into the cell.

A) Cl^- ions enter the cell.
B) Cl^- ions leave the cell.
C) the cell becomes depolarized.
D) Cl^- ions enter the cell and the cell becomes depolarized.
E) Cl^- ions leave the cell and the cell becomes depolarized.

A) length of the axon
B) presence or absence of a myelin sheath
C) diameter of the axon
D) presence or absence of nodes of Ranvier
E) whether axon is sensory or motor

A) sodium.
B) potassium.
C) calcium.
D) chloride.
E) zinc.

A) one
B) a few dozen
C) a few hundred
D) a few thousand
E) a few million

A) the Na⁺ and K⁺ ions that moved in/out of the cell must move back to their original compartments.
B) the Na⁺ inactivation gate must open and the Na⁺ activation gate must close.
C) the absolute refractory period must occur.
D) the Na⁺ and K⁺ ions that moved in/out of the cell must move back to their original compartments; the Na⁺ inactivation gate must open; and the Na⁺ activation gate must close.
E) None of the answers are correct.

A) Na⁺ enters the neuron.
B) Na⁺ leaves the neuron.
C) the neuron depolarizes.
D) Na⁺ enters the neuron and the neuron depolarizes.
E) Na⁺ leaves the neuron and the neuron depolarizes.

A) blood
B) intracellular
C) interstitial
D) extracellular
E) All of the answers are correct.

A) K⁺ enters the neuron.
B) K⁺ leaves the neuron.
C) the neuron depolarizes.
D) K⁺ enters the neuron and the neuron depolarizes.
E) K⁺ leaves the neuron and the neuron depolarizes.

A) higher in amplitude only.
B) more frequent only.
C) longer-lasting only.
D) higher in amplitude and more frequent.
E) higher in amplitude and longer-lasting.

A) Ca²⁺ concentration in the blood and interstitial fluid.
B) Na⁺ concentration in the blood and interstitial fluid.
C) K⁺ gradient between the blood and interstitial fluid.
D) K⁺ concentration inside cells.
E) Na⁺ concentration inside cells.

A) chemical synapse.
B) electrical synapse.
C) trigger zone.
D) dendritic membrane.
E) axon terminal.

A) only open chemically gated ion channels, causing graded potentials known as fast synaptic potentials.
B) only close ion channels via G proteins and second messenger systems, producing slow responses.
C) only regulate protein synthesis and affect the metabolic activities of the postsynaptic cell.
D) open chemically gated ion channels, causing graded potentials known as fast synaptic potentials and regulate protein synthesis and affect the metabolic activities of the postsynaptic cell.
E) open chemically gated ion channels, causing graded potentials known as fast synaptic potentials, close ion channels via G proteins and second messenger systems, producing slow responses, and regulate protein synthesis and affect the metabolic activities of the postsynaptic cell.

A) spatial summation
B) temporal summation
C) inhibition of the impulse
D) hyperpolarization
E) decrease in speed of impulse transmission

A) less likely to be in use, just through hyperpolarization of selected neurons.
B) more likely to be in use, just through depolarization of selected neurons.
C) capable of alteration, just through training and conditioning.
D) less likely to be in use, just through hyperpolarization of selected neurons and capable of alteration, just through training and conditioning.
E) more likely to be in use, just through depolarization of selected neurons and capable of alteration, just through training and conditioning.

A) Na⁺
B) K⁺
C) Cl^-
D) H⁺
E) Ca²⁺

A) GABA only
B) glycine only
C) glutamate only
D) GABA and glycine
E) All of the answers are correct.

A) norepinephrine.
B) glutamate.
C) acetylcholine.
D) GABA.
E) glycine.

A) An action potential is fired off more quickly than usual.
B) Nothing. They will cancel each other out.
C) The cell becomes hyperpolarized.
D) The cell becomes easier to excite.
E) The cell dies.

A) An excitatory and inhibitory signal can cancel each other out.
B) Two excitatory stimuli may be additive, and summation could occur.
C) Two inhibitory stimuli may be additive, resulting in lower excitability.
D) An excitatory and inhibitory signal can cancel each other out and two excitatory stimuli may be additive, and summation could occur.
E) An excitatory and inhibitory signal can cancel each other out; two excitatory stimuli may be additive, and summation could occur; and two inhibitory stimuli may be additive, resulting in lower excitability.

A) EPSPs that reach threshold can initiate an action potential.
B) The trigger zone is the integrating center of the neuron.
C) IPSPs depolarize the membrane.
D) All of the statements are true.

A) result in local depolarizations.
B) result in local hyperpolarizations.
C) increase membrane permeability to sodium ions.
D) prevent the escape of potassium ions.
E) prevent the escape of calcium ions.

A) exocytosis of a neurocrine
B) release of the neurotransmitter into the synaptic cleft
C) release of a neurohormone into the blood
D) Any of the above could happen next.

A) electrical signals reaching neurons from outer space.
B) multiple graded potentials arriving at one location simultaneously.
C) repeated graded potentials reaching the trigger zone one after the other.
D) suprathreshold potentials triggering action potentials that are extra large.
E) All of the answers are correct.

A) Ion channels open, allowing ions to enter or exit.
B) The membrane permeability is altered.
C) A second messenger is activated on the inside of the cell.
D) Any of these actions could happen next.

A) is necessary for acetylcholine synthesis.
B) signals the exocytosis of the neurotransmitter.
C) binds to receptors on the postsynaptic cell, opening ion channels, and triggering graded potentials.
D) leaves the axon terminal, hyperpolarizing the cell.

A) depolarizes a neuron, decreasing the likelihood of an action potential.
B) hyperpolarizes a neuron, decreasing the likelihood of an action potential.
C) depolarizes a neuron, increasing the likelihood of an action potential.
D) hyperpolarizes a neuron, increasing the likelihood of an action potential.

A) interfere with neurotransmitter synthesis
B) alter the rate of neurotransmitter release
C) prevent neurotransmitter inactivation
D) prevent neurotransmitter binding to receptors
E) change the type of neurotransmitter found in the synaptic vesicle

A) temporal summation.
B) spatial summation.
C) postsynaptic integration.
D) graded potentials.
E) EPSPs.

A) only Na⁺
B) only Cl^-
C) only K⁺
D) only Ca²⁺
E) Na⁺ and K⁺