Deck 7: The Nervous System and Neuronal Excitability

A) the cell bodies of the neurons
B) the nodes of Ranvier
C) unmyelinated axons
D) myelinated axons

A) oligodendrocytes
B) microglial cells
C) ependymal cells
D) Schwann cells

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

A) autonomic neurons
B) sensory neurons
C) somatic neurons
D) autonomic and somatic neurons

A) axon
B) dendrites
C) cell body (soma)
D) axon hillock

A) Recycling of old materials will decrease.
B) ATP production will slow.
C) There will be a decrease in the amount of synaptic vesicles available for release.
D) The neuron will no longer receive input from other neurons.

A) Oligodendrocytes
B) Ependymal cells
C) Astrocytes
D) Microglial cells

A) dynein
B) kinesin
C) microtubules
D) dynein and microtubules

A) the axon
B) the synaptic end bulbs
C) the dendrites
D) the cell body

A) cell body (soma) and efferent neurons
B) dendrites and afferent neurons
C) axons and interneurons
D) dendrites and efferent neurons

A) cell body (soma)
B) axon terminal
C) synaptic end bulb
D) axon hillock

A) sensory
B) sympathetic
C) parasympathetic
D) somatic

A) sensory function
B) integrative function
C) motor function
D) sensory and motor functions

A) sensory function
B) motor function
C) integrative function
D) none; all functions occur in reflexes

A) sensory neurons
B) sympathetic neurons
C) parasympathetic neurons
D) somatic neurons

A) The individual will no longer have voluntary control of the smooth muscle in his GI tract.
B) The nerve will change divisions and contain only somatic neurons.
C) Nothing, because the tissue of the GI tract responds only to the enteric nervous system, and the autonomic innervation was not vital.
D) This area of the GI tract will no longer be able to exchange information with the CNS through this nerve.

A) Unlike neuroglia, neurons are found in the central nervous system.
B) Unlike neuroglia, neurons have an axon.
C) In contrast to neuroglia, neurons are smaller and therefore more of them are found in the nervous system.
D) In contrast to neuroglia, neurons can multiply in the mature nervous system.

A) They pump charges only across the membrane, maintaining the electrical gradient.
B) They pump neutral elements (atoms) only across the membrane, maintaining the concentration gradient.
C) They pump ions across the membrane maintaining both electrical and concentration gradients.
D) They pump water across the membrane maintaining osmotic and concentration gradients.

A) a large V_m
B) a large number of closed ion channels
C) a large membrane resistance
D) a small difference in ion concentrations across the membrane

A) Neurons with short axons that relay information of minor importance.
B) Neurons with short axons that relay critical information.
C) Neurons with long axons that relay information of minor importance.
D) Neurons with long axons that relay critical information.

A) The Nernst calculates the resting membrane potential for a membrane, but GHK does not.
B) The Nernst calculates the equilibrium potential for anions, and the GHK for cations.
C) The Nernst calculates the equilibrium potential for a single ion and the GHK for the resting membrane potential.
D) The Nernst calculates the equilibrium potential for an ion with a single charge and the GHK for an ion with a charge of two or more.

A) they are found in roughly equal concentrations across the membrane
B) they are negatively charged, and the rmp relies on positive charges
C) they are bound to cations and thus can't cross the membrane
D) they do not have leak channels and thus can't cross the membrane

A) responding to a stimulus
B) generating an electrical signal
C) producing neurotransmitters
D) generating an action potential as a response to a stimulus

A) membrane potential
B) muscle action potential
C) nerve action potential
D) graded potential

A) astrocytes multiply rapidly, blocking potential regrowth of a neuron
B) there are plenty of other neurons to take the damaged neuron's place
C) inhibitory proteins produced by microglia stop and repair
D) Schwann cells fail to produce a regeneration tube

A) A higher concentration of Cl^- outside the cell will create a positive equilibrium potential.
B) A higher concentration of Cl^- inside the cell will create a positive equilibrium potential.
C) A higher concentration of Cl^- inside the cell will create a negative equilibrium potential.
D) It does not matter what the initial concentration is because Cl^- will always reach a negative equilibrium potential.

A) more K⁺ leak channels compared to Na⁺ channels
B) more K⁺ voltage-gated channels compared to Na⁺ channels
C) more K⁺ ligand-gated channels compared to Na⁺ channels
D) more K⁺ mechanically-channels compared to Na⁺ channels

A) concentration gradient
B) pressure gradient
C) osmotic gradient
D) thermal gradient

A) number of ions on each side of the membrane
B) number of open ion channel
C) charges of ions on each side of the membrane
D) All choices will affect the membrane's ability to separate charges.

A) the membrane is permeable to all substances
B) the membrane has channels that serve as conductors
C) the membrane has lipid components that serve as an insulator
D) the membrane is permeable to all substances because of its channels

A) concentration gradients
B) electrical gradients
C) pressure gradients
D) chemical and electrical gradients

A) plasticity only occurs in the CNS while regeneration only occurs in the PNS
B) new neurons are formed in plasticity, but not regeneration
C) plasticity and regeneration are both equally likely to occur
D) plasticity involves changes in synaptic strength or number while regeneration involves repair

A) ligand-gated
B) leak channels
C) mechanically-gated
D) voltage-gated

A) leak
B) gated
C) channel
D) ion

A) the suprathreshold will have the largest amplitude
B) threshold stimuli will not always produce an action potential
C) the suprathreshold stimulus will create a higher frequency of action potentials
D) there in no difference in action potentials generated by either type of stimulus

A) neuron
B) skeletal muscle cell
C) endocrine cell
D) All of these choices could be a postsynaptic cell.

A) Graded potentials can only travel a short distance by local current flow.
B) Graded potentials are caused by ligand and mechanically-gated channels that are most frequently found in dendrites and cell bodies.
C) Graded potentials are caused only by Na⁺ and K⁺ flowing through channels.
D) Graded potentials are both depolarizing and hyperpolarizing, which means they can't occur in axons where only depolarizing signals occur.

A) Ca²⁺ can block Na⁺ channels, so the extra concentration means fewer channels are available for Na⁺ to move through.
B) Ca²⁺ increases the voltage threshold required to open the Na⁺ channels, so the extra concentration means channels require more stimulus.
C) Ca²⁺ decreases the voltage threshold required to open the K⁺ channels, so the extra concentration means K⁺ channels will open sooner, hyperpolarizing the cell.
D) It makes the outside of the cell more positive, so by comparison the inside is more negative and therefore less likely to depolarize.

A) Ions move based on an electrochemical gradient. If the concentration of K⁺ outside the cell is greatly increased, then it would move in, depolarizing the cell.
B) When an ion crosses the membrane, it brings its charge with it. Because K⁺ is positively charged, it can only depolarize a cell (make it less negative.)
C) K⁺ basically doesn't move across the membrane unless it is actively transported, and potentials involve the movement of ions through channels.
D) Many types of ions (with their charges) are located inside and outside the cell. It is the concentrations of those other ions that determines whether a channel opening will lead to a depolarizing or hyperpolarizing potential.

A) axons with a larger diameter
B) axons that are myelinated
C) axons with more axon collaterals
D) axons with both myelin and a larger diameter

A) occurs in axons with myelin on them
B) occurs in dendrites
C) is slower than continuous conduction
D) utilizes more energy than continuous conduction

A) None, as action potentials rely on channels for Na⁺ and K⁺ to cross the membrane, not pumps.
B) It will make action potentials more likely to occur as the pump normally makes the cell more negative, so without it the membrane will reach threshold more easily.
C) It will not have an immediate effect, but eventually action potentials will stop as the Na⁺ and K⁺ gradients are depleted.
D) It will shorten the duration of the action potential as there will not be as many ions available to cross the membrane.

A) 1, 3, 6, 5, 4, 2
B) 3, 1, 6, 4, 5, 2
C) 5, 2, 1, 6, 4, 3
D) 6, 1, 3, 4, 5, 2

A) similar to the channels found on the dendrites
B) similar to the channels found on sensory receptors
C) similar to the channels found in the axon hillock
D) unique and unlike channels found anywhere else in the neuron

A) maximal frequency due to the absolute refractory period
B) travel one-direction (not go back where it came from)
C) inability to sum action potentials
D) All these characteristics are due to the inactivation gates.

A) The amplitude would be smaller, but the duration would be similar.
B) The amplitude would be similar, but the duration would be shorter.
C) The amplitude and duration would be similar, but fewer K⁺ channels would open.
D) The action potential would remain unchanged.

A) post-synaptic potential
B) receptor potential
C) end plate potential
D) resting membrane potential

A) will travel toward the cell body
B) will travel away from the cell body
C) will stay near the site where it was generated, as graded potentials can't travel far
D) will travel both toward and away from the cell body

A) chemical work
B) mechanical work
C) transport work
D) both chemical and transport work

A) Cl^- concentration higher outside a cell
B) Cl^- concentration higher inside a cell
C) Na⁺ concentration higher inside a cell
D) either Cl^- or Na⁺ concentrations higher inside a cell

A) The stimuli were given, but they did not reach threshold.
B) The stimuli were given too soon after a trial run and the membrane was still in a refractory period.
C) The stimuli caused a hyperpolarization, but graded potentials are only depolarizing.
D) Two stimuli, equal in amplitude, but opposite in polarity were given and when summed they cancelled each other out.

A) having depolarizing or hyperpolarizing potentials
B) typically being found in cell bodies or dendrites
C) being generated by ligand or mechanically-gated ion channels
D) All of the choices are characteristics of graded potentials.

A) Graded potentials only use Na⁺ and K⁺, while action potentials use other ions.
B) Action potentials are regenerated as they travel along the axon.
C) Refractory periods allow the channels to rest between action potentials so that they can travel a longer distance.
D) Myelin prevents all charges from leaking out of the axon.

A) distance the post-synaptic potential has traveled
B) the polarity of the potential (epsp or ipsp)
C) the timing of the potential (did they arrive close enough together to be summed)
D) All of the choices will affect the final amplitude.

A) increase the chances that the membrane will reach threshold
B) increase the chances that the membrane will return to its resting state
C) generate an action potential every time
D) cause dramatic changes in the postsynaptic neuron

A) ligand-gated ion channel
B) G-protein
C) K⁺ ion
D) secondary neurotransmitter

A) Yes, the effect on A would lead to a decrease in neurotransmitter release, thus decreasing the output to C.
B) Yes, the effect on A would lead to a increase in neurotransmitter release, thus increasing the output to C.
C) No, because A doesn't directly interact with C.
D) No, because hyperpolarizing potentials don't affect neurotransmitter release.

A) cardiac muscle
B) smooth muscle
C) skeletal muscle
D) glands

A) Presynaptic modulation affects the amount of neurotransmitter released onto the target.
B) Presynaptic modulation is a direct relationship between two neurons.
C) Presynaptic modulation always reflects facilitation of the synapse.
D) Presynaptic modulation always reflects inhibition of the synapse.

A) communication to occur in both directions
B) faster speed of communication
C) groups of cells to be linked together so that they seem to act as a unit
D) All of these options are possible because of gap junctions.

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

A) excitatory and inhibitory
B) small-molecule neurotransmitters and neuropeptides
C) solids and gases
D) hydrophilic and hydrophobic

A) The potentials must be equally divided between EPSPs and IPSPs.
B) The summation of the potentials must be at or above threshold.
C) The potentials must all arrive at different times.
D) The potentials must all travel great distances.

A) dendrite
B) cell body
C) axon
D) myelin

A) failure of the voltage-gated k⁺ channels to open, thus preventing repolarization
B) failure of the synaptotagmin to form channels for the neurotransmitter to cross the membrane
C) failure of voltage-gated ca²⁺ channels to open, preventing ca²⁺ from entering the cell
D) failure of kinesins to transport vesicles across the synaptic cleft

A) suddenly swerving to avoid hitting an object
B) maintaining hormone balances
C) modifiying intracellular proteins
D) removing Cl^- from a cell

A) they can only send signals in one direction
B) they are able to synchronize a group of cells
C) they are a slower way to send signals between cells
D) they provide a direct cytoplasmic connection between the two cells

A) it causes ion channels to open or close
B) it alters the strength of the post-synaptic cell response
C) it affects the synthesis of neurotransmitter in the presynaptic cell
D) it has long lasting effects

A) maintains the level of neurotransmitter release regardless of the amount of stimulus, thus strengthening the synapse
B) ensures that all axon collaterals stimulate their postsynaptic targets equally
C) allows the nervous tissue to selectively modulate input at synapses
D) allows the postsynaptic neuron to increase the number of receptors for the neurotransmitter

A) diffusion
B) enzymatic degradation
C) reuptake by the neuron
D) uptake by glial cells

A) The action potential triggers voltage-gated Na⁺ channels to open and the depolarization causes the vesicle walls to merge with the membrane.
B) The action potential causes a change in the proteins on the vesicle membranes such that the vesicle binds to the cell membrane and begins exocytosis.
C) The action potential triggers voltage-gated Ca²⁺ channels to open and the Ca²⁺ that flows in starts a cascade of protein reactions that allows exocytosis of the neurotransmitters.
D) The action potential causes K⁺ to leave during repolarization and the decrease in K⁺ concentration triggers vesicles to bind to the membrane, releasing their contents.

A) chemical; electrical
B) mechanical; chemical
C) electrical; chemical
D) mechanical; electrical

A) have rapid responses
B) have short-term responses
C) make use of second messenger systems
D) have both rapid and short-term responses