Deck 7: Nerve Cells and Electrical Signaling

A)positive feedback.
B)inhibitory graded potentials.
C)electrotonic conduction.
D)negative feedback.
E)excitatory graded potentials.

A)flux
B)conductance
C)impedance
D)voltage
E)current

A)afferent neuron
B)interneuron
C)bipolar neuron
D)pseudo- unipolar neuron
E)efferent neuron

A)oligodendrocyte
B)Schwann cell
C)ependymal cell
D)astrocyte
E)microglia

A)Fick's equation
B)NAD equation
C)Nernst equation
D)GHK equation
E)None of the answers is correct.

A)hyperpolarization only
B)depolarization only
C)repolarization only
D)both hyperpolarization and depolarization
E)both hyperpolarization and repolarization

A)Na+/K+ pump
B)action potential
C)Na+/Ca2+ exchanger
D)Na+/H+ antiporter
E)equilibrium potential

A)sodium (Na+)
B)potassium (K+)
C)chloride (Cl- )
D)calcium (Ca++)
E)phosphate (PO4- )

A)during the after- hyperpolarization
B)at the resting membrane potential
C)during depolarization
D)during the relative refractory period
E)during the absolute refractory period

A)- 70 mV.
B)+100 mV.
C)- 5 mV.
D)- 55 mV.
E)+30 mV.

A)Potassium would reach its equilibrium potential and the voltage inside the cell would not change.
B)Potassium would leave the cell, causing the membrane to hyperpolarize.
C)Potassium would enter the cell, causing the membrane to depolarize and reach threshold.
D)Potassium is a cation; therefore, it would cause an excitatory depolarization.
E)Potassium is an inhibitory second messenger; therefore, it would cause amplification of the graded potential.

A)They have a refractory period.
B)The all- or- none principle explains this.
C)They have myelinated axons.
D)The diameter of the axon explains this.
E)Only sodium- and potassium- gated channels are found on the axon.

A)voltage- gated channels
B)ligand- gated channels
C)mechanical channels
D)propagation channels
E)initiation channels

A)sodium (Na+)
B)potassium (K+)
C)chloride (Cl- )
D)calcium (Ca++)
E)phosphate (PO4- )

A)electrotonic conduction
B)action potential
C)graded potential
D)refractory period
E)resistance

A)retrograde
B)pinocytosis
C)anterograde
D)receptor- mediated
E)passive

A)The cell body is located in the ventral horn of the spinal cord.
B)They transmit information from the CNS to the periphery.
C)They are the most abundant class of neurons.
D)They transmit information from the periphery to the CNS.
E)They are typically multipolar neurons.

A)nodes of Ranvier
B)underlying myelin sheath
C)oligodendrocyte
D)Schwann cell
E)cell body

A)opening of sodium channels.
B)closure of potassium channels.
C)opening of potassium channels.
D)opening of chloride channels.
E)closure of sodium channels.

A)depolarized.
B)repolarized.
C)hyperpolarized.
D)polarized.
E)polar.

A)The movement of sodium and potassium ions that occurs during an action potential is countered by the active transport of these ions by the Na+/K+ pump.
B)The movement of sodium and potassium ions that occurs during an action potential is countered by the passive movement of these ions during the repolarization phase.
C)The movement of sodium and potassium ions that occurs during an action potential is countered by the passive leak of these ions when a neuron is at rest.
D)The movement of sodium and potassium ions that occurs during an action potential is countered by the passive movement of these ions during the after- hyperpolarization.
E)The movement of sodium and potassium ions that occurs during an action potential is countered by counter- transport of potassium with sodium during rest.

A)graded potentials
B)threshold potentials
C)action potentials
D)both graded potentials and action potentials
E)neither graded potentials nor action potentials

A)due to the decremental properties of graded potentials
B)due to electrotonic conduction
C)due to the magnitude of action potentials
D)due to the frequency of action potentials
E)due to summation of several action potentials

A)nucleus
B)axon hillock
C)axon
D)cell body
E)dendrite

A)closure of potassium channels.
B)opening of calcium channels.
C)opening of sodium channels.
D)opening of sodium channels and closure of potassium channels.
E)closure of sodium channels and opening of potassium channels.

A)the size of the graded potential
B)the size of the stimulus
C)the strength of the electrochemical gradient for sodium and potassium ions relative to their permeability to these ions
D)the length of the refractory period
E)the concentration of sodium and potassium ions

A)polar
B)pseudo- unipolar
C)unipolar
D)multipolar
E)bipolar

A)nodes of Ranvier
B)nucleus
C)axon terminal
D)axon hillock
E)dendrites

A)once membrane potential reaches threshold, an action potential will be generated and that action potential will always be the same magnitude.
B)all of the action potentials will be generated from the axon hillock.
C)there is a positive feedback loop for sodium channels that results in a rapid membrane depolarization.
D)the positive feedback loop for the sodium channel is terminated by the inactivation gate.
E)following an action potential, the membrane will be repolarized by the opening of a potassium channel.

A)influx : hyperpolarizes
B)efflux : depolarizes
C)influx : repolarizes
D)efflux : hyperpolarizes
E)influx : depolarizes

A)temporal summation.
B)inhibitory summation.
C)voltage potential.
D)spatial summation.
E)excitatory summation.

A)Forces on both sodium and potassium ions are to move out of the cell.
B)The force on sodium ions is to move out of the cell, and the force on potassium ions is to move into the cell.
C)Forces on both sodium and potassium ions are to move into the cell.
D)The force on sodium ions is to move into the cell, and the force on potassium ions is to move out of the cell.
E)There is no force on either ion to move.

A)peripheral nervous system
B)efferent nervous system
C)afferent nervous system
D)somatic nervous system
E)central nervous system

A)suprathreshold
B)axon hillock
C)threshold
D)axon terminal
E)subthreshold

A)by making the cell membrane more permeable to potassium
B)by blocking voltage- gated potassium channels
C)by making the cell membrane more permeable to sodium
D)by blocking voltage- gated sodium channels
E)by binding to the enzyme sodiumase

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

A)Dendrites : synapses
B)Dendrites : cell bodies
C)Axon hillocks : axon terminals
D)Dendrites : axon terminals
E)Somas : synapses

A)graded potentials
B)threshold potentials
C)action potentials
D)both graded potentials and action potentials
E)neither graded potentials nor action potentials

A)efferent
B)afferent
C)interneurons
D)visceral
E)bipolar

A)axon
B)dendrite
C)soma
D)nucleus
E)cell body

A)ion channels within the membrane
B)the ions present on either side of the membrane
C)enzymes on the surface of the cell membrane
D)the resting membrane potential
E)receptors on the cell membrane

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

A)nodal conduction.
B)nodal propagation.
C)electrotonic conduction.
D)saltatory conduction.
E)propagation.

A)increased activity of the Na+/K+ pump.
B)sodium flow out of the cell.
C)sodium flow into the cell.
D)potassium flow into the cell.
E)potassium flow out of the cell.

A)diameter = 5 microns, myelinated
B)diameter = 1 micron, myelinated
C)diameter = 5 microns, unmyelinated
D)diameter = 20 microns, myelinated
E)diameter = 20 microns, unmyelinated

A)axon
B)axon hillock
C)dendrites
D)axon terminal
E)soma

A)sodium (Na+)
B)potassium (K+)
C)chloride (Cl- )
D)calcium (Ca++)
E)phosphate (PO4- )

A)somatic nervous system
B)autonomic nervous system
C)efferent nervous system
D)central nervous system
E)afferent nervous system

A)graded potentials
B)threshold potentials
C)action potentials
D)both graded potentials and action potentials
E)neither graded potentials nor action potentials

A)the absolute refractory period
B)the diameter of the axon
C)the relative refractory period
D)the concentration of sodium within the cytoplasm of the cell
E)whether the axon is myelinated or not

A)autonomic nervous system
B)afferent nervous system
C)central nervous system
D)somatic nervous system
E)enteric nervous system

A)suprathreshold
B)ligand
C)all- or- none principle
D)regenerative
E)refractory

A)30 percent
B)5 percent
C)10 percent
D)50 percent
E)20 percent

A)when an excitatory depolarization reaches threshold
B)when electrotonic conduction occurs within the soma of the neuron
C)when sodium enters the soma of a cell
D)when the axon hillock is repolarized
E)when the neuron is hyperpolarized

A)outward sodium current
B)outward potassium current
C)outward calcium current
D)inward potassium current
E)inward chloride current

A)voltage- gated channels
B)potential- gated channels
C)synaptic channels
D)ligand- gated channels
E)leak channels

A)sodium (Na+)
B)potassium (K+)
C)chloride (Cl- )
D)calcium (Ca++)
E)phosphate (PO4- )

A)resistance
B)capacitance
C)current
D)potential difference
E)transistor

A)The region just in front of the action potential is in the absolute refractory period.
B)The region just in front of the action potential is in the relative refractory period.
C)The region just behind the action potential is in the absolute refractory period.
D)They will travel the path of least resistance.
E)The region just behind the action potential is in the relative refractory period.

A)positive feedback.
B)electrotonic conduction.
C)negative feedback.
D)the all- or- none principle.
E)a refractory period.

A)afferent : efferent
B)sensory : somatic
C)sympathetic : parasympathetic
D)somatic : sensory
E)efferent : afferent

A)efferent
B)visceral
C)sensory
D)somatic
E)afferent

A)autonomic nervous system
B)somatic nervous system
C)enteric nervous system
D)afferent nervous system
E)central nervous system

A)spinothalmic tract
B)afferent nervous system
C)central nervous system
D)efferent nervous system
E)enteric nervous system

A)graded potentials
B)threshold potentials
C)action potentials
D)both graded potentials and action potentials
E)neither graded potentials nor action potentials

A)graded potentials
B)threshold potentials
C)action potentials
D)both graded potentials and action potentials
E)neither graded potentials nor action potentials

A)soma
B)dendrites
C)axon terminal
D)axon
E)axon hillock

A)increase leakage of ions across the membrane
B)decrease axonal conduction velocity
C)reduce a membrane's ion permeability
D)decrease ion permeability in the nodes of Ranvier
E)increase a membrane's ion permeability

A)potassium : out of
B)chloride : into
C)sodium : into
D)sodium : out of
E)potassium : into

A)the gating of potassium channels only.
B)the gating of sodium channels only.
C)that membrane's threshold potential.
D)the changes in ion concentration across the membrane.
E)the ion channels that are opened or closed.

A)graded potentials
B)threshold potentials
C)action potentials
D)both graded potentials and action potentials
E)neither graded potentials nor action potentials

A)commissures.
B)ganglia.
C)tracts.
D)nuclei.
E)pathways.

A)central nervous system
B)enteric nervous system
C)efferent nervous system
D)somatic nervous system
E)afferent nervous system

A)axon hillock : axon terminal
B)axon terminal : axon hillock
C)dendrite : axon hillock
D)axon hillock : dendrite
E)dendrite : axon terminal

A)closure of the sodium activation gate.
B)decreased sodium permeability.
C)decreased potassium permeability.
D)the number of sodium channels whose inactivation gate has not opened.
E)increased potassium permeability.

A)outward : positive
B)inward : positive
C)at equilibrium : positive
D)inward : negative
E)outward : negative

A)Schwann cells : oligodendrocytes
B)Schwann cells : astrocytes
C)Schwann cells : microglial cells
D)oligodendrocytes : Schwann cells

A)parasympathetic and sympathetic
B)somatic and motor
C)peripheral and central
D)afferent and efferent
E)somatic and enteric

A)somatic nervous system
B)afferent nervous system
C)enteric nervous system
D)central nervous system
E)efferent nervous system