Deck 4: Multiple Choice

A) dog.
B) rabbit.
C) human.
D) a dog and a rabbit.

A) insert two electrodes into the axon and measure the voltage difference.
B) place one electrode on the outer surface of an axon's membrane and another inside the axon and measure the voltage difference.
C) place two electrodes on the outer surface of the axon's membrane and measure the voltage difference.
D) All of the answers are correct.

A) be made from glass.
B) be made from wire.
C) have a tip as small as 0.001 millimeter.
D) All of the answers are correct.

A) placing the tip of a microelectrode on an axon.
B) recording between two microelectrodes,one inside the axon and the other outside.
C) placing the tip of the microelectrode in an axon and applying some back suction.
D) placing the tips of two microelectrodes in an axon and recording between them.

A) a concentration gradient.
B) a voltage gradient.
C) diffusion.
D) All of the answers are correct.

A) Epilepsy
B) Parkinson disease
C) Multiple sclerosis
D) Stroke

A) a voltmeter.
B) a current meter.
C) an amp meter.
D) either a voltmeter or a current meter.

A) the difference in electrical potential between two poles.
B) current flow.
C) amps.
D) current flow and amps.

A) concentration gradient.
B) voltage gradient.
C) ionic translocation.
D) None of the answers is correct.

A) a concentration gradient.
B) a voltage gradient.
C) diffusion.
D) ionic translocation.

A) medication
B) deep brain stimulation
C) a high-fat,low-carbohydrate diet
D) All of the answers are correct.

A) hearing sounds.
B) movements.
C) seizures.
D) seeing patterns.

A) positive pole.
B) negative pole.
C) dipole.
D) ground pole.

A) the electroencephalogram.
B) the action potential.
C) the magnetoencephalogram.
D) axonal conductance.

A) Huntington disease.
B) Parkinson disease.
C) epilepsy.
D) myasthenia gravis.

A) the electroencephalogram.
B) the oscilloscope.
C) the microelectrode.
D) the oscilloscope and the microelectrode.

A) Luigi Galvani.
B) René Descartes.
C) Gustave Fritsch and Edward Hitzig.
D) David Ferrier.

A) neurons
B) phlegm
C) the pineal gland
D) cerebrospinal fluid

A) Young
B) von Helmholtz
C) Hodgkin and Huxley
D) Watson and Crick

A) depolarization.
B) hyperpolarization.
C) graded excitatory potential.
D) nothing,as these changes occur spontaneously.

A) blocks potassium channels.
B) blocks sodium channels.
C) blocks chlorine channels.
D) neutralizes large protein molecules.

A) continuously;intracellular Na+;extracellular K+.
B) continuously;intracellular K+;extracellular Na+.
C) continuously;extracellular Na+;intracellular K+.
D) intermittently;intracellular K+;extracellular Na+.

A) potassium ions
B) chloride ions
C) calcium ions
D) sodium ions

A) the role of potassium channels in hyperpolarization.
B) the role of sodium channels in depolarization.
C) the role of potassium channels in depolarization.
D) the role of sodium channels in hyperpolarization.

A) is -70 mV in all species.
B) can vary from -40 mV to -90 mV within a species.
C) can vary from -40 mV to -90 mV between species.
D) None of the answers is correct.

A) action potentials.
B) graded potentials.
C) ion fluctuations.
D) nerve impulses.

A) diffusion.
B) concentration.
C) charge.
D) electrostatic pressure.

A) depolarization.
B) hyperpolarization.
C) graded excitatory potential.
D) nothing,as these changes occur spontaneously.

A) potassium (K+);sodium (Na+)
B) sodium (Na+);potassium (K+)
C) potassium (K+);chloride (Cl-)
D) potassium (K+);anions (A-)

A) sodium ions.
B) potassium ions.
C) protein molecules.
D) lipids.

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

A) The cell membrane is semipermeable,so it keeps in large negatively charged protein molecules.
B) The membrane keeps out Na+ and allows K+ and Cl- to pass more freely.
C) The membrane has a sodium-potassium pump that removes potassium from inside the cell and replaces it with sodium.
D) The summed charges of the unequally distributed ions leave the inside of the membrane at -70 mV relative to the outside.This is the cell's resting potential.

A) manufactured by glial cells.
B) manufactured within a neuron.
C) transported to a neuron by glial cells.
D) not part of a neuron.

A) potassium ions.
B) sodium ions.
C) protein anions.
D) All of the answers are correct.

A) 20 times
B) 2 times
C) one-tenth
D) half

A) an excitatory postsynaptic potential.
B) repolarization.
C) an action potential.
D) hyperpolarization.

A) sodium;calcium
B) potassium;sodium
C) sodium;chloride
D) chloride;potassium

A) a large graded potential.
B) a large,brief reversal in the polarity of a membrane.
C) the same as a threshold potential.
D) seldom shorter than 10 milliseconds.

A) impermeable;no ions
B) impermeable;sodium
C) semipermeable;sodium (Na+)and calcium (Ca+)
D) semipermeable;potassium (K+)and chloride (Cl-)

A) neurotransmitter dependent.
B) voltage dependent.
C) calcium dependent.
D) both neurotransmitter and voltage dependent.

A) larger.
B) smaller.
C) of the same magnitude.
D) completely nullified.

A) It limits the firing rate of the neuron.
B) It forces nerve impulses to travel in one direction.
C) It increases the sensitivity of the neuron.
D) It allows time for the neuron to reset prior to another action potential.

A) an action potential crossing the synaptic cleft.
B) input at the dendrites of a cell.
C) the movement of an action potential along the axon.
D) an action potential along the combined axons,which are called nerves.

A) voltage-sensitive sodium and potassium channels.
B) voltage-sensitive chloride channels.
C) the time constraint on the sodium-potassium pump.
D) inhibitory postsynaptic potentials.

A) sodium-potassium pumps;terminal buttons
B) sodium and potassium channels;nodes of Ranvier
C) calcium channels;nodes of Ranvier
D) glial cells;nodes of Ranvier

A) 500
B) 1000
C) 100
D) 200

A) during the relative refractory period.
B) during the absolute refractory period.
C) during the intermediate refractory period.
D) None of the answers is correct.

A) the voltage of the cell membrane drops to zero and then returns to -70 mV.
B) the voltage of the cell membrane drops to zero,returns to about -100 mV,and then goes to 70 mV.
C) the voltage of the cell membrane goes to about +30 mV and then drops to -70 mV.
D) the voltage of the cell membrane goes to about +30 mV,drops to -100 mV,and then goes to -70 mV.

A) inflow of sodium;outflow of potassium
B) outflow of sodium;inflow of potassium
C) inflow of calcium;outflow of potassium
D) inflow of sodium;outflow of chloride

A) calcium;sodium
B) sodium;potassium
C) chloride;sodium
D) potassium;sodium

A) not decremental.
B) related to the opening of potassium and sodium ion channels.
C) similar to the effect of falling dominoes.
D) All of the answers are correct.

A) the absolute refractory period.
B) the nerve impulse.
C) the relative refractory period.
D) the resting membrane potential.

A) +50 mV.
B) +30 mV.
C) -50 mV.
D) 0 mV.

A) Ependymal cells;Schwann cells
B) Astroglia;oligodendroglia
C) Oligodendroglia;Schwann cells
D) Schwann cells,oligodendroglia

A) Calcium;potassium
B) Potassium;calcium
C) Sodium;potassium
D) All channels are equally sensitive.

A) -70 mV;resting potential
B) -50 mV;graded potential
C) -65 mV;threshold potential
D) -50 mV;threshold potential

A) the ions can flow only in one direction.
B) the refractory periods force the impulse to go in one direction.
C) the ion flow is attracted to chemicals in the synaptic knob.
D) autoreceptors inhibit backward flow of ions.

A) whenever the cell membrane starts to depolarize.
B) when the voltage across the membrane reaches zero.
C) when the threshold voltage of the cell is reached.
D) when the voltage across the membrane reaches +30 mV.

A) closing of calcium channels,stopping the influx of calcium.
B) opening of potassium channels,allowing the outflow of potassium.
C) closing of potassium channels,stopping the influx of potassium.
D) closing of sodium channels,stopping the outflow of sodium.

A) it increases the AP's conduction speed.
B) it reduces the need for sodium and potassium.
C) it conserves energy.
D) it both increases the AP's conduction speed and conserves energy.

A) myelin.
B) refractory periods.
C) the length of the axon.
D) calcium channels.

A) have maximum influence on an action potential.
B) are easier to summate both spatially and temporally than EPSPs elsewhere.
C) are less likely to have a dynamic effect than those close to the axon hillock.
D) do not modulate action potentials.

A) at the synaptic knob.
B) in the axon.
C) in the dendrites.
D) from the cell body.

A) an autoimmune disease.
B) related to vitamin D.
C) related to genetic risk factors.
D) All of the answers are correct.

A) the opening of potassium channels,allowing the outflow of potassium.
B) the opening of sodium channels,allowing the influx of sodium.
C) the closing of potassium channels,stopping the influx of potassium.
D) the closing of sodium channels,stopping the influx of potassium.

A) saltatory conduction.
B) an inhibitory postsynaptic potential (IPSP).
C) an excitatory postsynaptic potential (EPSP).
D) spatial summation.

A) axon hillock
B) dendrite
C) soma
D) ion channel

A) axon.
B) dendrites.
C) cell body.
D) initial segment (axon hillock).

A) 100
B) 50
C) 120
D) 30

A) initial segment (axon hillock)
B) cell body
C) dendrites
D) terminal buttons

A) spatial summation.
B) temporal summation.
C) both spatial and temporal summation.
D) neither spatial nor temporal summation.

A) when the two impulses are far apart on the membrane.
B) when the two impulses are close together on the membrane.
C) without regard to distance on the membrane.
D) when one EPSP follows the second by a short interval.

A) opening of sodium channels;opening of potassium channels
B) opening of sodium channels;closing of potassium channels
C) closing of sodium channels;opening of potassium channels
D) opening of calcium channels;closing of potassium channels

A) saltatory conduction.
B) an inhibitory postsynaptic potential (IPSP).
C) an excitatory postsynaptic potential (EPSP).
D) spatial summation.

A) the opening of potassium channels,allowing the outflow of potassium.
B) the opening of sodium channels,allowing the influx of sodium.
C) the closing of potassium channels,stopping the influx of potassium.
D) the closing of sodium channels,stopping the influx of potassium.

A) sodium concentration in the extracellular fluid.
B) action potentials that are facilitated by sodium.
C) action potentials jumping from one node to the next.
D) the leakage of the sodium channels that require the existence of a sodium-potassium pump.

A) spatial summation.
B) temporal summation.
C) both spatial and temporal summation.
D) neither spatial nor temporal summation.

A) she may have the flu.
B) she may have a brain tumor.
C) she may have multiple sclerosis.
D) she may have Huntington disease.

A) excess myelin on axons.
B) loss of myelin around axons.
C) excess excitatory input.
D) excess inhibitory input.