Deck 2: Structure and Function of Cells of the Nervous System

A) dendrite.
B) axon terminal.
C) presynaptic membrane.
D) soma.
E) glial membrane.

A) protein molecules.
B) vesicle remnants.
C) a double layer of lipid molecules.
D) cytoplasm.
E) a single layer of lipid molecules interfaced with a layer of protein molecules.

A) soma.
B) axon.
C) axon terminals.
D) dendrites.
E) mitochondria.

A) glial junction.
B) axon contact
C) synapse.
D) dendritic apposition.
E) neural gap.

A) mitochondria; extraction of energy
B) Golgi apparatus; extraction of energy
C) endoplasmic reticulum; breakdown of proteins
D) microtubules; transport of chemicals through the cell membrane
E) mitochondria; formation of vesicles

A) peripheral nervous
B) central nervous
C) enteric nervous
D) human nervous
E) local circuit

A) axon terminal; dendrite
B) dendrite; soma
C) soma; glial
D) glial; dendrite
E) dendrite; axon terminal

A) multipolar
B) apolar
C) sensory
D) bipolar
E) motor

A) All neurons are sensory neurons.
B) Motor neurons gather sensory information from the environment.
C) The number of neurons in the human nervous system is estimated at more than 100 billion.
D) The term "motor" refers to a mechanical engine.
E) Interneurons are found outside the brain and spinal cord.

A) detect the presence of hormones outside the cell.
B) form the membrane.
C) form channels to carry ions in and out of the cell.
D) transport molecules into the cell.
E) transport vesicles within the neuron.

A) Sensory
B) Motor
C) Inter-
D) Relay
E) Local

A) vesicles
B) ribosomes
C) genes
D) myeline.
E) the nucleolus

A) severe nausea.
B) inability to sleep.
C) muscle weakness.
D) distortions of memory.
E) difficulty in recognizing facial displays of emotion.

A) glial cell.
B) dendrite.
C) axon terminal.
D) dendritic apposition.
E) soma.

A) bipolar neurons
B) multipolar neurons
C) unipolar neurons
D) apolar neurons
E) motor neurons

A) extraspinal
B) central nervous
C) enteric nervous
D) human nervous
E) peripheral nervous

A) Sensory
B) Motor
C) Inter-
D) Relay inter-
E) Local inter-

A) nucleolus; production of cytoplasm
B) ribosomes; production of DNA
C) lipid bilayer; production of ribosomes
D) nucleolus; production of ribosomes
E) mRNA; production of cytoplasm

A) apolar
B) multipolar
C) glial fiber
D) bipolar
E) heteropolar

A) Schwann cell
B) phagocyte
C) dendrocyte
D) astrocyte
E) microglia

A) phagocyte
B) Schwann
C) microglia
D) astrocyte
E) microtubule

A) of their capacity to store glucose in the cytoplasm.
B) neurons receive lactate from astrocytes.
C) glial cells can transfer ATP into neurons.
D) brain blood vessels can convert glucose into lactate for neuron use.
E) glial cell mitochondria process fuel for the neuron.

A) axoplasmic transport; myelin sheath
B) facilitated diffusion; exterior of the cell membrane
C) facilitated diffusion; neurofilaments
D) protein synthesis; microtubules
E) axoplasmic transport; microtubules

A) the removal of neuronal debris.
B) the transfer of lactate from a glial cell to a neuron.
C) the wrapping of fatty material around an axon membrane.
D) structural support of a nerve cell.
E) the degradation of transmitter molecules within the synapse.

A) Schwann cells provide myelin for peripheral nerve cells.
B) Schwann cells are found within the brain.
C) A single Schwann cell wraps multiple segments around a peripheral nerve cell.
D) A single Schwann cells can myelinate up to 50 segments of axon membrane.
E) Schwann cells remove the cellular debris left by dead neurons in brain.

A) move vesicles from the soma to the axon terminal.
B) produce proteins.
C) degrade surplus cellular materials.
D) provide energy to the neuron.
E) transport vesicles within the neuron.

A) Protection of the outer surface of the brain.
B) Removal of physical debris from the brain.
C) Secretion of CSF in the brain.
D) Movement of vesicles along the axon.
E) The conduction of action potentials.

A) phagocytes
B) Schwann cells
C) dendrocytes
D) astrocytes
E) microtubules

A) astrocytes
B) microglia
C) Schwann cells
D) axon terminals
E) phagocytes

A) Dendrograde transport involves moving substances from the dendrites to the soma.
B) Retrograde transport involves moving substances from the soma to the axon terminals.
C) The kinesin molecule is involved in anterograde transport.
D) Retrograde transport is twice as fast as anterograde transport.
E) The dynein molecule is involved in anterograde transport.

A) mitochondria.
B) ribosomes.
C) lysosomes.
D) the cytoskeleton.
E) nucleoli.

A) The dynein molecule is involved in anterograde axoplasmic transport.
B) Retrograde axoplasmic transport involves moving substances from the soma to the axon terminals.
C) The kinesin molecule is involved in retrograde axoplasmic transport.
D) Retrograde transport is half as fast as anterograde axoplasmic transport.
E) Transport of materials occurs only in one direction.

A) mitochondria; production of fat-like molecules
B) mitochondria; formation of vesicles
C) endoplasmic reticulum; breakdown of proteins
D) microtubules; transport of molecules between the soma and the axon terminals
E) Golgi apparatus; extraction of energy for cell use

A) focal damage to a single brain region evident in a CT scan.
B) diverse neurological symptoms that appeared at different times.
C) the excess production of myelin in the nervous system.
D) the occurrence of small strokes that impair brain function.
E) an autoimmune disease that attacks the myelin found in the peripheral nervous system.

A) Schwann cells form barriers to axon regrowth.
B) Schwann cells form cylinders through which new axons can grow and reinnervate a target cell nerve cell.
C) Schwann cells generate a chemical signal that instructs nerve cells to die.
D) Astrocytes form cylinders through which new axons can grow and reinnervate a target cell nerve cell.
E) Oligodendroglia form barriers to axon regrowth.

A) Schwann
B) glial or neuroglial
C) Golgi
D) stem
E) microtubule

A) Neurons have a high metabolic rate.
B) The dendrites store nutrients and oxygen for the neuron.
C) Dead neurons are consumed by other neurons.
D) Neurons make up 29% of the volume of the brain.
E) Neurons can survive for hours without oxygen.

A) Humans have about 95,000,000 genes.
B) Much of the genome contains "junk" DNA.
C) Non-coding "junk" RNA sequences that do not produce protein has no known function.
D) The human genome has not been fully sequenced.
E) Nearly 10% of the genes of the human genome code for proteins.

A) oligodendrocytes.
B) microglia.
C) astrocytes.
D) neurocytes.
E) Schwann cells.

A) membrane
B) local
C) glial
D) action
E) axon

A) resting membrane
B) local
C) resting
D) action
E) axon

A) retrograde transport
B) diffusion
C) anterograde transport
D) electrostatic pressure
E) salinity

A) axon --> dendrite --> cell body --> axon terminals.
B) axon terminals --> cell body --> axon --> dendrite.
C) dendrite --> cell body --> axon --> terminal button.
D) cell body --> axon --> dendrite --> axon terminal.
E) dendrite --> axon terminal --> cell body --> axon.

A) action potential
B) local potential
C) downward shift of the threshold of excitation
D) upward shift of the membrane threshold
E) long-term change in the membrane potential

A) diffusion.
B) carrier-mediated transport.
C) refraction.
D) electrostatic pressure.
E) diffraction.

A) integration of sensory messages regarding the environment.
B) planning of feeding-related movements.
C) contraction of the squid mantle, which propels the squid away from danger.
D) coordination of general sensory-motor function.
E) contraction of the oral region to produce chewing movements.

A) microelectrode; inject potassium ions into the axon
B) voltmeter; stimulate the interior of the axon
C) microelectrode; compare the electric charge of the interior with that of the exterior
D) voltmeter; compare the electric charge of the interior with that of the exterior
E) microelectrode; dampen the electric charge within the axon

A) pain receptor that synapses onto an interneuron, which in turn activates a motor neuron in the spinal cord.
B) pain receptor that projects to the thalamus, which then projects to motor cortex and then back down to the spinal cord.
C) motor neuron within the spinal cord that is spontaneously active.
D) sensory neuron in the visual cortex that synapses onto a motor neuron in the spinal cord.
E) motor neuron that activates sensory fibers.

A) depolarization.
B) threshold potential.
C) action potential.
D) hyperpolarization.
E) excitatory local potential.

A) resting membrane potential
B) hyperpolarization event
C) threshold of excitation
D) rate level
E) refractory period

A) Transmitters
B) Solvents
C) Electrolytes
D) Cations
E) Anions

A) all cells of the body are stained by a dye injected into the bloodstream.
B) injection of dye into the bloodstream stains all cells but those of the brain and spinal cord.
C) the gut is stained by a dye injected into the brain ventricles.
D) injection of dye into the spinal cord stains the cells of the gut.
E) injection of dye into the gut stains the cells of the spinal cord.

A) nucleus accumbens; visual hallucinations
B) hippocampus; locomotion
C) hypothalamus; vomiting
D) area postrema; vomiting
E) hippocampus; vomiting

A) has the same ionic concentrations as the outside.
B) is at the same voltage potential as the outside.
C) has a higher sodium concentration than outside.
D) is negatively charged relative to the outside.
E) has a lower potassium concentration than outside.

A) depolarization.
B) resting potential.
C) action potential.
D) hyperpolarization.
E) inhibitory local potential.

A) The barrier is uniform, protecting all brain structures.
B) The barrier pumps glucose out of the brain into the bloodstream.
C) The barrier functions to regulate the chemical composition of the extracellular fluid surrounding the brain cells.
D) The barrier is formed by cells that line the capillaries of the brain.
E) The ventricles have a blood-brain barrier.

A) ion.
B) molecule.
C) electrolyte.
D) cation.
E) anion.

A) Transmitters
B) Solvents
C) Electrolytes
D) Cations
E) Anions

A) Ions
B) Solvents
C) Transmitters
D) Electrons
E) Solutes

A) involve activation of the sodium-potassium pump.
B) remain the same size at each point along the membrane.
C) are just smaller versions of the action potential.
D) decrease in size as they sweep along the membrane.
E) are not conducted along the membrane.

A) entry of a negative ion; hyperpolarization
B) entry of a positive ion; hyperpolarization
C) exit of a positive ion; depolarization
D) exit of a negative ion; hyperpolarization
E) inactivation of sodium-potassium transporters; depolarization

A) inactivation of potassium channels; diffusion.
B) electrostatic pressure; sodium-potassium pump activation.
C) sodium-potassium pump activation; diffusion.
D) ion channel inactivation; diffusion.
E) diffusion; electrostatic pressure.

A) extracellular sodium concentrations are kept low.
B) intracellular sodium concentrations are kept very high.
C) extracellular potassium concentrations are kept very high.
D) intracellular sodium concentrations are kept low.
E) very little energy is required to maintain ionic differences across the membrane.

A) saltatory conduction; faster conduction speeds in smaller neurons
B) open sodium channels; membrane depolarization
C) saltatory conduction; slower conduction speeds in smaller neurons
D) open potassium channels; membrane repolarization
E) sodium-potassium pump; restoration of the normal concentrations of these ions

A) Myelin changes the height of the action potential.
B) Myelin increases the energy requirements of the nerve cell.
C) Myelin slows down conduction speed.
D) Myelin reduces the threshold for induction of an action potential.
E) Myelin speeds up axon conduction speed.

A) repolarization rate
B) resting membrane potential
C) speed of conduction of action potentials
D) total amplitude of the action potential
E) firing rate

A) subthreshold signals degrade with distance from the point of stimulation.
B) a high rate of firing produces a stronger response in muscle.
C) subthreshold signals grow in size with distance.
D) subthreshold signals remain constant in size along the axon membrane.
E) subthreshold signals grow in size as time passes.

A) The action potential will diminish to near 0 mV when transmitted down a long axon.
B) The action potential fires at the same rate regardless of the inputs to the neuron.
C) The action potential is conducted more rapidly down the axon as it reaches the axon terminal.
D) The action potential is produced whenever the membrane potential reaches threshold.
E) The action potential travels only in one direction.

A) vesicle
B) neurite
C) cisternae
D) mitochondria
E) storage pool

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

A) the opening of sodium channels.
B) the opening of voltage-gated channels.
C) kinesin.
D) electrostatic pressure.
E) the sodium-potassium transporter.

A) More sodium channels are opened at a lower voltage level than are the potassium channels.
B) The action potential requires 10 msec for completion.
C) The action potential requires the activity of the sodium-potassium transporters during the rising phase.
D) More potassium channels are opened at a lower voltage than are sodium channels.
E) The overshoot is due to a prolonged change in sodium conductance.

A) Sodium ions move into the cell.
B) Potassium ions move out of the cell.
C) Potassium ions move into the cell.
D) Chloride ions move into the cell.
E) Protein anions move out of the cell.

A) receptors.
B) voltage transporters.
C) autoreceptors.
D) ion channels.
E) sodium-potassium transporters.

A) Chloride ions are more concentrated inside the axon membrane.
B) Potassium ions are more concentrated outside the cell membrane.
C) The action potential is the balance point between diffusion and electrostatic pressure.
D) Sodium ions are more concentrated outside the axon membrane.
E) Sodium ions are more concentrated inside the axon membrane.

A) More sodium ions have to be pumped out of the cell after an action potential.
B) Myelin allows the nerve cell to recycle neurotransmitter molecules.
C) Less transmitter is required to send a message across the next synapse.
D) Myelin speeds up the velocity at which an axon can conduct an action potential.
E) Myelin requires that nerve cell axons be larger in order to conduct a signal rapidly.

A) the terminal buttons.
B) the soma.
C) the nodes of Ranvier.
D) the segment of membrane under the Schwann cell wrapping.
E) every point along the axonal membrane.

A) cable properties carry the signal under the myelin sheath.
B) myelinated cells have more leakage through the membrane.
C) myelinated axons are larger in diameter.
D) myelinated cells have more ion channels per unit area than do non-myelinated cells.
E) myelinated fibers have a lower threshold of activation.

A) The AP is conducted along the dendrite.
B) The AP is conducted faster in unmyelinated nerve cells
C) The AP is an all-or-none electrical event
D) The AP amplitude is higher for an intense signal.
E) The AP amplitude depends on its location along the axon.