Deck 11: Nervous Tissue

A)cell body.
B)dendrite.
C)axon hillock.
D)Nissl body.

A)sense the internal and external environments
B)integrate sensory information
C)coordinate voluntary and involuntary activities
D)direct long-term functions,such as growth
E)control peripheral effectors

A)why CNS neurons grow such long axons.
B)why CNS neurons cannot divide.
C)the ability of neurons to generate an action potential.
D)the ability of neurons to communicate with each other.
E)the ability of neurons to produce a resting potential.

A)telodendria.
B)knobs.
C)vesicles.
D)mitochondria.
E)neurosomes.

A)axons
B)telodendria
C)dendritic spines
D)synaptic terminals
E)axosomata

A)telodendria.
B)synaptic knobs.
C)collateral branches.
D)axon hillock.
E)synapse.

A)somatic
B)autonomic
C)sensory division of the peripheral
D)automatic
E)special sensory

A)brain.
B)spinal cord.
C)nerve.
D)glial cell.
E)neuron.

A)dendrites.
B)synaptic knobs.
C)collateral branches.
D)hillocks.
E)synapses.

A)sympathetic
B)parasympathetic
C)afferent
D)somatic
E)autonomic

A)autonomic
B)peripheral
C)central
D)efferent
E)afferent

A)neurotubules
B)mitochondria
C)vesicles
D)neurofibrils
E)Nissl bodies

A)neurofilaments
B)axon
C)dendrite
D)nucleus
E)neurofibrils

A)axon hillock.
B)axoplasm.
C)axolemma.
D)axon terminal.
E)axokaryon.

A)Proprioceptors
B)Interoceptors
C)Exteroceptors
D)Somatic sensory receptors
E)Special sense receptors

A)neurofilaments.
B)neurofibrils.
C)perikaryon.
D)Nissl bodies.
E)microglia.

A)telodendria.
B)knobs.
C)collateral branches.
D)dendrites.
E)synapses.

A)telodendria.
B)synaptic knob.
C)collateral branch.
D)hillock.
E)synapse.

A)anaxonic
B)bipolar
C)multipolar
D)pseudopolar
E)unipolar

A)astrocytes.
B)satellite cells.
C)oligodendrocytes.
D)microglia.
E)ependymal cells.

A)Endoceptors
B)Interoceptors
C)Exteroceptors
D)Special sensory receptors
E)Sensory ganglia

A)Multipolar
B)Anaxonic
C)Unipolar
D)Bipolar
E)Pseudopolar

A)astrocytes.
B)satellite cells.
C)oligodendrocytes.
D)microglia.
E)ependymal cells.

A)sight
B)joint movement
C)activities of the digestive system
D)cardiovascular activities
E)urinary activities

A)Proprioceptors
B)Interoceptors
C)Exteroceptors
D)Somatic sensory receptors
E)Special sensory receptors

A)multipolar
B)anaxonic
C)unipolar
D)bipolar
E)pseudopolar

A)maintaining the blood-brain barrier.
B)conducting action potentials.
C)absorbing excess neurotransmitter.
D)responding to neural tissue damage.
E)forming a three-dimensional framework for the CNS.

A)anaxonic.
B)unipolar.
C)bipolar.
D)tripolar.
E)multipolar.

A)Sensory neurons
B)Motor neurons
C)Unipolar neurons
D)Bipolar neurons
E)Interneurons

A)anaxonic.
B)unipolar.
C)bipolar.
D)tripolar.
E)multipolar.

A)anaxonic.
B)unipolar.
C)bipolar.
D)tripolar.
E)multipolar.

A)anaxonic.
B)bipolar.
C)multipolar.
D)pseudopolar.
E)unipolar.

A)Multipolar
B)Anaxonic
C)Unipolar
D)Bipolar
E)Pseudopolar

A)Proprioceptors
B)Interoceptors
C)Exteroceptors
D)Somatic sensory receptors
E)Interneurons

A)nerves.
B)ganglia.
C)the spinal cord.
D)peripheral nerves.
E)nuclei.

A)support
B)memory
C)secretion of cerebrospinal fluid
D)maintenance of blood-brain barrier
E)phagocytosis

A)anaxonic.
B)unipolar.
C)bipolar.
D)tripolar.
E)multipolar.

A)Multipolar
B)Anaxonic
C)Unipolar
D)Bipolar
E)Pseudopolar

A)anaxonic.
B)unipolar.
C)bipolar.
D)tripolar.
E)multipolar.

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

A)producing new axons.
B)regenerating cell bodies for the neurons.
C)forming a cellular cord that directs axonal regrowth.
D)clearing away cellular debris.
E)producing more satellite cells that fuse to form new axons.

A)astrocytes.
B)ependymocytes.
C)microglia.
D)oligodendrocytes.
E)tanycytes.

A)formation of myelin sheaths.
B)formation of cerebrospinal fluid.
C)formation of ganglia.
D)repair of axons.
E)transport of neurotransmitters within axons.

A)Axons
B)Dendrites
C)Neuroglia
D)Synapses
E)Efferent fibers

A)white
B)grey
C)clear
D)dark
E)yellow

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

A)astrocytes.
B)satellite cells.
C)oligodendrocytes.
D)microglia.
E)ependymal cells.

A)dendrites
B)dendrites and cell body
C)cell body and axon
D)axon and telodendria
E)dendrites and telodendria

A)Astrocytes
B)Satellite cells
C)Oligodendrocytes
D)Microglia
E)Ependymal cells

A)astrocytes.
B)ependymocytes.
C)microglia.
D)oligodendrocytes.
E)tanycytes.

A)kinetic
B)potential
C)concentration
D)gradient
E)graded

A)astrocytes.
B)satellite cells.
C)oligodendrocytes.
D)microglia.
E)ependymal cells.

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

A)oligodendrocytes form a continuous myelin sheath around the axons.
B)the astrocytes isolate the CNS by forming a blood-brain barrier.
C)the neurilemma is impermeable to most molecules.
D)ependymal cells restrict the flow of interstitial fluid between the capillaries and the neurons.
E)Schwann cells form a capsule around neurons.

A)gap junctions.
B)synapses.
C)myelinated.
D)nodes.
E)internodes.

A)neural
B)central
C)peripheral
D)Wallerian
E)conduction

A)white
B)grey
C)clear
D)dark
E)yellow

A)loss of the structural framework of the brain.
B)a breakdown of the blood-brain barrier.
C)inability to produce scar tissue at the site of an injury.
D)decreased production of cerebrospinal fluid.
E)reduced speed of nerve impulses.

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

A)They have both an activation gate and an inactivation gate that work independent of each other.
B)They open and close in response to changes in the membrane potential.
C)They are found on excitable membranes.
D)They have both an activation gate and an inactivation gate that work dependent of each other.
E)None of these is false.

A)through voltage-gated channels along the axolemma.
B)through passive or leak channels.
C)by ATP-dependent ion pumps like the sodium-potassium exchange pump.
D)through chemically-gated channels as in neuromuscular transmission.
E)diffusion directly through the plasma membrane.

A)leak-gated
B)voltage-gated
C)chemically gated
D)mechanically gated
E)ATP

A)is not involved in producing the resting membrane 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 opposite to the direction of their electrochemical gradients.
E)depends on a hydrogen gradient for energy.

A)intracellular concentration of potassium ions will increase.
B)neuron will slowly depolarize.
C)membrane will slowly lose its capacity to generate action potentials.
D)inside of the membrane will have a resting potential that is more positive than normal.
E)intracellular concentration of sodium ions will increase.

A)Voltage-gated
B)Chemically gated
C)Active
D)Mechanically gated
E)Leak

A)closed voltage-gated sodium channel.
B)chemically gated acetylcholine receptor.
C)sodium leak channel.
D)mechanically gated sodium channel.
E)inactivated voltage-gated sodium channel.

A)1 intracellular sodium ion for 2 extracellular potassium ions.
B)2 intracellular sodium ions for 1 extracellular potassium ion.
C)3 intracellular sodium ions for 1 extracellular potassium ion.
D)3 intracellular sodium ions for 2 extracellular potassium ions.
E)3 extracellular sodium ions for 2 intracellular potassium ions.

A)-90 mV.
B)-70 mV.
C)+66 mV.
D)0 mV.
E)-55 mV.

A)Chemical and electrical forces both favor sodium ions entering the cell.
B)Electrical forces push sodium ions out of the cell.
C)Chemical forces tend to drive potassium ions out of the cell.
D)Potassium ions are attracted to the negative charges inside the cell.
E)Potassium ions are repulsed by positive charges outside the cell.

A)active
B)gated
C)leak
D)regulated
E)local

A)Neurons would depolarize more rapidly.
B)Action potentials would lack a repolarization phase.
C)The absolute refractory period would be shorter than normal.
D)The axon would be unable to generate action potentials.
E)None,because the chemically gated sodium channels would still function.

A)Leak
B)Activated
C)Chemically gated
D)Voltage-gated
E)Mechanically-gated

A)the membrane potential will depolarize.
B)the membrane potential will hyperpolarize.
C)inward movement of sodium ions will increase.
D)outward movement of sodium ions will decrease.
E)both the inward movement of sodium ions will increase and the membrane potential will depolarize.

A)osmotic
B)chemiosmotic
C)concentration
D)potential
E)electrochemical

A)diffusion of potassium ions out of the cell
B)diffusion of sodium ions into the cell
C)Membrane permeability for sodium ions is greater than for potassium ions.
D)Membrane permeability for potassium ions is greater than for sodium ions.
E)The interior of the plasma membrane has an excess of negative charges.

A)at the motor end plate.
B)on the surface of dendrites.
C)in the membrane that covers axons.
D)on the soma of neurons.
E)along the perikaryon of neurons.

A)leak
B)active
C)chemically gated
D)voltage-gated
E)mechanically-gated

A)depolarize the membrane potential
B)hyperpolarize the membrane potential
C)increase the magnitude of the potassium equilibrium potential
D)repolarize the membrane potential
E)increase the magnitude of the sodium equilibrium potential

A)The inside of the membrane will become more positive.
B)The inside of the membrane will become more negative.
C)There will be almost no effect on transmembrane potential.
D)The membrane will become depolarized.
E)The outside of the membrane will become more positive.