Deck 19: Autonomic Nervous System

A) skeletal muscle fibers.
B) other neurons in the brain.
C) the body's organs and tissues.
D) the body's sensory receptors.
E) the motor cortex.

A) sympathetic
B) parasympathetic
C) cholinergic
D) limbic
E) autonomic ganglionic

A) symptoms such as reduced blood pressure, increased gut motility, and pupillary constriction.
B) symptoms such as increased blood pressure, reduced gut motility, and pupillary dilation.
C) a disruption of circadian rhythms.
D) increased appetite and/or overeating.
E) loss of muscular coordination.

A) has a more general, widespread effect on the body.
B) has more focused, selective effects.
C) is more directly under voluntary control.
D) is less directly under voluntary control.
E) tends to be associated with emotions.

A) mainly convergent, with many preganglionic fibers innervating each ganglionic neuron.
B) mainly divergent, with each preganglionic fiber innervating many ganglionic neurons.
C) both convergent and divergent.
D) direct, with each preganglionic fiber innervating a single ganglionic neuron.
E) unknown, since the fibers are too entangled to map their connections.

A) myelinated; unmyelinated
B) unmyelinated; myelinated
C) long; short
D) short; long
E) unipolar; multipolar

A) close to the tissues or organs that they innervate.
B) inside the spinal cord.
C) close to the muscles that they control.
D) in the brainstem.
E) next to the spinal cord.

A) present in the sympathetic nervous system, with parasympathetic neurons being unmyelinated.
B) absent, with most neurons being unmyelinated.
C) present on preganglionic neurons, with postganglionic neurons being unmyelinated.
D) present on postganglionic neurons, with preganglionic neurons being unmyelinated.
E) present on both preganglionic and postganglionic neurons

A) the autonomic ganglia use nicotinic receptors while the neuromuscular junction uses muscarinic receptors.
B) the autonomic ganglion cells are activated by acetylcholine, while the neuromuscular junction uses glutamate.
C) unlike the neuromuscular junction, the autonomic ganglion cells are inhibited by presynaptic activity.
D) the autonomic ganglion cells are activated by epinephrine instead of acetylcholine.
E) the structure of nicotinic receptors in autonomic ganglion cells differs from those at the neuromuscular junction.

A) an action potential in any presynaptic neuron is capable of producing an action potential in the ganglion cell.
B) some "strong" presynaptic neurons can produce action potentials in the ganglion cell, while other "weak" neurons produce subthreshold potentials.
C) all presynaptic neurons produce subthreshold potentials that must summate to produce an action potential.
D) an action potential in any presynaptic neuron is capable of inhibiting any action potentials in the ganglion cell.
E) only g-protein coupled receptors are present on the ganglion cell, so presynaptic firing does not produce any direct changes in postsynaptic potential.

A) are not present in autonomic ganglion cells.
B) produce fast, direct activation of autonomic ganglion cells.
C) produce slow, long lasting activation of autonomic ganglion cells.
D) produce inhibition of autonomic ganglion cells.
E) are present in autonomic ganglion cells, but their function has not yet been determined.

A) are not present in autonomic ganglion cells.
B) produce fast, direct activation of autonomic ganglion cells.
C) produce slow, long lasting activation of autonomic ganglion cells.
D) produce inhibition of autonomic ganglion cells.
E) are present in autonomic ganglion cells, but their function has not yet been determined.

A) neuropeptide Y and glutamate.
B) norepinephrine and gonadotropin-releasing hormone.
C) acetylcholine and nicotine.
D) glutamate and epinephrine.
E) acetylcholine and luteinizing hormone releasing hormone.

A) epinephrine; nicotinic
B) norepinephrine, adrenergic
C) purines; P
D) acetylcholine, nicotinic
E) acetylcholine; muscarinic

A) fast, direct excitatory potential in post-ganglionic autonomic neurons.
B) slow, long-lasting depolarization in post-ganglionic autonomic neurons.
C) fast, direct inhibitory potential in post-ganglionic autonomic neurons.
D) slow, long-lasting hyperpolarization in post-ganglionic autonomic neurons.
E) initiation of long-term potentiation in post-ganglionic autonomic neurons.

A) magnesium.
B) sodium.
C) chloride.
D) calcium.
E) potassium.

A) open, allowing an influx of potassium.
B) open, allowing an influx of sodium.
C) open, allowing an efflux of potassium.
D) close, reducing the efflux of potassium.
E) close, reducing the influx of sodium.

A) depolarizing the cell.
B) hyperpolarizing the cell.
C) maintaining the cell's resting potential.
D) ending the activity of cyclic AMP.
E) None of the above

A) increasing the probability of an action potential.
B) decreasing the probability of an action potential.
C) lowering the resting potential of the cell.
D) increasing the magnitude of action potentials.
E) activation of cyclic AMP.

A) M-channels are closed.
B) M-channels are opened.
C) Nicotinic ACh receptors are opened.
D) Nicotinic ACh receptors are closed.
E) C-cells are activated.

A) Shift from tonic firing to phasic firing
B) Shift from phasic firing to tonic firing
C) Suppress all firing activity
D) No effect on firing activity
E) Induction of long-term potentiation

A) closed, reducing potassium conductance.
B) closed, reducing chloride conductance.
C) closed, reducing sodium conductance.
D) open, contributing to resting sodium conductance.
E) open, contributing to resting potassium conductance.

A) acetylcholine and adenosine.
B) VIP and LHRH.
C) epinephrine and norepinephrine.
D) adenosine and ATP.
E) ATP and adrenaline.

A) sympathetic nervous system.
B) parasympathetic nervous system.
C) neuromuscular junction.
D) M-channel synapses.
E) adrenal medulla.

A) prevalent in the parasympathetic nervous system.
B) activated by purines.
C) activated by polypeptides.
D) responsive to pain.
E) located in the pituitary.

A) the inability to sleep.
B) high blood pressure.
C) overeating.
D) depression.
E) lethargy.

A) stretch receptors in the carotid artery.
B) oxygen receptors in the brain.
C) activated by polypeptides.
D) responsive to pain.
E) only found in the peripheral nervous system.

A) activates the hypothalamus; inhibits the hypothalamus
B) stimulates GnRH; stimulates LHRH
C) inhibits melatonin; stimulates melatonin
D) increases leptin; decreases leptin
E) releases GABA; releases norepinephrine

A) is a useful model system because it is very simple with only a few neurons.
B) consists almost entirely of sensory neurons.
C) consists almost entirely of motor neurons.
D) contains all known neurotransmitters.
E) is fully understood in the lobster but not yet in humans.

A) scientists have only recently begun to study its function.
B) the human enteric nervous system does not resemble that of any other species.
C) it contains an extremely large number of densely interconnected neural circuits.
D) electrical recordings cannot be used on these neurons.
E) it uses a different set of neurotransmitters than those found elsewhere.

A) hippocampus.
B) hypothalamus.
C) amygdala.
D) cerebellum.
E) limbic system.

A) body temperature, appetite, heart rate, and growth.
B) coordination of complex skeletal motor activity.
C) emotions and empathy.
D) language comprehension and production.
E) fear and aggression.

A) the principle neurotransmitter of the enteric nervous system.
B) a hormone released by the pituitary gland.
C) a protein involved in the regulation of blood pressure.
D) a peptide secreted by adipose cells.
E) a hormone released by hypothalamic neurons.

A) An increase in food intake
B) A reduction in food intake
C) A reduction in energy expenditure
D) Loss of rhythmicity of circadian cycles
E) No effect since the hypothalamus is not responsive to leptin

A) both hormone release and direct innervation by the hypothalamus.
B) release of melatonin by the hypothalamus.
C) purinergic transmission.
D) a sympathetic ganglion.
E) M-currents.

A) Ach into the pituitary.
B) NE into the bloodstream.
C) melatonin into the SCN.
D) GnRH into the pituitary.
E) NE into the sympathetic ganglia.

A) hypothalamus to act on the pituitary.
B) pituitary to act on the adrenal glands.
C) gonads to act on the hypothalamus.
D) hypothalamus to act on the gonads.
E) pituitary to act at locations all over the body.

A) pineal gland.
B) pituitary gland.
C) hypothalamus.
D) limbic system.
E) optic nerve.

A) induce sleep.
B) inhibit sleep.
C) regulate the sleep/wake cycle.
D) activate sympathetic activity.
E) coordinate reproductive behaviors.

A) periaqueductal grey.
B) photo-optic ganglion.
C) hypothalamus.
D) pineal gland.
E) suprachiasmatic nucleus.

A) specialized photoreceptive ganglion cells in the visual system.
B) rods in the retina.
C) pineal gland.
D) lateral geniculate nucleus.
E) paraventricular nucleus.

A) hyperarousal and high activity levels.
B) loss of circadian rhythms.
C) Increased appetite and weight gain.
D) difficulty regulating heart rate and blood pressure.
E) reduction in sexual activity.

A) maintaining circadian rhythms.
B) maintaining blood pressure.
C) regulating body weight.
D) opening M-channels.
E) hypothalamic regulation.

A) circadian rhythms are abolished.
B) circadian rhythm cycles become longer.
C) circadian rhythm cycles become shorter.
D) animals behave as though they are constantly in the "night," or dark, cycle.
E) circadian rhythms can still be entrained.

A) norepinephrine.
B) acetylcholine.
C) GABA.
D) ATP.
E) glutamate.

A) open chloride channels.
B) close chloride channels.
C) open sodium channels.
D) open potassium channels.
E) close potassium channels.