Deck 4: Psychopharmacology

A) neurotransmitters.
B) neuromodulators.
C) neurohormones.
D) neuroenzymes.

A) neurotransmitters.
B) neuromodulators.
C) neurohormones.
D) neuroenzymes.

A) neurotransmitters.
B) neuromodulators.
C) neurohormones.
D) neuroenzymes.

A) neurotransmitter.
B) neuromodulator.
C) neurohormone.
D) enzyme.

A) cell body, axon terminal
B) axon terminal, cell body
C) axon terminal, axon terminal
D) cell body, cell body

A) no other types of neurotransmitters.
B) a second type of small-molecule neurotransmitter.
C) at least one type of neuropeptide neurotransmitter.
D) at least one other type of small-molecule neurotransmitter and multiple types of neuropeptides neurotransmitters.

A) acts on the precursors of ACh to produce the final form of the neurochemical.
B) breaks down ACh in the synaptic gap.
C) acts on ACh to produce choline.
D) acts on ChAT to produce ACh.

A) muscarine, a substance found in tobacco, and ACh.
B) muscarine, a substance found in Amanita mushrooms, and ACh.
C) muscarine, nicotine, and ACh.
D) ACh only.

A) preganglionic and postganglionic synapses of both the sympathetic and parasympathetic nervous systems.
B) preganglionic synapses of the sympathetic nervous system and both the preganglionic and postganglionic synapses of the parasympathetic nervous system.
C) preganglionic synapses of the parasympathetic nervous system and both the preganglionic and postganglionic synapses of the sympathetic nervous system.
D) postganglionic synapses of the sympathetic nervous system and the preganglionic synapses of the parasympathetic nervous system.

A) dopamine.
B) GABA.
C) ACh.
D) serotonin.

A) higher levels of calcium than the release of small-molecule neurochemicals.
B) lower levels of calcium than the release of small-molecule neurochemicals.
C) approximately equal levels of calcium as the release of small-molecule neurochemicals.
D) no calcium at all.

A) cannot be deactivated by enzymes, whereas small-molecule transmitters diffuse away or are deactivated by reuptake.
B) are deactivated by reuptake, whereas small-molecule transmitters diffuse away or are deactivated by enzymes.
C) can diffuse away from synapses, whereas small-molecule transmitters are deactivated by reuptake.
D) and small-molecule transmitters can be deactivated by diffusion, enzymes, or reuptake.

A) containing neuropeptides are used only once, whereas vesicles containing small molecule neurochemicals are recycled.
B) containing small molecule neurochemicals are used only once, whereas vesicles containing neuropeptides are recycles.
C) containing some small molecule neurochemicals are recycled, while vesicles containing other types of small molecules are not.
D) containing some neuropeptides are recycled, while vesicles containing other types of neuropeptides are not.

A) dopamine
B) GABA
C) ACh
D) serotonin

A) muscarine.
B) norepinephrine.
C) serotonin.
D) ACh.

A) Muscarinic and nicotinic receptors are found in both the central and peripheral nervous systems.
B) Muscarinic receptors are found in the CNS only, whereas nicotinic receptors are found in the peripheral nervous system only.
C) Nicotinic receptors are found in both the central and peripheral nervous systems, whereas muscarinic receptors are found in the CNS only.
D) Muscarinic receptors are found in both the central and peripheral nervous systems, whereas nicotinic receptors are found in the CNS only.

A) diffusion away from the synapse.
B) absorption by astrocytes.
C) reuptake.
D) enzymes.

A) Nicotinic receptors are ionotropic, whereas muscarinic receptors are metabotropic.
B) Nicotinic receptors are metabotropic, whereas muscarinic receptors are ionotropic.
C) Nicotinic and muscarinic receptors are both ionotropic.
D) Nicotinic and muscarinic receptors are both metabotropic.

A) choline
B) acetyl CoA
C) tryptophan
D) ChAT

A) The muscarine in the mushrooms interacted with dopaminergic receptors in Rob's peripheral nervous system.
B) The nicotine in the mushrooms interacted with cholinergic receptors in Rob's CNS.
C) The muscarine in the mushrooms interacted with cholinergic receptors in Rob's peripheral nervous system.
D) The muscarine in the mushrooms interacted with cholinergic receptors in Rob's CNS.

A) neurotransmitters.
B) neuromodulators.
C) neurohormones.
D) neuroenzymes.

A) Regulating mood and appetite
B) Processing olfaction
C) Learning and memory
D) Maintaining homeostasis

A) correct.
B) incorrect, as some neurons can release two small molecules in different locations.
C) partially correct, in that neuropeptides are never found in the same neuron as amines or amino acids.
D) partially correct, as neurons nearly always release more than a dozen neurotransmitters whenever stimulated.

A) acetyl coenzyme A (acetyl CoA), usually found in dietary fats, and choline, a substance formed by the actions of mitochondria within cells.
B) choline from dietary fats and acetyl CoA, both of which are acted on by choline acetyltransferase (ChAT) to produce ACh.
C) the amino acid tyrosine, synthesized from the phenylalanine found in foods.
D) tryptophan, an amino acid found in chocolate, milk, and poultry.

A) dopamine only.
B) dopamine and epinephrine.
C) dopamine and norepinephrine.
D) dopamine, epinephrine, and norepinephrine.

A) her peripheral nervous system only.
B) her central nervous system only.
C) both her peripheral and central nervous systems.
D) neither her peripheral nor central nervous systems, because she only smokes a couple of cigarettes with friends during weekend parties.

A) always fast ionotropic.
B) always slow metabotropic.
C) fast metabotropic in systems involved with reward but slow ionotropic in systems involved with movement.
D) slow and fast metabotropic in systems involved with movement but fast ionotropic in systems involved with reward.

A) glutamate
B) GABA
C) ACh
D) norepinephrine

A) ACh
B) norepinephrine
C) epinephrine
D) dopamine

A) serotonin.
B) dopamine.
C) norepinephrine.
D) epinephrine.

A) always ionotropic.
B) always metabotropic.
C) ionotropic in synapses using norepinephrine and metabotropic in synapses using epinephrine.
D) ionotropic in synapses using epinephrine and metabotropic in synapses using norepinephrine.

A) serotonin
B) dopamine
C) norepinephrine
D) epinephrine

A) dopamine.
B) norepinephrine.
C) epinephrine.
D) serotonin.

A) serotonin
B) epinephrine
C) dopamine
D) norepinephrine

A) serotonin.
B) epinephrine.
C) norepinephrine.
D) ACh.

A) epinephrine
B) norepinephrine
C) serotonin
D) dopamine

A) ACh
B) serotonin
C) dopamine
D) norepinephrine

A) norepinephrine
B) ACh
C) dopamine
D) GABA

A) dopamine
B) norepinephrine
C) epinephrine
D) serotonin

A) substantia nigra; occipital lobe
B) raphe nucleus; reticular activating system
C) locus coeruleus; pons
D) nucleus accumbens; cerebellum

A) ACh
B) indoleamines
C) histamines
D) catecholamines

A) dopamine and is important in movement.
B) dopamine and is important in the development of Parkinson's disease.
C) norepinephrine and is important in vigilance.
D) serotonin and is important in mood.

A) reuptake.
B) diffusion.
C) enzymes.
D) enzymes and reuptake.

A) dopamine
B) norepinephrine
C) epinephrine
D) serotonin

A) an N-methyl-D-aspartate (NMDA) glutamate receptor
B) a kainate glutamate receptor
C) a nicotinic dopamine receptor
D) a GABAA receptor

A) Glycine
B) GABA
C) Glutamate
D) Aspartate

A) glycine
B) GABA
C) glutamate
D) adenosine

A) NMDA
B) AMPA
C) kainate
D) muscarinic

A) serotonin.
B) epinephrine.
C) glutamate.
D) GABA.

A) GABA
B) glutamate
C) serotonin
D) dopamine

A) The rats will fall asleep.
B) The rats will be wakeful.
C) The rats will be more responsive to pain than usual.
D) The rats will not show any obvious changes in behavior.

A) chloride
B) sodium and chloride
C) calcium
D) sodium and calcium

A) serotonin.
B) dopamine.
C) norepinephrine.
D) epinephrine.

A) glutamate
B) GABA
C) dopamine
D) serotonin

A) Substance P
B) Endorphins
C) Oxytocin
D) Cholecystokinin (CCK)

A) satiety.
B) dreaming.
C) drowsiness.
D) alertness.

A) 200,000
B) 1 million
C) 200 million
D) 1 billion

A) are quite numerous.
B) are surprisingly few in number.
C) project to very limited parts of the brain.
D) do not have different receptor subtypes.

A) glutamate.
B) GABA.
C) serotonin.
D) ACh.

A) substance P.
B) CCK.
C) oxytocin.
D) vasopressin.

A) substantia nigra.
B) raphe nucleus.
C) locus coeruleus.
D) nucleus accumbens.

A) serotonin.
B) ACh.
C) GABA.
D) glutamate.

A) NMDA receptors allow calcium into a cell, and excess calcium can stimulate harmful levels of enzyme activity.
B) NMDA receptors block the movement of calcium into a cell, preventing the release of other neurochemicals.
C) it blocks receptors for other types of neurochemicals, preventing effective communication between cells.
D) its breakdown in the synaptic gap produces harmful free radicals.

A) sodium
B) magnesium
C) potassium
D) calcium