Deck 38: Nervous and Sensory Systems

A) ceases breathing while sleeping and remains underwater.
B) sleeps for only 30 minutes at a time, the maximum interval for which it can cease breathing.
C) fills its swim bladder with air to keep its blowhole above the surface of the water while it sleeps.
D) moves to shallow water to sleep, so it does not need to swim to keep its blowhole above the surface of the water.
E) alternates which half of its brain is asleep and which half is awake.

A) a complete gut.
B) bilateral symmetry.
C) radial symmetry.
D) a closed circulatory system.
E) excitable membranes.

A) pituitary gland.
B) hypothalamus.
C) cerebrum.
D) cerebellum.
E) thalamus.

A) motor and sensory systems.
B) sympathetic and parasympathetic systems.
C) presynaptic and postsynaptic membranes.
D) forebrain and hindbrain.
E) central nervous system and peripheral nervous system.

A) central nervous system.
B) peripheral nervous system.
C) autonomic nervous system.
D) parasympathetic nervous system.
E) sympathetic nervous system.

A) increased activity in all parts of the peripheral nervous system.
B) increased activity in the sympathetic division and decreased activity in the parasympathetic division.
C) decreased activity in the sympathetic division and increased activity in the parasympathetic division.
D) increased activity in the enteric nervous system.
E) reduced heart rate and blood pressure.

A) Hydra.
B) cnidarians.
C) Planaria.
D) sea stars.
E) invertebrate animals with radial symmetry.

A) develops as the neural tube differentiates.
B) develops from the midbrain.
C) is the brain region most like that of ancestral vertebrates.
D) gives rise to the cerebrum.
E) divides further into the metencephalon and myelencephalon.

A) chemosensory structures.
B) tactile structures.
C) olfactory structures.
D) highly sensitive photoreceptors.
E) gustatory structures.

A) sympathetic
B) somatic
C) central
D) visceral
E) parasympathetic

A) a filtrate of the blood.
B) a secretion of glial cells.
C) a secretion of interneurons.
D) cytosol secreted from ependymal cells.
E) secreted by the hypothalamus.

A) increased activity in the sympathetic, parasympathetic, and enteric nervous systems.
B) decreased activity in the sympathetic, parasympathetic, and enteric nervous systems.
C) decreased activity in the sympathetic nervous system, and increased activity in the parasympathetic and enteric nervous systems.
D) increased activity in the sympathetic nervous system, and decreased activity in the parasympathetic and enteric nervous systems.
E) increased activity in the sympathetic nervous system, decreased activity in the parasympathetic nervous system, and increased activity in the enteric nervous system.

A) central nervous system.
B) motor system.
C) autonomic nervous system.
D) parasympathetic nervous system.
E) sympathetic nervous system.

A) continue to have cycles of exactly 24 hours in duration.
B) continue to have cycles of approximately 24 hours in duration-some more rapid, some slower.
C) synchronize activity with whatever lighting cycle is imposed on them.
D) cease having any rhythms.
E) are independent of any genetic determinants.

A) resting and digesting.
B) release of epinephrine into the blood.
C) increased metabolic rate.
D) fight-or-flight responses.
E) intensive aerobic exercise.

A) the gray matter of the brain and the white matter of the spinal cord.
B) the white matter of the brain and the gray matter of the spinal cord.
C) the gray matter of the brain and the gray matter of the spinal cord.
D) the white matter in the brain and the white matter in the spinal cord.
E) all areas of the brain and spinal cord.

A) functioning in transport of nutrients and hormones through the brain.
B) a product of the filtration of blood in the brain.
C) formed from layers of connective tissue.
D) functioning to cushion the brain.
E) filling cavities in the brain called ventricles.

A) is formed by tight junctions.
B) is formed by oligodendrocytes.
C) tightly regulates the intracellular environment of the CNS.
D) uses chemical signals to communicate with the spinal cord.
E) provides support to the brain tissue.

A) sensory systems.
B) peripheral nervous system.
C) autonomic nervous system.
D) parasympathetic nervous system.
E) sympathetic nervous system.

A) cerebrum.
B) cerebellum.
C) thalamus.
D) hypothalamus.
E) medulla oblongata.

A) the temporal and frontal lobes.
B) the parietal lobe.
C) Broca's area.
D) Wernicke's area.
E) the occipital lobe.

A) degree of convolutions in the brain's surface.
B) evolution of the telencephalon.
C) sequence of developmental specialization.
D) chemicals involved in brain communications.
E) nature of the blood-brain barrier.

A) olfaction.
B) vision.
C) speech.
D) memory.
E) hearing.

A) pituitary gland.
B) hypothalamus.
C) cerebrum.
D) cerebellum.
E) spinal cord.

A) is active when speech is heard and comprehended.
B) is active during the generation of speech.
C) coordinates the response to olfactory sensation.
D) is active when you are reading silently.
E) is found on the left side of the brain.

A) brainstem.
B) medulla.
C) hypothalamus.
D) hippocampus.
E) cranial nerves.

A) frontal lobe-decision making
B) occipital lobe-control of skeletal muscles
C) temporal lobe-visual processing
D) cerebellum-language comprehension
E) occipital lobe-speech production

A) cerebrum.
B) cerebellum.
C) thalamus.
D) hypothalamus.
E) medulla oblongata.

A) cannot receive stimuli.
B) will not have a nervous system.
C) will not be able to interpret stimuli.
D) can be expected to lack myelinated neurons.

A) converts that neuron to an ependymal cell.
B) causes the neuron to migrate to another part of the brain.
C) converts that neuron to a glial cell.
D) leads to Alzheimer's disease.
E) results in the apoptosis of that neuron.

A) corpus callosum.
B) medulla oblongata.
C) thalamus.
D) pituitary.
E) cerebellum.

A) a more advanced cerebellum.
B) a cerebellum with several flat layers.
C) a pallium with neurons clustered into nuclei.
D) microvilli to increase the brain's surface area.

A) cerebrum.
B) cerebellum.
C) thalamus.
D) hypothalamus.
E) medulla oblongata.

A) forebrain and medulla oblongata
B) forebrain and cerebellum
C) midbrain and cerebrum
D) hindbrain and cerebellum
E) brainstem and anterior pituitary gland

A) cerebrum.
B) cerebellum.
C) thalamus.
D) hypothalamus.
E) medulla oblongata.

A) cerebrum.
B) cerebellum.
C) thalamus.
D) hypothalamus.
E) medulla oblongata.

A) thalamus.
B) cerebellum.
C) medulla oblongata.
D) corpus callosum.
E) cerebrum.

A) thalamus.
B) hypothalamus.
C) epithalamus.
D) amygdala.
E) Broca's area.

A) cerebrum.
B) cerebellum.
C) spinal cord.
D) midbrain.
E) medulla oblongata.

A) gustatory stimuli.
B) olfactory stimuli.
C) visual stimuli.
D) auditory stimuli.
E) stimuli related to the position of the head.

A) glucose.
B) sodium ions.
C) potassium ions.
D) hydrogen ions.
E) monosodium glutamate.

A) primary visual cortex.
B) thalamus.
C) optic chiasma.
D) sense of taste.
E) sense of touch.

A) loss of the ability to reason.
B) loss of all short-term memory.
C) greatly altered emotional responses.
D) loss of all long-term memory.
E) loss of his sense of balance.

A) 1 → 2 → 3 → 4
B) 1 → 4 → 2 → 3
C) 2 → 4 → 1 → 3
D) 3 → 1 → 2 → 4
E) 3 → 1 → 4 → 2

A) perception.
B) sensory transduction.
C) sensory adaptation.
D) habituation.
E) lateral inhibition.

A) neural projections from taste receptors reach different parts of the brain than the neural projections from olfactory receptors.
B) the single area of the cerebral cortex that receives smell and taste signals can distinguish tastes and smells by the pattern of action potentials received.
C) tastant molecules are airborne, whereas odorant molecules are dissolved in fluids.
D) distinguishing tastant molecules requires learning, whereas smell discrimination is an innate process.
E) odorants bind to receptor proteins, but none of the tastant stimuli will bind to receptors.

A) nasal cavity.
B) anterior pituitary gland.
C) posterior pituitary gland.
D) brain.
E) brainstem.

A) the receptor.
B) a G protein.
C) an enzyme-catalyzed reaction.
D) sensory adaptation.
E) triggering several receptors at once.

A) sugar water.
B) chocolate milk.
C) a savory and rich cheese.
D) acidic orange juice.
E) salt water.

A) sensory adaptation → stimulus reception → sensory transduction → sensory perception.
B) stimulus reception → sensory transduction → sensory perception → sensory adaptation.
C) sensory perception → stimulus reception → sensory transduction → sensory adaptation.
D) sensory perception → sensory transduction → stimulus reception → sensory adaptation.
E) stimulus reception → sensory perception → sensory adaptation → sensory transduction.

A) integration.
B) transmission.
C) transduction.
D) transcription.
E) amplification.

A) tectorial membrane.
B) tympanic membrane.
C) round-window membrane.
D) hair cell membrane.
E) basilar membrane.

A) thalamus.
B) hypothalamus.
C) hippocampus.
D) somatosensory cortex.
E) primary motor cortex.

A) cold temperature.
B) hot temperature.
C) tactile stimulus.
D) odor of pepper.
E) deep pressure.

A) sensory adaptation.
B) accommodation.
C) the increase of transduction.
D) reduced motor unit recruitment.
E) reduced receptor amplification.

A) cold temperature.
B) hot temperature.
C) tactile stimulus.
D) odor of pepper.
E) deep pressure.

A) move.
B) sense light.
C) hear.
D) orient with respect to gravity.
E) respond to touch.

A) mechanoreceptors used to detect orientation relative to gravity.
B) chemoreceptors used in selecting migration routes.
C) photoreceptors used in setting biological rhythms.
D) thermoreceptors used in prey detection.
E) chemoreceptors used in acid-base balance.

A) tectorial membrane.
B) tympanic membrane.
C) round-window membrane.
D) hair cell membrane.
E) basilar membrane.

A) A
B) B
C) C
D) D
E) E

A) A
B) B
C) C
D) D
E) E

A) cone cells can detect color, but rod cells cannot.
B) cone cells are more sensitive than rod cells to light.
C) cone cells, but not rod cells, have a visual pigment.
D) rod cells are most highly concentrated in the center of the retina.
E) rod cells require higher illumination for stimulation than do cone cells.

A) excellent hearing for detecting predators.
B) compound eyes with multiple ommatidia.
C) eyes with multiple fovea.
D) a camera-like eye with multiple fovea.
E) binocular vision.

A) depolarize due to the opening of sodium channels.
B) hyperpolarize due to the closing of sodium channels.
C) depolarize due to the opening of potassium channels.
D) hyperpolarize due to the closing of potassium channels.
E) fire one action potential for each photon received.

A) 3.
B) 4.
C) 5.
D) 6.
E) 7.

A) 1, 2, 3, and 4
B) 2, 3, and 4
C) 3 and 4
D) 4
E) 5

A) hair cells of the organ of Corti, which rests on the basilar membrane, coming in contact with the tectorial membrane.
B) hair cells of the organ of Corti, which rests on the tympanic membrane, coming in contact with the tectorial membrane.
C) hair cells of the organ of Corti, which rests on the tectorial membrane, coming in contact with the basilar membrane.
D) hair cells of the organ of Corti coming in contact with the tectorial membrane as a result of fluid waves in the cochlea causing vibrations in the round window.
E) hair cells on the tympanic membrane as a result of fluid waves in the cochlea causing vibrations in the round window.

A) A
B) B
C) C
D) D
E) E

A) the hair cells in the cochlea move more than their normal limits.
B) moving fluid in the semicircular canals encounters a stationary cupula.
C) rods and cones provide information that does not correspond with information received by cochlear hair cells.
D) the basilar membrane makes physical contact with the tectorial membrane.
E) the utricle is horizontal but the saccule is vertical.

A) A
B) B
C) C
D) D
E) E

A) 2, 3, and 4
B) 2, 5, and 7
C) 4
D) 5
E) 7 and 8

A) which part of the tympanic membrane is being vibrated by sound waves.
B) which part of the oval window produces waves in the cochlear fluid.
C) which region of the basilar membrane was set in motion.
D) whether or not the sound moves the incus, malleus, and stapes.
E) the listener having had training in music.

A) neuromast.
B) statocyst.
C) taste bud.
D) ommatidium.
E) olfactory bulb.

A) cochlea.
B) statoliths.
C) stapes.
D) pinnae.
E) antennae.

A) ganglion cells.
B) amacrine cells.
C) bipolar cells.
D) horizontal cells.
E) rods and cones.

A) fluid and cells that can undergo mechanosensory transduction.
B) air and cells that produce wax.
C) air and small bones that vibrate in response to sound waves.
D) fluid with stacks of chemosensory cells.
E) air and statocysts activated by movement.

A) 7.
B) 1.
C) 8.
D) 9.
E) 10.

A) fire action potentials that will increase its release of glutamate.
B) undergo a graded depolarization that will increase its release of glutamate.
C) undergo a graded hyperpolarization that will increase its release of glutamate.
D) undergo a graded depolarization that will decrease its release of glutamate.
E) undergo a graded hyperpolarization that will decrease its release of glutamate.

A) A
B) B
C) C
D) D
E) E