Deck 7: Audition, the Body Senses, and the Chemical Senses

A) outer ear.
B) inner ear.
C) organ of Corti.
D) pinna.
E) middle ear.

A) outer channel.
B) inner ear.
C) tectorial membrane.
D) tympanic membrane.
E) pinna.

A) cilia.
B) rods.
C) intrafusal fibers.
D) extrafusal fibers.
E) villi.

A) timbre
B) pitch
C) amplitude
D) saturation
E) loudness

A) high pitch.
B) low pitch.
C) loudness.
D) softness.
E) timbre.

A) 30; 700
B) 25; 4,000
C) 30; 20,000
D) 25; 9,000
E) 300; 45,000

A) Deiter's cells
B) Glial cells
C) Outer hair cells
D) Inner hair cells
E) Cilia cells

A) the amplitude of sound vibration.
B) the distance between the successive air vibrations.
C) the complexity of the sound waves.
D) its frequency of vibration.
E) the total duration of the sound stimulation.

A) 1:1.
B) 8:1.
C) 1:4.
D) 1:8.
E) 2:7.

A) outer ear.
B) inner ear.
C) organ of Corti.
D) pinna.
E) middle ear.

A) hair-cell cilia
B) the basilar membrane
C) the tympanic membrane
D) the tectorial membrane
E) Deiters's cells

A) compression of air molecules by an object.
B) changes in air pressure produced by the vibration of an object.
C) particles of energy that travel at better than 20 miles per hour.
D) packets of energy.
E) expansion of air molecules produced by an object as it moves through air.

A) outer membrane.
B) basilar membrane.
C) tectorial membrane.
D) tympanic membrane.
E) pinna.

A) hue.
B) pitch.
C) loudness.
D) saturation.
E) timbre.

A) vibration amplitude.
B) the distance between the sound source and the detector.
C) sound wave complexity.
D) frequency of vibration.
E) sound intensity.

A) movement of the stapes against the oval window.
B) contraction of the muscle fibers within the middle ear.
C) movement of the malleus against the round window.
D) movement of the stapes against the round window.
E) movement of the scala tympani.

A) receptive cells in the inner ear.
B) positioned within the pinna of the ear.
C) auditory receptors.
D) tiny bones located within the middle ear.
E) neurons that innervate the middle ear.

A) are tiny bones located within the outer ear.
B) are located within the inner ear.
C) provide a mechanical advantage for transferring sound energy to the inner ear.
D) are the formal names for the oval, round, and tympanic membranes, respectively.
E) comprise the pinna of the ear.

A) stapes, incus, malleus
B) malleus, incus, stapes
C) incus, malleus, stapes
D) pinna, malleus, stapes
E) malleus, stapes, incus

A) place coding
B) rate coding
C) phase coding
D) tonotopic codes
E) phase shifts

A) parietal cortex; location of sound
B) parietal cortex; perception of form
C) inferior temporal cortex; location of sound
D) inferior temporal cortex; perception of form
E) inferior temporal cortex; analysis of complex sounds

A) near the stapes.
B) at the apical end of the membrane.
C) farthest from the stapes.
D) farthest from the basal end of the membrane.
E) nearest the tympanic membrane.

A) Antibiotics can kill hair cells in a basal to apical direction and produce corresponding deficits in pitch perception.
B) Damage to the posterior temporal cortex impairs hearing.
C) Mutant mice that lack inner hair cells are unable to hear.
D) Overgrowth of bone over the round window impairs the hearing of high- but not low-pitched sounds.
E) Antibiotics can degenerate hair cells in an apical to basal direction and produce corresponding deficits in intensity perception.

A) Most afferent axons form connections with the outer hair cells.
B) Damage to the inner hair cells impairs hearing.
C) Outer hair cells play a more important role in hearing than do inner hair cells.
D) Thin unmyelinated axons form connections with inner hair cells.
E) Thick myelinated axons form connections with outer hair cells.

A) higher; closer to
B) higher; further from
C) lower; closer to
D) lower; further from
E) middle; closer to

A) posterior parabelt region of the anterior temporal region; sound localization
B) posterior occipital cortex; sound localization
C) parabelt region of the anterior temporal region; complex sound analysis
D) posterior parietal cortex; complex sound analysis
E) posterior parietal cortex; sound localization

A) acetylcholine; GABA
B) GABA; glycine
C) glutamate; dopamine
D) glutamate; acetylcholine
E) acetylcholine; dopamine

A) auditory lemniscus.
B) organ of Corti.
C) somatoacoustic nerve.
D) trigeminal nerve.
E) cochlear nerve.

A) electrically stimulating the 8th cranial nerve at > 500 pulses per second.
B) allowing pressure changes to occur within the cochlea.
C) opening a larger aperture within the round window.
D) electrically stimulating different regions of the basilar membrane.
E) changing the overall rate of firing of cochlear cells.

A) auditory nerve -> superior olivary nuclei -> medial geniculate -> superior colliculus -> auditory cortex
B) auditory nerve -> cochlear nuclei -> medial geniculate -> auditory cortex
C) auditory nerve -> cochlear nuclei -> superior olivary nuclei -> inferior colliculus -> medial geniculate -> auditory cortex
D) auditory nerve -> cochlear nuclei -> superior olivary nuclei -> medial geniculate -> auditory cortex
E) auditory nerve -> cochlear nuclei -> superior colliculus -> lateral geniculate -> auditory cortex

A) strands of actin.
B) the outer edges of the tectorial membrane.
C) tip links.
D) insertional plaques.
E) intrafusal fibers.

A) difficulty in locating the source of a sound.
B) total impairment of hearing.
C) the inability to detect differences in sound intensity.
D) the inability to detect differences between different musical instruments.
E) difficulty in recognizing the voice of another person.

A) open an ion channel.
B) reduce the amount of neurotransmitter released.
C) cause a hyperpolarization.
D) close an ion channel.
E) reduce the activity of the cell.

A) analysis of timbre.
B) analysis of sound intensity.
C) analysis of musical tunes.
D) complex sound analysis.
E) sound localization.

A) The neurons of this nerve are of the bipolar type.
B) The cell bodies of these neurons are located within the medulla.
C) The neurons of this nerve are of the multipolar type.
D) These nerve cells are hyperpolarized by release of transmitter from the hair cells.
E) These cells conduct local potentials, which can produce action potentials in downstream nerve cells.

A) linkage between the hair cells and the tectorial membrane.
B) mechanical linkage between the hair cells and the tympanic membrane.
C) movement of the round window.
D) movement of the hair cells through the tectorial membrane.
E) movement of fluid past the tips of the hair cells.

A) is a function of the voltage of the cilia membrane.
B) reflect the action of a second messenger within the cilia.
C) is controlled by ionotropic membrane receptors.
D) reflects tension exerted by the tip links on the insertional plaques.
E) involves the breakdown of cyclic AMP.

A) allow the entry of sodium ions into the hair cell.
B) open a channel to potassium in the insertional plaque.
C) allow the efflux of potassium ions out of the hair cell.
D) close a channel to potassium in the insertional plaque.
E) allow chloride ions to flow into the cilia.

A) frequencies; retinotopic
B) intensities; somatotopic
C) intensities; tonotopic
D) frequencies; tonotopic
E) timbres; tonotopic

A) sound location; sound loudness
B) object form; object location
C) complex sounds; perception of form
D) loudness; pitch
E) tone loudness; timbre

A) middle ear.
B) cochlea.
C) vestibular sacs.
D) semicircular canals.
E) pain reactivity system.

A) phase differences; intensity differences
B) intensity differences; phase differences
C) loudness differences; intensity differences
D) loudness differences; phase differences
E) phase differences; loudness differences

A) timbre; dorsal stream
B) identity; posterior stream
C) timbre; ventral stream
D) timbre; anterior stream
E) pitch; dorsal stream

A) cells within the 8th cranial nerve.
B) neural circuits within the superior olivary complex.
C) coincidence detectors within the medial geniculate thalamic nuclei.
D) circuits within the auditory cortex.
E) the inner hair cells.

A) sound identity; location of a sound
B) object form; object location
C) location of a sound; loudness
D) loudness; pitch
E) loudness; timbre

A) timing of musical rhythms; inferior frontal cortex
B) recognition of harmony; inferior frontal cortex
C) perception of underlying beat; left auditory cortex
D) perception of harmony; cerebellum
E) musical emotional tone; cerebellum

A) cochlear microphones
B) semicircular canals
C) organs of Corti
D) vestibular sacs
E) utricles

A) Vestibular sacs
B) Semicircular canals
C) The ampulla
D) The cupulla
E) Circular canals

A) inability to understand verbal and written instructions.
B) inability to perceive or produce music.
C) ability to recognize the emotional tone of a musical piece but not the melody.
D) apparently normal hearing.
E) inability to read sheet music.

A) attack phase.
B) decay phase.
C) overtone.
D) characteristic frequency.
E) fundamental frequency.

A) is a genetic trait.
B) involves the analysis of left-right phase arrival differences.
C) is a function of experience.
D) is better in blind than sighted people.
E) involves the analysis of right-left loudness differences.

A) geniculate nerve
B) auditory nerve
C) cochlear nerve
D) trochlear nerve
E) trigeminal nerve

A) induce deafness.
B) produce auditory hallucinations similar to those of schizophrenia.
C) impair the understanding of sound meaning but not impair hearing.
D) produce auditory-visual synesthesia.
E) alter the function of the vestibular system.

A) no definable sensation.
B) a low humming sound.
C) dizziness.
D) nystagmus.
E) nausea.

A) the fundamental overtones.
B) a sonic shadow that reflects differences in loudness.
C) differences in arrival times at the eardrums.
D) differences in sound phase.
E) differences in movement of the tympanic membrane.

A) lateral superior olivary complex.
B) medial geniculate.
C) parabelt region.
D) medial superior olivary complex.
E) organ of Corti.

A) rate of firing; the number of axons active at a time
B) the number of axons active at a time; rate of firing
C) rate of firing; rate of firing
D) the number of axons active at a time; the number of axons active at a time
E) perception; sensation

A) hair cells of the semicircular canals.
B) hair cells of the utricle.
C) hair cells of the saccule.
D) hair cells of the semicircular canals and the utricle.
E) hair cells of the semicircular canals, the utricle, and the saccule.

A) 0.1
B) 0.4
C) 2
D) 4
E) 8

A) impair sensing of extreme cold.
B) increase the emotional response to a painful stimulus.
C) alter reactivity to high-temperature stimuli.
D) alter reactivity to mechanical stimuli.
E) impair the detection of itch.

A) movements of the otoconia.
B) distortion of the tympanic membrane.
C) a traveling sine wave.
D) movements of the cupula.
E) movements of the basilar membrane.

A) cold probe applied to the face.
B) warm probe applied to the face.
C) tickle of her forehead.
D) slap of her cheek.
E) itch on her nose.

A) TRPV1 receptors
B) TRPV1 receptors
C) Merkel's disks
D) Pacinian corpuscles
E) High-threshold mechanoreceptors

A) pain.
B) cold.
C) heat.
D) salt in a food.
E) the bitterness of a drink.

A) second
B) fifth
C) eighth
D) tenth
E) twelfth

A) Free nerve endings in the skin
B) Stretch receptors in cardiac muscle
C) Receptors located within the semicircular canals
D) Hair cells within the cochlea
E) Cilia within the otoconia

A) two
B) three
C) four
D) five
E) six

A) edge contours.
B) cold.
C) heat.
D) texture.
E) harmful stimulation.

A) smooth.
B) thin.
C) hairy.
D) thick.
E) rough.

A) Ruffini corpuscles
B) Free nerve endings
C) Meissner's corpuscles
D) Pacinian corpuscles
E) Dieter's cells

A) free nerve endings.
B) TRPA1 receptors.
C) Pacinian corpuscles.
D) Ruffini corpuscles.
E) ATP-sensitive free nerve endings.

A) the external surface of the skin.
B) the hair cells of the vestibular sacs.
C) receptors of the muscles.
D) receptors that line the surfaces of internal organs.
E) muscles of the gut.

A) traveling sine waves.
B) distortion of the tympanic membrane.
C) movements of the otoconia.
D) movements of the cupula.
E) movement of the basilar membrane.

A) vestibulo-ocular reflex
B) oculo-vestibular reflex
C) visual reflex
D) motion reflex
E) visuo-ocular relfex

A) Ruffini corpuscles
B) free nerve endings
C) Meissner's corpuscles
D) Pacinian corpuscles
E) Dieter's cells

A) hairy; soles of the feet
B) non-hairy; legs
C) hairy; top of the head
D) non-hairy; top of the head
E) non-hairy; palm of the hand

A) Ruffini corpuscles
B) Free nerve endings
C) Meissner's corpuscles
D) Pacinian corpuscles
E) Dieter's cells

A) free nerve endings with mechanoceptor properties.
B) TRPV1 receptors.
C) Pacinian corpuscles.
D) Ruffini corpuscles.
E) ATP-sensitive free nerve endings.

A) cardiac pressure.
B) blood flow to the muscles.
C) events that damage the skin.
D) brain temperature.
E) head movement.