Deck 7: Hearing, Balance, Taste, and Smell

A) sound localization.
B) intensifying auditory stimuli.
C) adjusting the tension of the round window to incoming sounds.
D) protecting the auditory system from intense sounds.

A) inner
B) middle
C) external
D) pinna

A) Stapedius muscle
B) Pinna
C) Organ of Corti
D) Tympanic membrane

A) a framework of supporting cells.
B) hair cells.
C) the stapedius muscle.
D) the terminations of the auditory nerve fibers.

A) vestibular canal.
B) tympanic canal.
C) tectorial duct.
D) middle canal.

A) inner hair cells.
B) basilar membrane.
C) auditory nerve fibers.
D) tectorial membrane.

A) Tensor tympani
B) Stapedius muscle
C) Stapes
D) Hair cells

A) hair cells; mechanical motion
B) air; wind
C) fluid; waves
D) ampullae; waves

A) Na⁺
B) K⁺
C) Cl^-
D) Ca²⁺

A) to the inner
B) to the outer
C) from the inner
D) from the outer

A) IHC afferents, which convey messages from the hair cells to the brain, give rise to the perception of sound.
B) OHC afferents, which convey messages from the hair cells to the brain, convey information to the brain about the perception of sounds coming specifically from the basilar membrane.
C) IHC efferents, which lead from the brain to the hair cells, provide a way for the brain to control afferent responsiveness.
D) OHC efferents, which lead from the brain to the OHCs, transmit commands to the OHCs to change their length, thereby controlling the stiffness of regions of the basilar membrane.

A) rectifier.
B) attenuator.
C) tuner.
D) bandpass filter.

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

A) facial
B) trochlear
C) accessory
D) vestibulocochlear

A) acetylcholine.
B) glutamate.
C) GABA.
D) aspartate.

A) 10
B) 25
C) 65
D) 95

A) superior colliculi
B) inferior colliculi
C) superior olivary nuclei
D) medial geniculate nuclei

A) the primary auditory area.
B) portions of the thalamus.
C) portions of the cerebellum.
D) All the above

A) the same brain regions.
B) more extensive brain regions.
C) smaller brain regions.
D) only the left hemisphere.

A) amplitude; harmonics
B) fundamental; pure tones
C) fundamental; harmonics
D) pure tone; timbre

A) quieter.
B) louder.
C) more complex.
D) purer.

A) topographic
B) tonotopic
C) tomographic
D) tonic

A) 80
B) 100
C) 120
D) 140

A) 20-20,000
B) 100-100,000
C) 200-250,000
D) 1,000-50,000

A) ultrasound.
B) infrasound.
C) harmonic sound.
D) timbre.

A) signal to her brain a change in pitch through place coding.
B) increase the activation of receptors near the apex of the cochlea.
C) signal to her brain a change in pitch through temporal coding.
D) All the above

A) place coding.
B) binaural processing.
C) temporal coding.
D) pitch processing.

A) her left ear hears exactly twice as well as her right ear.
B) her right ear will be cast in a sound shadow.
C) she experiences no onset disparity.
D) she must turn away from the sound to allow for spectral filtering.

A) determine if a sound is biologically relevant.
B) amplify sounds.
C) dampen sounds.
D) localize sounds.

A) It is specialized to detect simple and pure tones.
B) It is specialized to detect sounds containing many frequencies and complex patterns.
C) It is specialized to detect low-frequency sounds.
D) It is specialized to detect high-frequency sounds.

A) thalamic
B) olivary
C) auditory
D) amusic

A) Heschl's gyrus will be close to twice as large as that of nontrained infants by adulthood.
B) The brain will become extra sensitive to musical notes.
C) The brain will become more sensitive to infrasound.
D) Heschl's gyrus will be twice as strongly activated by musical notes as compared to nontrained individuals by adulthood.

A) interpret jokes.
B) discern tunes accurately.
C) sing and dance at the same time.
D) play a musical instrument.

A) have a strong ability to discriminate pitch.
B) have no ability to discriminate pitch.
C) have amusia.
D) are sensitive to loud noises.

A) Hearing loss can develop during life, while deafness is always a congenital condition.
B) Hearing loss is not considered a hearing disorder, while deafness is.
C) Deafness can be brought about by an accident or other event, while hearing loss is a slow process.
D) Hearing loss is defined as decreased sensitivity to sound, while deafness is hearing loss such that speech perception is not possible.

A) It is the result of a failure of sound vibrations to reach the inner ear.
B) It is caused by damage to hair cells or interruption of the vestibulocochlear nerve carrying information to the brain.
C) It is caused by damage to auditory brain areas.
D) It is caused by damage to the ossicles of the middle ear, which deadens the nerves at the base of the cochlea.

A) the eardrum.
B) nerve fibers.
C) cochlear nuclei.
D) hair cells.

A) They work by stimulating the ossicles and hair cells directly.
B) They electrically stimulate the cochlea at locations corresponding to a sound's pitch.
C) They send information about low frequencies to electrodes, stimulating nerves at the apex of the cochlea.
D) They send information about high frequencies to electrodes, stimulating nerves at the base of the cochlea.

A) pseudostereocilia.
B) binaural replacements.
C) cochlear implants.
D) sound shadows.

A) ampulla
B) vestibular nuclei
C) organ of Corti
D) pinna

A) The opening of ion channels on stereocilia
B) The sound latency difference between the two ears
C) The deflecting of the stereocilia in the ampulla
D) The activation of efferent fibers in the semicircular canals

A) the ampulla.
B) vestibular organs.
C) vestibular hair cells.
D) the basilar membrane.

A) visual; auditory
B) vestibular; motor
C) vestibular; visual
D) visual; motor

A) Conduction motion
B) Motion sickness
C) Sensorineural movement
D) Motion shadows

A) acoustic stimuli.
B) the movement and position of the body.
C) forces that act within the body cavities.
D) stimulation of the autonomic nervous system.

A) Turbinate
B) Foliate
C) Fungiform
D) Circumvallate

A) kokumi; pores; microvilli
B) taste buds; microvilli; papillae
C) tastants; foliates; neurons
D) papillae; buds; receptor cells

A) only at the tip of the tongue.
B) only on the left side of the tongue.
C) only on the right side of the tongue.
D) anywhere on the tongue where there are taste receptors.

A) Umami
B) Salty
C) Sour
D) Fruity

A) bitter
B) salty
C) sour
D) sweet

A) hydrogen ions interacting with ionotropic receptors.
B) sodium ions.
C) slow, metabotropic receptors.
D) T2R receptors.

A) hydrogen ions.
B) sodium and chloride ions.
C) slow, metabotropic receptors.
D) T2R receptors.

A) it activates sodium channels in taste buds.
B) it suppresses receptors for sweet in taste buds.
C) the umami receptor responds to foods that are naturally savory.
D) it activates TR2 receptors.

A) Tongue, brainstem nuclei, pituitary, somatosensory cortex
B) Tongue, pituitary, brainstem nuclei, somatosensory cortex
C) Tongue, brainstem nuclei, somatosensory cortex, thalamus
D) Tongue, brainstem nuclei, thalamus, somatosensory cortex

A) circumvallate
B) gustatory
C) umami
D) papillae

A) detection of toxins.
B) appetite and digestion.
C) immune system functions.
D) detecting subtle tastes.

A) basal
B) receptor
C) supporting
D) glomerular

A) primary olfactory cortex.
B) amygdala.
C) orbitofrontal cortex.
D) occipital lobe.

A) As a reaction to an increasingly complex olfactory environment
B) As a response to the hazards of the olfactory environment
C) As a response to declining of air quality
D) To compensate for losses of other senses as we age

A) hypothalamus.
B) amygdala.
C) olfactory bulb.
D) thalamus.

A) each odor activates a characteristic combination of different kinds of receptor molecules.
B) each odor is broken down into its component parts.
C) we have many specific genes per receptor.
D) olfactory neurons are continually replaced through adulthood.

A) main olfactory bulb.
B) accessory olfactory bulb.
C) medial dorsal thalamus.
D) orbitofrontal cortex.