Physiology of auditory & vestibular

Question 1

What is the structure of the basilar membrane?

Answer 1

Narrow and stiff near oval/round windows

Wider and more flexible near helicotrema

Question 2

Where do high vs low frequency sounds cause deflection of the basilar membrane?

Answer 2

High frequency - where membrane is narrow and stiff (base)

Low frequency - where membrane is loose and flexible (apex)

Question 3

How is the frequency of sound (pitch) coded?

Answer 3

Depends on where along the basilar membrane there is the greatest deflection

Question 4

What is amplitude?

Answer 4

Sound pressure/intensity measured in decibels (dB)

Question 5

What is frequency?

Answer 5

Number of oscillations of air pressure per second (Hz)

Question 6

How are the outer hair cells activated?

Answer 6

They are displaced when the pressure differential results in a shearing force against the tectorial membrane

Question 7

How are the inner hair cells activated?

Answer 7

By fluid movement in the cochlear duct

Question 8

What type of receptor is the TRPA1 channel?

Answer 8

A mechanotransduction ion channel

Question 9

What is the advantage to a mechanotransduction channel?

Answer 9

They respond to stimuli much faster than a chemical signal transduction process. They are also more sensitive to stimuli

Question 10

Where is endolymph found and what makes it up?

Answer 10

Fills the scala media and bathes the apical end of the hair cells. Similar to ICF, high in K+ and low in Na+

Question 11

Where is perilymph found and what makes it up?

Answer 11

Foundin scala vestibuli and scala tympani, bathes the basal end of cochlear hair cells. Similar to ECF, high Na+ and low K+

Question 12

How are hair cells depolarized?

Answer 12

Cation channels at the apical ends open when the tip links connecting hair cells are stretched. Influx of K+ (from endolymph) depolarizes the cell

Question 13

How does depolarization of hair cells cause sound waves to be converted to action potentials?

Answer 13

After K+ depolarizes the hair cell, Ca2+ channels at the base of the hair cell open. This causes NT-filled vesicles to release glutamate onto the afferent cochlear nerve fibers

Question 14

How are hair cells situated in the cochlea?

Answer 14

The stereocilia at the tips are embedded in the tectorial membrane and the bodies rest on the basilar membrane

Question 15

What does an upward displacement of the basilar membrane do?

Answer 15

Causes shearing force to laterally displace stereocilia which depolarizes the hair cell

Question 16

What do inner hair cells do vs outer hair cells?

Answer 16

Inner hair cells- responsible for hearing, contain 90% of cochlear nerve fibers
Outer hair cells- specialized type of epithelial cells that amplify sound waves via their contractile properties

Question 17

What does the stria vascularis do?

Answer 17

Produces endolymph and maintains its electrochemical properties

Question 18

What is the blood-labyrinth barrier?

Answer 18

The high endocochlear potential that serves to drive positively charged ions into the hair cells down their concentration gradient. It is one of the main sites of drug entry to inner hair cells

Question 19

What are otoacoustic emissions?

Answer 19

Retrograde movement of the basilar membrane toward the oval window and through the middle ear via the ossicles causing displacement of the tympanic membrane and therefore producing sound

Question 20

How do olivocochlear efferents help protect the cochlea during intense sound?

Answer 20

Reduce electromotility of outer hair cells and reduce responses of inner hair cells
-also decreass basilar membrane motion

Question 21

How do medial ear efferents help protect the cochlea during intense sound?

Answer 21

Tensor tympani m and stapedius m attenuate sounds. Bilateral response decreases transmission of sound

Question 22

How do autonomic efferents help protect the cochlea during intense sound?

Answer 22

Regulate vascular tone in blood supply to the cochlea, arise from CN VIII (sympathetic adrenergic fibers)

Question 23

What do the dorsal cochlear nuclei do vs the ventral cochlear nuclei?

Answer 23

DCN - integrates acoustic info with somatosensory info

VCN - begins processing temporal and spectral features of sound

Question 24

What does the medial superior olivary complex vs the lateral superior olivary complex do?

Answer 24

MSO - generates map of interaural time differences to localize sound
LSO - generates map of interaural intensity differences to localize source of sound

Both receive excitatory (glutamatergic) input and then converge into the Inferior Colliculus

Question 25

What does the inferior colliculus do?

Answer 25

Suppresses echoes and uses information from MSO and LSO to help create precise origin of sound

Question 26

What does the medial geniculate nucleus do?

Answer 26

Processes features of speech inflections. Receives information regarding intensity, frequency, and binaural properties of sound and relays this information onward

Question 27

What does the primary auditory cortex (A1) do?

Answer 27

Conscious perception of sound, higher order processing (loudness, volume modulation, rate of freq)

Question 28

What does the secondary auditory cortex (A2) do?

Answer 28

Broca’s + Wernicke’s + others

Responding to more complex sounds, speech, and identifying (naming) a sound

Question 29

What causes sensorineural hearing loss?

Answer 29

Inner ear problems (hair cells or cochlear nerve itself)

Question 30

How does a cochlear prosthesis work?

Answer 30

The electrode array inserted into the oval window mimics the tonotopy of the basilar membrane and stimulates nerves at discrete frequencies

Question 31

What activates the anterior, horizontal, and posterior semicircular canals?

Answer 31

Anterior- rotation in vertical plane forward
Horizontal- rotation in horizontal plane
Posterior - rotation in vertical plane backward

Question 32

What activates the utricle vs saccule?

Answer 32

Utricle- linear acceleration forward and backward

Saccule- linear acceleration up and down

Question 33

What is the order of hair cell activation in sound?

Answer 33

1. waves hit stapes- it moves
2. pressure falls in scala vestibuli (lower than tympani)
3. upward bowing of basilar membrane
4. Organ of Corti ‘shears’ toward tectorial membrane hinge
5. outer hair cells tilt TOWARDS stereovilli–cause depol
6. basilar membrane attenuates UP to cause a endolymph wave that moves to the tectorial membrane
7. Causes the inner hair cells to brand toward stereovilli and depolarize (via voltage gated Ca channels opening)
8. Synaptic vescicles fuse- Glutamate is released (Ach)