Lecture 19; Sound 3

Question 1

Describe the transfer of sound to the inner ear:

Answer 1

The external ear resonates the sound (makes it louder) this displaces the tympanic membrane, displacing the ossicular tree, which articulates and the stapes oscillates the round window

This causes displacement of the fluid which causes the sensory cells to connect with the tectorali membrane and transduction to occur

The round window is a membranous layer that can move to allow fluid displacement.

Question 2

Describe what happens when the stapes articulates;

Answer 2

Movement in the stapes in the oval window sets up a traveling wave on the organ of corti and basilar membrane

Question 3

As the travelling wave moves along the organ of corti what happens?

Answer 3

The wave increases in amplitude, decreasing wavelength but maintaining frequency until the point of resonance.

Question 4

What does the point of resonance signify on the organ of corti?

Answer 4

The point of resonance occurs at a single frequency.

The point of resonance will be defined by the mass and stiffness of the structures (organ of corti)

Additional mechanisms enables this to form a peak of activity and around this area threshold/ sensory cells will be stimulated.

Different frequencies will change the point of resonance.

Question 5

Describe HZ organisation of the organ of corti;

Answer 5

Base = High frequencies (near oval window)

Apex = low frequencies

Position of peak of travelling wave varies spatially with frequency

Question 6

How is complex sound processed by the organ of corti?

Answer 6

• Multiple resonate frequencies occur

Question 7

How does the organ of corti act as a mechanical filter?

Answer 7

Gradient in mechanical properties along length generates mechanical filter

Question 8

Describe the mechanical properties along the basilar membrane;

Answer 8

Gradual gradient;

Basal end: Thick, narrow and stiff

Apical end: Thin wide and compliant

Question 9

how is the cochlea mapped?

Answer 9

Tonotopically mapped

• Hz distribution (ability to seperate freqeuncies) thus at those resonating points, those sensory cells are activated and sound is transduced.

Question 10

Does tonotopicity extend beyond the basilar membrane?

Answer 10

Yes it extends into the cortices where some neurons only respond to specific frequencies..

Question 11

What sort of motion is the vertical motion of the organ of corti translated to in the sensory cells?

Answer 11

Vertical motion of the organ of corti is converted into radial motion at the stereocilia. (as they rub against the tectorali membrane, which leads to sensory transduction)

Question 12

Describe radial movement and sensory cell depolarisation;

Answer 12

Movement in one radial direction generates depolarisation, while movement in the other causes hyperpolarisation (but only in the one plane)

Question 13

What part of the IHC and OHC are the sensory transducers?

Answer 13

The stereocilia are the transduction elements

Question 14

Describe the stereocilia:

Answer 14

There are an array of different length stereocilia. B/w the longer and shorter one there are little bridges and this is where the transduction channels are.

Question 15

What are the bridges between stereocilia called?

Answer 15

tip links (transduction channels)

Question 16

What are tip links?

Answer 16

• Dont know what constitutes the channels
• Mechanical, electrical transduction channels (linking mechanical motion to electrical transduction)
• Made up a single cadhedrin molecule with a proteocadhedrin molecule at either end.

Question 17

Are transduction channels found in tip links?

Answer 17

No, they movement of the stereocilia causes the tip links to pull, opening the transduction channel son the stereocilia, enabling ions to flow into the cell and activate it.

Question 18

What is essential of tip links for stereocilia function?

Answer 18

There is always a good amount of tension on tip links to ensure stereocilia are at optimal state… that is the actin filaments can actually increase or decrease the tension if make sure it stays within the optimal range.

Ensuring sound is heard.

Question 19

How does the tip links system function as an adaptive mechanism?

Answer 19

• It will tone itself down to prevent background noise from being heard

Question 20

What happens to tip links with loud noise exposure?

Answer 20

They break, this is where initial sound damage occurs, they do repair but lose this ability after being broken a number of times.

Question 21

What does opening of the transduction channels by tip links lead to?

Answer 21

A channel opening between the endolymph and the sensory cells

K flows into the cells, depolarising it.

Question 22

Describe receptor potential with a tone being player for a period of time.

Answer 22

Displacement leads to PERIODIC changes in membrane voltage which at low Hz follows HZ.(AC COMPONENT)

(i.e the basilar membrane keeps displacing in the wave nature, so the sensory cells keep depolarising in a wave pattern)

At high HZ leads to net depolarisation during duration of sound. (DC COMPONENT)

• Think about how this will correlate with neurotransmitter release

Question 23

What is the DC component due to?

Answer 23

The DC component is due to high capacitance of cell membrane and inability to follow Hz

Question 24

What is the AC component due to?

Answer 24

AC due to Hz dependant changes in receptor potential

Question 25

What is depolarisation and repolarisation of the hair cells driven by?

Answer 25

Mediated by K from endolymph driven by the endocochlear potential

Question 26

Whats the RMP of the inner hair cells?

Answer 26

-70mV

(endolymph is ~+80mV)

= endocochlear potential, the very large potential across the surface of the hair cell and is essential for transduction

Question 27

Why is there such a large potential across the inner hair cell?

Answer 27

B/c there is no K gradient as the fluids both have strong K concentrations, but there is an electrical gradient, it must be higher fro transduction to occur

Question 28

For every mV this potential drops whats the hearing loss?

Answer 28

1db for 1mV

Question 29

Why do stereocilia hyperpolarise when moved in the off direction?

Answer 29

B/c this closes the transduction channels, but background channels remain open thus hyperpolarisation occurs.

Question 30

What is the first key characteristic that tells us the function of IHC?

Answer 30

The innervation pattern

Question 31

What does the innervation pattern tell us?

Answer 31

Predominant afferent innervation of IHC (thus main sensory cell input)

Predominant efferent innervation of OHC

Question 32

How many rows of hair cells are there?

Answer 32

1 IHC

3OHC

Question 33

What do OHC do?

Answer 33

Amplify sound and tuning at low levels (of the mechanical response)

Question 34

How do OHC function?

Answer 34

The travelling wave is actively amplified by action of OHC to overcome the viscous forces of the fluid and resistance of the tissues.

They oscillate and pulls itself up pushing on the tectorali membrane

Question 35

How do the OHC achieve their function?

Answer 35

• OHC are electromotile
• Motor proteins (prestin) in the cell membranes
• The affects cochlear mechanical motion known as the cochlear amplifier.

Question 36

What are the types of afferent fibres?

Answer 36

Spiral ganglion fibres

Type one: innervates IHC
Type Two: innervates OHC

Question 37

What are special proteins in the IHC for controlled neurotransmitter release?

Answer 37

Hair Cell Ribbon synapses

Question 38

How do ribbon synapses function?

Answer 38

They have lots of neurotransmitter vesicles docked onto them, allowing for controlled neurotransmitter release

Acts as a converyor belt, ensures locking between stimulus and neurotransmitter release.

Question 39

Describe the tuning of the auditory nerve fibres;

Answer 39

Auditory nerve fibres are sharply tuned to different Hz

They tend to respond to some extent below their maximum Hz.

Synchronized firing at low Hz but at higher ones they turn on and adapt, continuously firing.

Question 40

What are the two mechanisms for frequency coding of the auditory nerves?

Answer 40

Place principle

Volley principle

Question 41

Whats the place principle?

Answer 41

Cochlear is a filter and is tonotopically organised so that Hz is detected by spatial representation from base to apex

Question 42

What is volley principle?

Answer 42

Low Hz are detected by temporal firing (synch) of nerve fibres in time to the Hz of the stimulus (phase locking)

Only useful at low Hz 1-2hz

Question 43

How is intensity encoded for?

Answer 43

Rate of firing of an individual auditory nerve fibres increases with sound intensity