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Hearing and Deafness 1. Anatomy & physiology Chris Darwin Web site for lectures, lecture notes and filtering lab:

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1 Hearing and Deafness 1. Anatomy & physiology Chris Darwin Web site for lectures, lecture notes and filtering lab: http://www.lifesci.susx.ac.uk/home/Chris_Darwin/ safari

2 Protection Impedance match Capture; Amplify mid-freqs Vertical direction coding Frequency analysis Transduction Outer, middle & inner ear

3 Middle ear structure

4 Conductive hearing loss Sounds don’t get into cochlea Middle ear problems Helped by surgery and by amplification

5 Protection Impedance match Capture; Amplify mid-freqs Vertical direction coding Frequency analysis Transduction Outer, middle & inner ear

6 Cochlea

7 Cochlea cross-section

8 Travelling wave on basilar membrane sorts sounds by frequency

9 Reponse of basilar membrane to sine waves Each point on the membrane responds best to a different frequency: high freq at base, low at apex. amadeus praat

10 Organ of Corti

11 Inner hair cell

12 Hair Cell Stereocilia

13 Auditory nerve innervation OHC (2) spiral afferent (green) medial efferent (red) IHC (1) radial afferent (blue) lateral efferent (pink)

14 Auditory nerve rate-intensity functions

15 Phase Locking of Inner Hair Cells Auditory nerve connected to inner hair cell tends to fire at the same phase of the stimulating waveform.

16 Phase-locking

17 Inner vs Outer Hair Cells

18

19 OHC movement Passive No OHC movement Active With OHC movement

20 OHC activity Increases sensitivity (lowers thresholds) Increases selectivity (reduces bandwidth of auditory filter) Gives ear a logarithmic (non-linear) amplitude response Produce Oto-acoustic emissions OHCs are relatively more active for quiet sounds than for loud sounds. They only amplify sounds that have the characteristic frequency of their place.

21 Auditory nerve frequency-threshold curves

22 Auditory tuning curves Healthy ear Inner hair-cell damage

23 Outer-hair cell damage

24 BM becomes linear without OHCs (furosemide injection)

25 Amplification greater and tuning more selective at low levels Robles, L. and Ruggero, M. A. (2001). "Mechanics of the mammalian cochlea," Physiological Review 81, 1305-1352.

26 Conductive vs Sensori-neural deafness Becomes linear, so No combination tones Or two-tone suppression Mostly a combination of OHC and IHC damage

27 Normal vs Impaired Dynamic Range

28 Normal auditory non-linearities Normal loudness growth (follows Weber’s Law) Combination tones Two-tone suppression Oto-acoustic emissions

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