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Physiology of Hearing & Equilibrium

Physiology of Hearing & Equilibrium. Dr. Vishal Sharma. Parts of hearing apparatus. Conductive apparatus: external & middle ear Conducts mechanical sound impulse to inner ear Perceptive apparatus: cochlea Converts mechanical sound impulse into electrical

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Physiology of Hearing & Equilibrium

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  1. Physiology of Hearing & Equilibrium Dr. Vishal Sharma

  2. Parts of hearing apparatus Conductive apparatus:external & middle ear Conducts mechanical sound impulse to inner ear Perceptive apparatus:cochlea Converts mechanical sound impulse into electrical impulse & transmits to higher centers

  3. Role of external ear • Collection of sound waves by pinna & conduction to tympanic membrane • Increases sound intensity by 15-20 dB • Cupping of hand behind pinna also increases sound intensity by 15 dB especially at 1.5 kHz.

  4. Role of middle ear in hearing • Impedance matching mechanism (step – up transformer or amplifier function) • Preferential sound pressure application to oval window (phase difference by ossicular coupling) • Equalization of pressure on either sides of tympanic membrane (via Eustachian tube)

  5. Impedance matching mechanism • When sound travels from air in middle ear to fluid in inner ear, its amplitude is ed by fluid impedance. • Only 0.1 % sound energy goes inside inner ear. • Middle ear amplifies sound intensity to compensate for this loss. Converts sound of low pressure, high amplitude to high pressure, low amplitude vibration suitable for driving cochlear fluids.

  6. Hermann von Helmholtz Described impedance matching in 1868

  7. T.M. Catenary lever (curved membrane effect): Sound waves focused on malleus. Magnifies 2 times Ossicular Lever ratio: Length of handle of malleus > long process of incus. Magnifies 1.3 times Surface area ratio (Hydraulic lever): T.M. = 55 mm2 ; Stapes foot plate = 3.2 mm2 Magnifies 17 times Total Mechanical advantage: 2 X 17 X 1.3 = 45 times = 30 – 35 dB

  8. Natural Resonance • Property to allow certain sound frequencies to pass more readily to inner ear. • External auditory canal = 2500 – 3000 Hz • Tympanic membrane = 800 - 1600 Hz • Ossicular chain = 500 – 2000 Hz • Range = 500 – 3000 Hz (speech frequency)

  9. Preferential sound pressure application (phase difference) • Sound pressure preferentially applied to oval window by ossicular coupling while round window is protected by tympanic membrane • Sound pressure travels to scala vestibuli  helicotrema  scala tympani  round window membrane yields  scala media moves up & down  movement of hair cells in scala media

  10. Preferential sound pressure application (phase difference) • Yielding of round window membrane (push-pull effect) is necessary as inner ear fluids are incompressible • Large tympanic membrane perforation  loss of this function (push-push effect)  no movement of inner ear fluids

  11. Ossicular break + intact T.M. = 55-60 dB loss Ossicular break + T.M. perforated = 45-50 dB loss

  12. Transduction of mechanical energy to electrical impulses • Movement of basilar membrane • Shear force between tectorial membrane & hair cells • Cochlear microphonics • Nerve impulses

  13. Cochlear hair cells

  14. Transducer Mechanism

  15. Auditory pathway • Eighth (Auditory) nerve • Cochlear nucleus • Olivary nucleus (superior) • Lateral lemniscus • Inferior colliculus • Medial geniculate body • Auditory cortex

  16. Theories of hearing Place / Resonance Theory (Helmholtz, 1857) Perception of pitch depends on selective vibration of specific place on basilar membrane. Telephone Theory (Rutherford, 1886) Entire basilar membrane vibrates. Pitch related to rate of firing of individual auditory nerve fibers.

  17. Theories of hearing Volley Theory (Wever, 1949) > 5 KHz: Place theory; <400 Hz: Telephone theory 400 – 5000 Hz: Volley theory Groups of fibres fire asynchronously (volley mechanism). Required frequency signal is presented to C.N.S. by sequential firing in groups of 2 - 5 fibers as each fiber has limitation of 1 Khz.

  18. Bekesy’s travelling wave theory Sound stimulus produces a wave-like vibration of basilar membrane starting from basal turn towards apex of cochlea . It increases in amplitude as it moves until it reaches a maximum & dies off. Sound frequency is determined by point of maximum amplitude. High frequency sounds cause wave with maximum amplitude near to basal turn of cochlea. Low frequency sound waves have their maximum amplitude near cochlear apex.

  19. Georg von Bekesy Won Nobel prize for his traveling wave theory in 1961

  20. Bekesy’s travelling wave theory

  21. Theories of bone conduction Compression theory:skull vibration from sound stimulus  vibration of bony labyrinth & inner ear fluids Inertia theory:sound stimulus  skull vibration but ear ossicles lag behind due to inertia. Out of phase movement of skull & ear ossicles  movement of stapes footplate vibration of inner ear fluids

  22. Theories of bone conduction Osseo-tympanic theory:sound stimulus  skull vibration but mandible condyle lags behind due to inertia. Out of phase movement of skull & mandible  vibration of air in external auditory canal  vibration of tympanic membrane Tonndorf’s theory:sound stimulus  skull vibration  rotational vibration of ear ossicles  movement of stapes footplate

  23. Physiology of equilibrium Balance of body during static or dynamic positions is maintained by 4 organs: 1. Vestibular apparatus (inner ear) 2. Eye 3. Posterior column of spinal cord 4. Cerebellum

  24. Vestibular apparatus Semicircular canals Angular acceleration & deceleration Utricle Horizontal linear acceleration & deceleration Saccule Vertical linear acceleration & deceleration

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