1. SENSE OF HEARING EAR

2. Ear Consists of 3 parts –External ear Consists of pinna, external auditory meatus, and tympanum Transmits airborne sound waves to fluid-filled inner ear Amplifies sound energy –Middle ear Transmits airborne sound waves to fluid-filled inner ear Amplifies sound energy –Inner ear Houses 2 different sensory systems –Cochlea »Contains receptors for conversion of sound waves into nerve impulses which makes hearing possible –Vestibular apparatus »Necessary for sense of equilibrium

3. Ear

4. Parts of the ear  Outer (external) ear  Middle ear (ossicles) for hearing)  Inner ear (labyrinth) for hearing & equilibrium

5. Sound in external acoustic meatus hits tympanic membrane (eardrum) – it vibrates Pressure is equalized by the pharyngotympanic tube (AKA eustachian or auditory tube

6. The Tympanic Membrane and the Ossicular System Tympanic membrane functions to transmit vibrations in the air to the cochlea Amplifies the signal because the area of the tympanic membrane is 17 times larger than the oval window Tympanic membrane connected to the ossicles – malleus – incus – stapes

7. Attenuation of Sound by Muscle Contraction two muscles attach to the ossicles – stapedius – tensor tympani a loud noise initiates reflex contraction after 40 - 80 milliseconds attenuates vibration going to cochlea serves to protect cochlea and damps low frequency sounds i.e., your own voice

8. 1.Cochlea - hearing 2.Vestibule - equilibrium 3.Semicircular canals - equilibrium Inner ear = bony “labyrinth” of 3 parts

9. Organ of Corti receptor organ that generates nerve impulses lies on the surface of the basilar membrane, contains rows of cells with stereo cilia called hair cells the tectorial membrane lies above the stereo cilia of the hair cells movement of the basilar membrane causes the stereo cilia of the hair cells to shear back and forth against the tectorial membrane

10. The Organ of Corti

11. Nerve Impulse Origination The stereo cilia, when bent in one direction cause the hair cells to depolarize, and when bent in the opposite direction hyperpolarize. –this is what begins the neural transduction of the auditory signal Auditory signals are transmitted by the inner hair cells. –3-4 times more outer hair cells than inner hair cells –outer hair cells may control the sensitivity of the inner hair cells for different sound pitches

12. Hearing Neural perception of sound energy Involves 2 aspects –Identification of the sounds (“what”) –Localization of the sounds (“where”) Sound waves –Traveling vibrations of air –Consist of alternate regions of compression and rarefaction of air molecules

13. Formation of Sound Waves

14. Hearing Pitch (tone) of sound –Depends on frequency of air waves Intensity (loudness) –Depends on amplitude of air waves Timbre (quality) –Determined by overtones

15. Decibel unit of sound expressed in terms of the logarithm of their intensity a 10 fold increase in energy is 1 bel 0.1 bel is a decibel 1 decibel is an increase in sound energy of 1.26 times

17. Sound Wave Transmission Tympanic membrane vibrates when struck by sound waves Middle ear transfers vibrations through ossicles (malleus, incus, stapes) to oval window (entrance into fluid-filled cochlea) Waves in cochlear fluid set basilar membrane in motion Receptive hair cells are bent as basilar membrane is deflected up and down Mechanical deformation of specific hair cells is transduced into neural signals that are transmitted to auditory cortex in temporal lobe of brain for sound perception

21. Bending of Hairs on Deflection of Basilar Membrane

22. Determination of Sound Frequency and Amplitude Place principle determines the frequency of sound perceived. –Different frequencies of sound will cause the basilar membrane to oscillate at different positions. –Position along the basilar membrane where hair cells are being stimulated determines the pitch of the sound being perceived. Amplitude is determined by how much the basilar membrane is displaced.

23. The “Place Principle”

25. Chapter 6 The Peripheral Nervous System: Afferent Division; Special Senses Human Physiology by Lauralee Sherwood ©2010 Brooks/Cole, Cengage Learning

33. Determining the Direction of Sound superior olivary nucleus divided into lateral and medial nuclei lateral nuclei detects direction by the difference in sound intensities between the 2 ears medial nuclei detects direction by the time lag between acoustic signals entering the ears

34. Chapter 6 The Peripheral Nervous System: Afferent Division; Special Senses Human Physiology by Lauralee Sherwood ©2010 Brooks/Cole, Cengage Learning Auditory pathway

36. Deafness Nerve (sensorineural) deafness –impairment of the cochlea or the auditory nerve –Acoustic neuroma –Cerebello-pontine angle tumor Conduction deafness –Obstruction of External auditory canal e.g. wax or foreign body –impairment of tympanic membrane or ossicles

37. Equilibrium Vestibular apparatus –In inner ear –Consists of Semicircular canals –Detect rotational acceleration or deceleration in any direction Utricle and saccule –Detect changes in rate of linear movement in any direction –Provide information important for determining head position in relation to gravity

38. Chapter 6 The Peripheral Nervous System: Afferent Division; Special Senses Human Physiology by Lauralee Sherwood ©2010 Brooks/Cole, Cengage Learning

42. Equilibrium Neural signals generated in response to mechanical deformation of hair cells by specific movement of fluid and related structures Vestibular input goes to vestibular nuclei in brain stem and to cerebellum for use in maintaining balance and posture, controlling eye movement, perceiving motion and orientation

43. Equilibrium

45. Chapter 6 The Peripheral Nervous System: Afferent Division; Special Senses Human Physiology by Lauralee Sherwood ©2010 Brooks/Cole, Cengage Learning