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Premium member Presentation Transcript Chapter 16 The Special Senses: 1 Chapter 16 The Special Senses Smell, taste, vision, hearing and equilibrium Housed in complex sensory organs Ophthalmology is science of the eye Otolaryngology is science of the earChemical Senses: 2 Chemical Senses Interaction of molecules with receptor cells Olfaction (smell) and gustation (taste) Both project to cerebral cortex & limbic system evokes strong emotional reactionsOlfactory Epithelium: 3 Olfactory Epithelium 1 square inch of membrane holding 10-100 million receptors Covers superior nasal cavity and cribriform plate 3 types of receptor cellsOlfaction: Sense of Smell: 4 Olfaction: Sense of Smell Odorants bind to receptors Na+ channels open Depolarization occurs Nerve impulse is triggeredAdaptation & Odor Thresholds: 5 Adaptation & Odor Thresholds Adaptation = decreasing sensitivity Olfactory adaptation is rapid 50% in 1 second complete in 1 minute Low threshold only a few molecules need to be present methyl mercaptan added to natural gas as warningGustatory Sensation: Taste: 6 Gustatory Sensation: Taste Taste requires dissolving of substances Four classes of stimuli--sour, bitter, sweet, and salty 10,000 taste buds found on tongue, soft palate & larynxAnatomy of Taste Buds: 7 Anatomy of Taste Buds An oval body consisting of 50 receptor cells surrounded by supporting cells A single gustatory hair projects upward through the taste pore Basal cells develop into new receptor cells every 10 days.Physiology of Taste: 8 Physiology of Taste Complete adaptation in 1 to 5 minutes Thresholds for tastes vary among the 4 primary tastes most sensitive to bitter (poisons) least sensitive to salty and sweetAccessory Structures of Eye: 9 Accessory Structures of Eye Eyelids or palpebrae protect & lubricate Tarsal glands oily secretions keep lids from sticking together Conjunctiva stops at corneal edge dilated BV--bloodshotEyelashes & Eyebrows: 10 Eyelashes & Eyebrows Eyelashes & eyebrows help protect from foreign objects, perspiration & sunlight Sebaceous glands are found at base of eyelashes (sty) Palpebral fissure is gap between the eyelids Eyeball = 1 inch diameter 5/6 of Eyeball inside orbit & protectedLacrimal Apparatus: 11 Lacrimal Apparatus About 1 ml of tears produced per day. Spread over eye by blinking. Contains bactericidal enzyme called lysozyme.Extraocular Muscles: 12 Extraocular Muscles Six muscles that insert on the exterior surface of the eyeball . 4 rectus muscles -- superior, inferior, lateral and medial 2 oblique muscles -- inferior and superiorTunics (Layers) of Eyeball: 13 Tunics (Layers) of Eyeball Fibrous Tunic (outer layer) Vascular Tunic (middle layer) Nervous Tunic (inner layer)Fibrous Tunic -- Description of Cornea : 14 Transparent Helps focus light(refraction) astigmatism Transplants common & successful no blood vessels so no antibodies to cause rejection Fibrous Tunic -- Description of CorneaFibrous Tunic -- Description of Sclera: 15 Fibrous Tunic -- Description of Sclera “White” of the eye Dense irregular connective tissue layer -- collagen & fibroblasts Provides shape & supportVascular Tunic -- Choroid & Ciliary Body : 16 Vascular Tunic -- Choroid & Ciliary Body Choroid pigmented epithilial cells (melanocytes) & blood vessels provides nutrients to retina black pigment in melanocytes absorb scattered light Ciliary body ciliary processes folds on ciliary body secrete aqueous humor ciliary muscle smooth muscle that alters shape of lensVascular Tunic -- Iris & Pupil: 17 Vascular Tunic -- Iris & Pupil Colored portion of eye Shape of flat donut suspended between cornea & lens Hole in center is pupil Function is to regulate amount of light entering eyeVascular Tunic -- Description of lens: 18 Vascular Tunic -- Description of lens Avascular Crystallin proteins arranged like layers in onion Clear capsule & perfectly transparentNervous Tunic -- Retina: 19 Nervous Tunic -- Retina Posterior 3/4 of eyeball Optic disc optic nerve exiting back of eyeball Central retina BV fan out to supply nourishment to retina visible for inspection hypertension & diabetes Detached retina trauma (boxing) fluid between layers distortion or blindness View with OphthalmoscopeRods & Cones--Photoreceptors: 20 Rods & Cones--Photoreceptors Rods----rod shaped shades of gray in dim light 120 million rod cells discriminates shapes & movements distributed along periphery Cones----cone shaped sharp, color vision 6 million fovea of macula lutea densely packed region at exact visual axis of eye 2nd cells do not cover cones sharpest resolution or acuityPathway of Nerve Signal in Retina: 21 Pathway of Nerve Signal in Retina Light penetrates retina Rods & cones transduce light into action potentials Rods & cones excite bipolar cells Bipolars excite ganglion cells Axons of ganglion cells form optic nerve leaving the eyeball (blind spot) To thalamus & then the primary visual cortexAqueous Humor: 22 Aqueous Humor Continuously produced by ciliary body Flows from posterior chamber into anterior through the pupil Glaucoma increased intraocular pressure that could produce blindness problem with drainage of aqueous humorMajor Processes of Image Formation: 23 Major Processes of Image Formation Refraction of light by cornea & lens light rays must fall upon the retina Accommodation of the lens changing shape of lens so that light is focused Constriction of the pupil less light enters the eyeDefinition of Refraction: 24 Definition of Refraction Bending of light as it passes from one substance (air) into a 2nd substance with a different density(cornea) In the eye, light is refracted by the anterior & posterior surfaces of the cornea and the lensRefraction by the Cornea & Lens: 25 Refraction by the Cornea & Lens Image focused on retina is inverted & reversed from left to right Brain learns to work with that information 75% of Refraction is done by cornea -- rest is done by the lensNear Point of Vision and Presbyopia: 26 Near Point of Vision and Presbyopia Near point is the closest distance from the eye an object can be & still be in clear focus 4 inches in a young adult 8 inches in a 40 year old lens has become less elastic 31 inches in a 60 to 80 year old Reading glasses may be needed by age 40 presbyopia glasses replace refraction previously provided by increased curvature of the relaxed, youthful lensCorrection for Refraction Problems: 27 Correction for Refraction Problems Emmetropic eye (normal) can refract light from 20 ft away Myopia (nearsighted) eyeball is too long from front to back glasses concave Hypermetropic (farsighted) eyeball is too short glasses convex (coke-bottle) Astigmatism corneal surface wavy parts of image out of focusConstriction of the Pupil: 28 Constriction of the Pupil Constrictor pupillae muscle contracts Prevents light rays from entering the eye through the edge of the lens Sharpens vision by preventing blurry edges Protects retina very excessively bright light Convergence of the Eyes: 29 Convergence of the Eyes Binocular vision in humans has both eyes looking at the same object As you look at an object close to your face, both eyeballs must turn inward. convergencePhotoreceptors: 30 Photoreceptors Photopigment is integral membrane protein of outer segment membrane photopigment membrane folded into “discs” & replaced at a very rapid rate Photopigments = opsin (protein) + retinal (derivative of vitamin A) rods contain rhodopsin cone photopigments contain 3 different opsin proteins permitting the absorption of 3 different wavelengths (colors) of lightColor Blindness & Night Blindness: 31 Color Blindness & Night Blindness Color blindness inability to distinguish between certain colors absence of certain cone photopigments red-green color blind person can not tell red from green Night blindness (nyctalopia) difficulty seeing in low light inability to make normal amount of rhodopsin possibly due to deficiency of vitamin ALight and Dark Adaptation: 32 Light and Dark Adaptation Light adaptation adjustments when emerge from the dark into the light Dark adaptation adjustments when enter the dark from a bright situation light sensitivity increases as photopigments regenerate during first 8 minutes of dark adaptation, only cone pigments are regenerated, so threshold burst of light is seen as color after sufficient time, sensitivity will increase so that a flash of a single photon of light will be seen as gray-whiteBrain Pathways of Vision: 33 Brain Pathways of Vision synapse in thalamus & visual cortexProcessing of Image Data in the Brain: 34 Processing of Image Data in the Brain Visual information in optic nerve travels to occipital lobe for vision midbrain for controlling pupil size & coordination of head and eye movements hypothalamus to establish sleep patterns based upon circadian rhythms of light and darknessVisual fields: 35 Visual fields Left occipital lobe receives visual images from right side of an object through impulses from nasal 1/2 of the right eye and temporal 1/2 of the left eye Left occipital lobe sees right 1/2 of the world Fibers from nasal 1/2 of each retina cross in optic chiasmAnatomy of the Ear Region: 36 Anatomy of the Ear RegionExternal Ear: 37 External Ear Function = collect sounds Structures auricle or pinna elastic cartilage covered with skin external auditory canal curved 1” tube of cartilage & bone leading into temporal bone ceruminous glands produce cerumen = ear wax tympanic membrane or eardrum epidermis, collagen & elastic fibers, simple cuboidal epith. Perforated eardrum (hole is present) at time of injury (pain, ringing, hearing loss, dizziness) caused by explosion, scuba diving, or ear infectionMiddle Ear Cavity: 38 Middle Ear CavityMiddle Ear Cavity: 39 Middle Ear Cavity Air filled cavity in the temporal bone Separated from external ear by eardrum and from internal ear by oval & round window 3 ear ossicles connected by synovial joints malleus attached to eardrum, incus & stapes attached by foot plate to membrane of oval window stapedius and tensor tympani muscles attach to ossicles Auditory tube leads to nasopharynx helps to equalize pressure on both sides of eardrum Connection to mastoid bone =mastoiditisInner Ear---Bony Labyrinth: 40 Inner Ear---Bony Labyrinth ampulla Vestibule Bony labyrinth = set of tubelike cavities in temporal bone semicircular canals, vestibule & cochlea lined with periosteum & filled with perilymph surrounds & protects Membranous Labyrinth canalsInner Ear---Membranous Labyrinth: 41 Inner Ear---Membranous Labyrinth Membranous labyrinth = set of membranous tubes containing sensory receptors for hearing & balance and filled with endolymph utricle, saccule, ampulla, 3 semicircular ducts & cochleaAnatomy of the Organ of Corti: 42 Anatomy of the Organ of Corti 16,000 hair cells have 30-100 stereocilia(microvilli ) Microvilli make contact with tectorial membrane (gelatinous membrane that overlaps the spiral organ of Corti) Basal sides of inner hair cells synapse with 1st order sensory neurons whose cell body is in spiral ganglionSound Waves: 43 Sound Waves Vibrating object causes compression of air around it = sound waves audible range is 20 to 20,000 Hz hear best within 500 to 5000 cycles/sec or Hz speech is 100 to 3000 Hz Frequency of a sound vibration is pitch higher frequency is higher pitch Greater intensity (size) of vibration, the louder the sound measured in decibels (dB) Conversation is 60 dB; pain above 140dB OSA requires ear protection above 90dBDeafness: 44 Deafness Nerve deafness damage to hair cells from antibiotics, high pitched sounds, anticancer drugs the louder the sound the quicker the hearing loss fail to notice until difficulty with speech Conduction deafness perforated eardrum otosclerosisPhysiology of Hearing: 45 Physiology of Hearing Auricle collects sound waves Eardrum vibrates slow vibration in response to low-pitched sounds rapid vibration in response to high-pitched sounds Ossicles vibrate since malleus attached to eardrum Stapes pushes on oval window producing fluid pressure waves in scala vestibuli & tympani oval window vibration 20X more vigorous than eardrum Pressure fluctuations inside cochlear duct move the hair cells against the tectorial membrane Microvilli are bent producing receptor potentialsOverview of Physiology of Hearing: 46 Overview of Physiology of HearingCochlear Implants: 47 Cochlear Implants If deafness is due to destruction of hair cells Microphone, microprocessor & electrodes translate sounds into electric stimulation of the vestibulocochlear nerve artificially induced nerve signals follow normal pathways to brain Provides only a crude representation of soundsPhysiology of Equilibrium (Balance): 48 Physiology of Equilibrium (Balance) Static equilibrium maintain the position of the body (head) relative to the force of gravity Dynamic equilibrium maintain body position (head) during sudden movement of any type--rotation, deceleration or accelerationDetection of Position of Head: 49 Detection of Position of Head Movement of stereocilia or kinocilium results in the release of neurotransmitter onto the vestibular branches of the vestibulocochler nerveDetection of Rotational Movement: 50 Detection of Rotational Movement When head moves, the attached semicircular ducts and hair cells move with it Nerve signals to the brain are generated indicating which direction the head has been rotated You do not have the permission to view this presentation. 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sense orans 5 aSGuest93925 Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINT lite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 83 Category: Education License: All Rights Reserved Like it (0) Dislike it (0) Added: April 09, 2011 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Chapter 16 The Special Senses: 1 Chapter 16 The Special Senses Smell, taste, vision, hearing and equilibrium Housed in complex sensory organs Ophthalmology is science of the eye Otolaryngology is science of the earChemical Senses: 2 Chemical Senses Interaction of molecules with receptor cells Olfaction (smell) and gustation (taste) Both project to cerebral cortex & limbic system evokes strong emotional reactionsOlfactory Epithelium: 3 Olfactory Epithelium 1 square inch of membrane holding 10-100 million receptors Covers superior nasal cavity and cribriform plate 3 types of receptor cellsOlfaction: Sense of Smell: 4 Olfaction: Sense of Smell Odorants bind to receptors Na+ channels open Depolarization occurs Nerve impulse is triggeredAdaptation & Odor Thresholds: 5 Adaptation & Odor Thresholds Adaptation = decreasing sensitivity Olfactory adaptation is rapid 50% in 1 second complete in 1 minute Low threshold only a few molecules need to be present methyl mercaptan added to natural gas as warningGustatory Sensation: Taste: 6 Gustatory Sensation: Taste Taste requires dissolving of substances Four classes of stimuli--sour, bitter, sweet, and salty 10,000 taste buds found on tongue, soft palate & larynxAnatomy of Taste Buds: 7 Anatomy of Taste Buds An oval body consisting of 50 receptor cells surrounded by supporting cells A single gustatory hair projects upward through the taste pore Basal cells develop into new receptor cells every 10 days.Physiology of Taste: 8 Physiology of Taste Complete adaptation in 1 to 5 minutes Thresholds for tastes vary among the 4 primary tastes most sensitive to bitter (poisons) least sensitive to salty and sweetAccessory Structures of Eye: 9 Accessory Structures of Eye Eyelids or palpebrae protect & lubricate Tarsal glands oily secretions keep lids from sticking together Conjunctiva stops at corneal edge dilated BV--bloodshotEyelashes & Eyebrows: 10 Eyelashes & Eyebrows Eyelashes & eyebrows help protect from foreign objects, perspiration & sunlight Sebaceous glands are found at base of eyelashes (sty) Palpebral fissure is gap between the eyelids Eyeball = 1 inch diameter 5/6 of Eyeball inside orbit & protectedLacrimal Apparatus: 11 Lacrimal Apparatus About 1 ml of tears produced per day. Spread over eye by blinking. Contains bactericidal enzyme called lysozyme.Extraocular Muscles: 12 Extraocular Muscles Six muscles that insert on the exterior surface of the eyeball . 4 rectus muscles -- superior, inferior, lateral and medial 2 oblique muscles -- inferior and superiorTunics (Layers) of Eyeball: 13 Tunics (Layers) of Eyeball Fibrous Tunic (outer layer) Vascular Tunic (middle layer) Nervous Tunic (inner layer)Fibrous Tunic -- Description of Cornea : 14 Transparent Helps focus light(refraction) astigmatism Transplants common & successful no blood vessels so no antibodies to cause rejection Fibrous Tunic -- Description of CorneaFibrous Tunic -- Description of Sclera: 15 Fibrous Tunic -- Description of Sclera “White” of the eye Dense irregular connective tissue layer -- collagen & fibroblasts Provides shape & supportVascular Tunic -- Choroid & Ciliary Body : 16 Vascular Tunic -- Choroid & Ciliary Body Choroid pigmented epithilial cells (melanocytes) & blood vessels provides nutrients to retina black pigment in melanocytes absorb scattered light Ciliary body ciliary processes folds on ciliary body secrete aqueous humor ciliary muscle smooth muscle that alters shape of lensVascular Tunic -- Iris & Pupil: 17 Vascular Tunic -- Iris & Pupil Colored portion of eye Shape of flat donut suspended between cornea & lens Hole in center is pupil Function is to regulate amount of light entering eyeVascular Tunic -- Description of lens: 18 Vascular Tunic -- Description of lens Avascular Crystallin proteins arranged like layers in onion Clear capsule & perfectly transparentNervous Tunic -- Retina: 19 Nervous Tunic -- Retina Posterior 3/4 of eyeball Optic disc optic nerve exiting back of eyeball Central retina BV fan out to supply nourishment to retina visible for inspection hypertension & diabetes Detached retina trauma (boxing) fluid between layers distortion or blindness View with OphthalmoscopeRods & Cones--Photoreceptors: 20 Rods & Cones--Photoreceptors Rods----rod shaped shades of gray in dim light 120 million rod cells discriminates shapes & movements distributed along periphery Cones----cone shaped sharp, color vision 6 million fovea of macula lutea densely packed region at exact visual axis of eye 2nd cells do not cover cones sharpest resolution or acuityPathway of Nerve Signal in Retina: 21 Pathway of Nerve Signal in Retina Light penetrates retina Rods & cones transduce light into action potentials Rods & cones excite bipolar cells Bipolars excite ganglion cells Axons of ganglion cells form optic nerve leaving the eyeball (blind spot) To thalamus & then the primary visual cortexAqueous Humor: 22 Aqueous Humor Continuously produced by ciliary body Flows from posterior chamber into anterior through the pupil Glaucoma increased intraocular pressure that could produce blindness problem with drainage of aqueous humorMajor Processes of Image Formation: 23 Major Processes of Image Formation Refraction of light by cornea & lens light rays must fall upon the retina Accommodation of the lens changing shape of lens so that light is focused Constriction of the pupil less light enters the eyeDefinition of Refraction: 24 Definition of Refraction Bending of light as it passes from one substance (air) into a 2nd substance with a different density(cornea) In the eye, light is refracted by the anterior & posterior surfaces of the cornea and the lensRefraction by the Cornea & Lens: 25 Refraction by the Cornea & Lens Image focused on retina is inverted & reversed from left to right Brain learns to work with that information 75% of Refraction is done by cornea -- rest is done by the lensNear Point of Vision and Presbyopia: 26 Near Point of Vision and Presbyopia Near point is the closest distance from the eye an object can be & still be in clear focus 4 inches in a young adult 8 inches in a 40 year old lens has become less elastic 31 inches in a 60 to 80 year old Reading glasses may be needed by age 40 presbyopia glasses replace refraction previously provided by increased curvature of the relaxed, youthful lensCorrection for Refraction Problems: 27 Correction for Refraction Problems Emmetropic eye (normal) can refract light from 20 ft away Myopia (nearsighted) eyeball is too long from front to back glasses concave Hypermetropic (farsighted) eyeball is too short glasses convex (coke-bottle) Astigmatism corneal surface wavy parts of image out of focusConstriction of the Pupil: 28 Constriction of the Pupil Constrictor pupillae muscle contracts Prevents light rays from entering the eye through the edge of the lens Sharpens vision by preventing blurry edges Protects retina very excessively bright light Convergence of the Eyes: 29 Convergence of the Eyes Binocular vision in humans has both eyes looking at the same object As you look at an object close to your face, both eyeballs must turn inward. convergencePhotoreceptors: 30 Photoreceptors Photopigment is integral membrane protein of outer segment membrane photopigment membrane folded into “discs” & replaced at a very rapid rate Photopigments = opsin (protein) + retinal (derivative of vitamin A) rods contain rhodopsin cone photopigments contain 3 different opsin proteins permitting the absorption of 3 different wavelengths (colors) of lightColor Blindness & Night Blindness: 31 Color Blindness & Night Blindness Color blindness inability to distinguish between certain colors absence of certain cone photopigments red-green color blind person can not tell red from green Night blindness (nyctalopia) difficulty seeing in low light inability to make normal amount of rhodopsin possibly due to deficiency of vitamin ALight and Dark Adaptation: 32 Light and Dark Adaptation Light adaptation adjustments when emerge from the dark into the light Dark adaptation adjustments when enter the dark from a bright situation light sensitivity increases as photopigments regenerate during first 8 minutes of dark adaptation, only cone pigments are regenerated, so threshold burst of light is seen as color after sufficient time, sensitivity will increase so that a flash of a single photon of light will be seen as gray-whiteBrain Pathways of Vision: 33 Brain Pathways of Vision synapse in thalamus & visual cortexProcessing of Image Data in the Brain: 34 Processing of Image Data in the Brain Visual information in optic nerve travels to occipital lobe for vision midbrain for controlling pupil size & coordination of head and eye movements hypothalamus to establish sleep patterns based upon circadian rhythms of light and darknessVisual fields: 35 Visual fields Left occipital lobe receives visual images from right side of an object through impulses from nasal 1/2 of the right eye and temporal 1/2 of the left eye Left occipital lobe sees right 1/2 of the world Fibers from nasal 1/2 of each retina cross in optic chiasmAnatomy of the Ear Region: 36 Anatomy of the Ear RegionExternal Ear: 37 External Ear Function = collect sounds Structures auricle or pinna elastic cartilage covered with skin external auditory canal curved 1” tube of cartilage & bone leading into temporal bone ceruminous glands produce cerumen = ear wax tympanic membrane or eardrum epidermis, collagen & elastic fibers, simple cuboidal epith. Perforated eardrum (hole is present) at time of injury (pain, ringing, hearing loss, dizziness) caused by explosion, scuba diving, or ear infectionMiddle Ear Cavity: 38 Middle Ear CavityMiddle Ear Cavity: 39 Middle Ear Cavity Air filled cavity in the temporal bone Separated from external ear by eardrum and from internal ear by oval & round window 3 ear ossicles connected by synovial joints malleus attached to eardrum, incus & stapes attached by foot plate to membrane of oval window stapedius and tensor tympani muscles attach to ossicles Auditory tube leads to nasopharynx helps to equalize pressure on both sides of eardrum Connection to mastoid bone =mastoiditisInner Ear---Bony Labyrinth: 40 Inner Ear---Bony Labyrinth ampulla Vestibule Bony labyrinth = set of tubelike cavities in temporal bone semicircular canals, vestibule & cochlea lined with periosteum & filled with perilymph surrounds & protects Membranous Labyrinth canalsInner Ear---Membranous Labyrinth: 41 Inner Ear---Membranous Labyrinth Membranous labyrinth = set of membranous tubes containing sensory receptors for hearing & balance and filled with endolymph utricle, saccule, ampulla, 3 semicircular ducts & cochleaAnatomy of the Organ of Corti: 42 Anatomy of the Organ of Corti 16,000 hair cells have 30-100 stereocilia(microvilli ) Microvilli make contact with tectorial membrane (gelatinous membrane that overlaps the spiral organ of Corti) Basal sides of inner hair cells synapse with 1st order sensory neurons whose cell body is in spiral ganglionSound Waves: 43 Sound Waves Vibrating object causes compression of air around it = sound waves audible range is 20 to 20,000 Hz hear best within 500 to 5000 cycles/sec or Hz speech is 100 to 3000 Hz Frequency of a sound vibration is pitch higher frequency is higher pitch Greater intensity (size) of vibration, the louder the sound measured in decibels (dB) Conversation is 60 dB; pain above 140dB OSA requires ear protection above 90dBDeafness: 44 Deafness Nerve deafness damage to hair cells from antibiotics, high pitched sounds, anticancer drugs the louder the sound the quicker the hearing loss fail to notice until difficulty with speech Conduction deafness perforated eardrum otosclerosisPhysiology of Hearing: 45 Physiology of Hearing Auricle collects sound waves Eardrum vibrates slow vibration in response to low-pitched sounds rapid vibration in response to high-pitched sounds Ossicles vibrate since malleus attached to eardrum Stapes pushes on oval window producing fluid pressure waves in scala vestibuli & tympani oval window vibration 20X more vigorous than eardrum Pressure fluctuations inside cochlear duct move the hair cells against the tectorial membrane Microvilli are bent producing receptor potentialsOverview of Physiology of Hearing: 46 Overview of Physiology of HearingCochlear Implants: 47 Cochlear Implants If deafness is due to destruction of hair cells Microphone, microprocessor & electrodes translate sounds into electric stimulation of the vestibulocochlear nerve artificially induced nerve signals follow normal pathways to brain Provides only a crude representation of soundsPhysiology of Equilibrium (Balance): 48 Physiology of Equilibrium (Balance) Static equilibrium maintain the position of the body (head) relative to the force of gravity Dynamic equilibrium maintain body position (head) during sudden movement of any type--rotation, deceleration or accelerationDetection of Position of Head: 49 Detection of Position of Head Movement of stereocilia or kinocilium results in the release of neurotransmitter onto the vestibular branches of the vestibulocochler nerveDetection of Rotational Movement: 50 Detection of Rotational Movement When head moves, the attached semicircular ducts and hair cells move with it Nerve signals to the brain are generated indicating which direction the head has been rotated