1. The Special Senses Lecture Outline
Chapter 17
The Special Senses
Lecture Outline

2. Chapter 17 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 ear
Principles of Human Anatomy and Physiology, 11e

3. Chemical Senses Interaction of molecules with receptor cells
Olfaction (smell) and gustation (taste)
Both project to cerebral cortex & limbic system
evokes strong emotional reactions
Principles of Human Anatomy and Physiology, 11e

4. Anatomy of olfactory receptors
The receptors for olfaction, which are bipolar neurons, are in the nasal epithelium in the superior portion of the nasal cavity (Figure 17.1).
They are first-order neurons of the olfactory pathway.
Supporting cells are epithelial cells of the mucous membrane lining the nose.
Basal stem cells produce new olfactory receptors.
Principles of Human Anatomy and Physiology, 11e

5. Olfactory Epithelium
1 square inch of membrane holding million receptors
Covers superior nasal cavity and cribriform plate
3 types of receptor cells
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6. Cells of the Olfactory Membrane
Olfactory receptors
bipolar neurons with cilia or olfactory hairs
Supporting cells
columnar epithelium
Basal cells = stem cells
replace receptors monthly
Olfactory glands
produce mucus
Both epithelium & glands innervated cranial nerve VII.
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7. Physiology of Olfaction - Overview
Genetic evidence suggests there are hundreds of primary scents.
In olfactory reception, a generator potential develops and triggers one or more nerve impulses.
Adaptation to odors occurs quickly, and the threshold of smell is low: only a few molecules of certain substances need be present in air to be smelled.
Olfactory receptors convey nerve impulses to olfactory nerves, olfactory bulbs, olfactory tracts, and the cerebral cortex and limbic system.
Hyposmia, a reduced ability to smell, affects half of those over age 65 and 75% of those over 80. It can be caused by neurological changes, drugs, or the effects of smoking .
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8. Olfaction: Sense of Smell
Odorants bind to receptors
Na+ channels open
Depolarization occurs
Nerve impulse is triggered
Principles of Human Anatomy and Physiology, 11e

9. 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 warning
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10. Olfactory Pathway
Axons from olfactory receptors form the olfactory nerves (Cranial nerve I) that synapse in the olfactory bulb
pass through 40 foramina in cribriform plate
Second-order neurons within the olfactory bulb form the olfactory tract that synapses on primary olfactory area of temporal lobe
conscious awareness of smell begins
Other pathways lead to the frontal lobe (Brodmann area 11) where identification of the odor occurs
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11. GUSTATORY: SENSE OF SMELL
Taste is a chemical sense.
To be detected, molecules must be dissolved.
Taste stimuli classes include sour, sweet, bitter, and salty.
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12. Gustatory Sensation: Taste
Taste requires dissolving of substances
Four classes of stimuli--sour, bitter, sweet, and salty
Other “tastes” are a combination of the four taste sensations plus olfaction.
10,000 taste buds found on tongue, soft palate & larynx
Found on sides of circumvallate & fungiform papillae
3 cell types: supporting, receptor & basal cells
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13. 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.
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14. Physiology of Taste
Receptor potentials developed in gustatory hairs cause the release of neurotransmitter that gives rise to nerve impulses.
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 sweet
Mechanism
dissolved substance contacts gustatory hairs
receptor potential results in neurotransmitter release
nerve impulse formed in 1st-order neuron
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15. Gustatory Pathway First-order gustatory fibers found in cranial nerves
VII (facial) serves anterior 2/3 of tongue
IX (glossopharyngeal) serves posterior 1/3 of tongue
X (vagus) serves palate & epiglottis
Signals travel to thalamus or limbic system & hypothalamus
Taste fibers extend from the thalamus to the primary gustatory area on parietal lobe of the cerebral cortex
provides conscious perception of taste
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16. VISION
More than half the sensory receptors in the human body are located in the eyes.
A large part of the cerebral cortex is devoted to processing visual information.
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17. Accessory Structures of Eye - Overview
Eyelids or palpebrae
protect & lubricate
epidermis, dermis, CT, orbicularis oculi m., tarsal plate, tarsal glands & conjunctiva
Tarsal glands
oily secretions
Conjunctiva
palpebral & bulbar
stops at corneal edge
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18. Eyelids
The eyelids shade the eyes during sleep, protect the eyes From superficial to deep, each eyelid consists of epidermis, dermis, subcutaneous tissue, fibers of the orbicularis oculi muscle, a tarsal plate, tarsal glands, and conjunctiva (Figure 17.4a).
The tarsal plate gives form and support to the eyelids.
The tarsal glands secrete a fluid to keep the eye lids from adhering to each other.
The conjunctiva is a thin mucous membrane that lines the inner aspect of the eyelids and is reflected onto the anterior surface of the eyeball.
Eyelashes and eyebrows help protect the eyeballs from foreign objects, perspiration, and the direct rays of the sun.
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19. Eyelashes & Eyebrows Eyeball = 1 inch diameter
5/6 of Eyeball inside orbit & protected
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
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20. Lacrimal Apparatus
About 1 ml of tears produced per day. Spread over eye by blinking. Contains bactericidal enzyme called lysozyme.
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21. Extraocular Muscles
Six muscles that insert on the exterior surface of the eyeball
Innervated by CN III, IV or VI.
4 rectus muscles -- superior, inferior, lateral and medial
2 oblique muscles -- inferior and superior
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22. Tunics (Layers) of Eyeball
The eye is constructed of three layers (Figure 17.5).
Fibrous Tunic (outer layer)
Vascular Tunic (middle layer)
Nervous Tunic (inner layer)
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23. Fibrous Tunic -- Description of Cornea
Transparent
Helps focus light(refraction)
astigmatism
3 layers
nonkeratinized stratified squamous
collagen fibers & fibroblasts
simple squamous epithelium
Transplants
common & successful
no blood vessels so no antibodies to cause rejection
Nourished by tears & aqueous humor
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24. Fibrous Tunic -- Description of Sclera
“White” of the eye
Dense irregular connective tissue layer -- collagen & fibroblasts
Provides shape & support
At the junction of the sclera and cornea is an opening (scleral venous sinus)
Posteriorly pierced by Optic Nerve (CNII)
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25. Vascular Tunic -- Choroid & Ciliary Body
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 lens
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26. 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 eye
Autonomic reflexes
circular muscle fibers contract in bright light to shrink pupil
radial muscle fibers contract in dim light to enlarge pupil
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27. Vascular Tunic -- Muscles of the Iris
Constrictor pupillae (circular) are innervated by parasympathetic fibers while Dilator pupillae (radial) are innervated by sympathetic fibers.
Response varies with different levels of light
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28. Vascular Tunic -- Description of lens
Avascular
Crystallin proteins arranged like layers in onion
Clear capsule & perfectly transparent
Lens held in place by suspensory ligaments
Focuses light on fovea
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29. Vascular Tunic -- Suspensory ligament
Suspensory ligaments attach lens to ciliary process
Ciliary muscle controls tension on ligaments & lens
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30. 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 Ophthalmoscope
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31. Photoreceptors shapes of their outer segments differ Rods
specialized for black-and-white vision in dim light
allow us to discriminate between different shades of dark and light
permit us to see shapes and movement.
Cones
specialized for color vision and sharpness of vision (high visual acuity) in bright light
most densely concentrated in the central fovea, a small depression in the center of the macula lutea.
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32. Photoreceptors
The macula lutea is in the exact center of the posterior portion of the retina, corresponding to the visual axis of the eye.
The fovea is the area of sharpest vision because of the high concentration of cones.
Rods are absent from the fovea and macula and increase in density toward the periphery of the retina.
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33. Layers of Retina Pigmented epithelium nonvisual portion
absorbs stray light & helps keep image clear
3 layers of neurons (outgrowth of brain)
photoreceptor layer
bipolar neuron layer
ganglion neuron layer
2 other cell types (modify the signal)
horizontal cells
amacrine cells
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34. Rods & Cones--Photoreceptors
Rods----rod shaped
shades of gray in dim light
120 million rod cells
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 (acuity)
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35. 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 cortex
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36. Lens
The eyeball contains the nonvascular lens, just behind the pupil and iris.
The lens fine tunes the focusing of light rays for clear vision.
With aging the lens loses elasticity and its ability to accommodate resulting in a condition known as presbyopia.
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37. Cavities of the Interior of Eyeball
Anterior cavity (anterior to lens)
filled with aqueous humor
produced by ciliary body
continually drained
replaced every 90 minutes
2 chambers
anterior chamber between cornea and iris
posterior chamber between iris and lens
Posterior cavity (posterior to lens)
filled with vitreous body (jellylike)
formed once during embryonic life
floaters are debris in vitreous of older individuals
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38. Eye Anatomy
The pressure in the eye, called intraocular pressure, is produced mainly by the aqueous humor.
The intraocular pressure, along with the vitreous body, maintains the shape of the eyeball and keeps the retina smoothly applied to the choroid so the retina will form clear images.
Glaucoma
increased intraocular pressure
problem with drainage of aqueous humor
may produce degeneration of the retina and blindness
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39. Aqueous Humor opening in white of eye at junction of cornea & sclera
Continuously produced by ciliary body
Flows from posterior chamber into anterior through the pupil
Scleral venous sinus
canal of Schlemm
opening in white of eye at junction of cornea & sclera
drainage of aqueous humor from eye to bloodstream
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40. 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 eye
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41. 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 lens
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42. 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 lens
Light rays from > 20’ are nearly parallel and only need to be bent enough to focus on retina
Light rays from < 6’ are more divergent & need more refraction
extra process needed to get additional bending of light is called accommodation
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43. Accommodation & the Lens
Accommodation is an increase in the curvature of the lens, initiated by ciliary muscle contraction, which allows the lens to focus on near objects (figure 17.10c).
Convex lens refract light rays towards each other
Lens of eye is convex on both surfaces
Viewing a distant object
lens is nearly flat by pulling of suspensory ligaments
View a close object
ciliary muscle is contracted & decreases the pull of the suspensory ligaments on the lens
elastic lens thickens as the tension is removed from it
increase in curvature of lens is called accommodation
The near point of vision is the minimum distance from the eye that an object can be clearly focused with maximum effort.
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44. 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 lens
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45. Refraction Abnormalities
Myopia is nearsightedness (Figure 17.11).
Hyperopia is farsightedness (Figure 17.11).
Astigmatism is a refraction abnormality due to an irregular curvature of either the cornea or lens.
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46. 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 focus
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47. Constriction of the Pupil
Constrictor pupillae muscle contracts
Narrows beam of light that enters the eye
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
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48. 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.
In convergence, the eyeballs move medially so they are both directed toward an object being viewed.
required so that light rays from the object will strike both retinas at the same relative point
extrinsic eye muscles must coordinate this action
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49. Physiology of Vision
The first step in vision transduction is the absorption of light by photopigments (visual pigments) in rods and cones (photoreceptors) (Figure 17.12).
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50. Photoreceptors Named for shape of outer segment
Receptors transduce light energy into a receptor potential in outer segment
Photopigment is integral membrane protein of outer segment membrane
photopigment membrane is folded into “discs” & replaced at a very rapid rate
Photopigments
opsin (protein) + retinal (derivative of vitamin A)
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51. Physiology of Vision
Photopigments are undergo structural changes upon light absorption.
Retinal is the light absorbing part of all visual photopigments.
All photopigments involved in vision contain a glycoprotein called opsin and a derivative of vitamin A called retinal.
There are four different opsins
A cone contains one of three different kinds of photopigments so there are three types of cones.
permit the absorption of 3 different wavelengths (colors) of light
Rods contain a single type of photopigment (rhodopsin)
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52. Physiology of Vision
Figure shows how photopigments are activated and restored.
Bleaching and regeneration of the photopigments accounts for much but not all of the sensitivity change during light and dark adaptation.
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53. Photopigments Isomerization
light cause cis-retinal to straighten & become trans-retinal shape
Bleaching
enzymes separate the trans-retinal from the opsin
colorless final products
Regeneration
in darkness, an enzyme converts trans-retinal back to cis-retinal (resynthesis of a photopigment)
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54. Application: Color Blindness & Night Blindness
Most forms of colorblindness (inability to distinguish certain colors) result from an inherited absence of or deficiency in one of the three cone photopigments and are more common in males. A deficiency in rhodopsin may cause night blindness (nyctalopia)
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 A
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55. Regeneration of Bleached Photopigments
Pigment epithelium near the photoreceptors contains large amounts of vitamin A and helps the regeneration process.
After complete bleaching, it takes 5 minutes to regenerate 1/2 of the rhodopsin
Full regeneration of bleached rhodopsin takes 30 to 40 minutes
Rods contribute little to daylight vision, since they are bleached as fast as they regenerate.
Only 90 seconds are required to regenerate the cone photopigments
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56. 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-white
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57. Details: Formation of Receptor Potentials
In darkness
Na+ channels are held open and photoreceptor is always partially depolarized (-30mV)
continuous release of inhibitory neurotransmitter onto bipolar cells suppresses their activity
In light
enzymes cause the closing of Na+ channels producing a hyperpolarized receptor potential (-70mV)
release of inhibitory neurotransmitter is stopped
bipolar cells become excited and a nerve impulse will travel towards the brain
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58. Release of Neurotransmitters
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59. Visual Pathway
Horizontal cells transmit inhibitory signals to bipolar cells
bipolar or amacrine cells transmit excitatory signals to ganglion cells
ganglion cells which depolarize and initiate nerve impulses (Figure 17.8).
Impulses are conveyed through the retina to the optic nerve, the optic chiasma, the optic tract, the thalamus, and the occipital lobes of the cortex (Figure 17.15).
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60. Retinal Processing of Visual Information
Convergence
one cone cell synapses onto one bipolar cell produces best visual acuity
600 rod cells synapse on single bipolar cell increasing light sensitivity although slightly blurry image results
126 million photoreceptors converge on 1 million ganglion cells
Horizontal and amacrine cells
horizontal cells enhance contrasts in visual scene because laterally inhibit bipolar cells in the area
amacrine cells excite bipolar cells if levels of illumination change
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61. Brain Pathways of Vision
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62. Processing of Image Data in the Brain
Visual information in optic nerve travels to
hypothalamus to establish sleep patterns based upon circadian rhythms of light and darkness
midbrain for controlling pupil size & coordination of head and eye movements
occipital lobe for vision
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63. Visual fields
Fibers from nasal 1/2 of each retina cross in optic chiasm
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 and Right occipital lobe sees left 1/2 of the world.
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64. Anatomy of the Ear Region
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65. HEARING AND EQUILIBRIUM - Overview
The external (outer) ear collects sound waves.
The middle ear (tympanic cavity) is a small, air-filled cavity in the temporal bone that contains auditory ossicles (middle ear bones, the malleus, incus, and stapes), the oval window, and the round window (Figure 17.17).
The internal (inner) ear is also called the labyrinth because of its complicated series of canals (Figure 17.18).
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66. Anatomy of the Ear Region
Principles of Human Anatomy and Physiology, 11e

67. External Ear The external (outer) ear collects
sound waves and passes them
inwards (Figure 17.16)
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 infection
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68. Middle Ear Cavity
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69. 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 =mastoiditis
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70. Muscles of the Ear Stapedius m. inserts onto stapes
prevents very large vibrations of stapes from loud noises
Tensor tympani attaches to malleus
limits movements of malleus & stiffens eardrum to prevent damage
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71. Bony Labyrinth
The bony labyrinth is a series of cavities in the petrous portion of the temporal bone.
It can be divided into three areas named on the basis of shape: the semicircular canals and vestibule, both of which contain receptors for equilibrium, and the cochlea, which contains receptors for hearing.
The bony labyrinth is lined with periosteum and contains a fluid called perilymph. This fluid, chemically similar to cerebrospinal fluid, surrounds the membranous labyrinth.
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72. Inner Ear---Bony Labyrinth
Bony labyrinth = set of tubelike cavities in temporal bone
semicircular canals, vestibule & cochlea lined with periosteum & filled with perilymph
surrounds & protects Membranous Labyrinth
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73. Inner Ear---Membranous Labyrinth
Membranous labyrinth = set of membranous tubes containing sensory receptors for hearing & balance
utricle, saccule, ampulla, 3 semicircular ducts & cochlea
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74. Membranous Labyrinth
The membranous labyrinth is a series of sacs and tubes lying inside and having the same general form as the bony labyrinth.
lined with epithelium.
contains a fluid called endolymph, chemically similar to intracellular fluid.
The vestibule constitutes the oval central portion of the bony labyrinth. The membranous labyrinth in the vestibule consists of two sacs called the utricle and saccule.
Anterior to the vestibule is the cochlea, which consists of a bony spiral canal that makes almost three turns around a central bony core called the modiolus (Figure 17.19a).
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75. Semicircular Canals
Projecting upward and posteriorly from the vestibule are the three bony semicircular canals.
arranged at approximately right angles (X-Y-Z axis)
The anterior and posterior semicircular canals are oriented vertically; the lateral semicircular canal is oriented horizontally.
Two parts
One end of each canal enlarges into a swelling called the ampulla.
The portions of the membranous labyrinth that lie inside the semicircular canals are called the semicircular ducts (membranous semicircular canals).
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76. Cranial nerves of the Ear Region
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77. Nerve Vestibulocochlear nerve = CN VIII
The vestibular branch of the vestibulocochlear nerve consists of 3 parts
ampullary, utricular, and saccular nerves
cochlear branch has spiral ganglion in bony modiolus
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78. Overview of Physiology of Hearing
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79. Physiology of Hearing - Overview
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 is attached to the eardrum
Stapes pushes on oval window producing fluid pressure waves in scala vestibuli & tympani
oval window vibration is 20X more vigorous than eardrum (but the frequency of vibration is unchanged)
Pressure fluctuations inside cochlear duct move the hair cells against the tectorial membrane
Microvilli are bent producing receptor potentials
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80. Tubular Structures of the Cochlea
Stapes pushes on fluid of scala vestibuli at oval window
At helicotrema, vibration moves into scala tympani
Fluid vibration dissipated at round window which bulges
The central structure is vibrated (cochlear duct)
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81. Cochlea
Cross sections through the cochlea show that it is divided into three channels by partitions that together have the shape of the letter Y (Figure a-c).
The channel above the bony partition is the scala vestibuli, which ends at the oval window.
The channel below is the scala tympani, which ends at the round window.
The scala vestibuli and scala tympani both contain perilymph and are completely separated except at an opening at the apex of the cochlea called the helicotrema.
The third channel (between the wings of the Y) is the cochlear duct (scala media).
The vestibular membrane separates the cochlear duct from the scala vestibuli, and the basilar membrane separates the cochlear duct from the scala tympani.
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82. Cochlear Anatomy – Zoom In
Section thru one turn of Cochlea
Partitions that separate the channels are Y shaped
bony shelf of central modiolus
vestibular membrane above & basilar membrane below form the central fluid filled chamber (cochlear duct)
Fluid vibrations affect hair cells in cochlear duct
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83. Cochlear Anatomy – Zoom Out
3 fluid filled channels found within the cochlea
scala vestibuli, scala tympani and cochlear duct
Vibration of the stapes upon the oval window sends vibrations into the fluid of the scala vestibuli
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84. Anatomy
Resting on the basilar membrane is the spiral organ (organ of Corti), the organ of hearing (Figure 17.19, c,d).
Projecting over and in contact with the hair cells of the spiral organ is the tectorial membrane, a delicate and flexible gelatinous membrane.
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85. Anatomy of the Organ of Corti
16,000 hair cells have 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 ganglion
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86. Sound Waves
Sound waves result from the alternate compression and decompression of air molecules.
The sounds heard best by human ears are at frequencies between 1000 and 4000 Hertz (Hz; cycles per minute), but many people perceive a range of 20 to 20,000 Hz
speech is 100 to 3000 Hz
Frequency of a sound vibration is percieved as pitch
higher frequency is higher pitch
The volume of a sound is its intensity (the greater the size of the vibration, the louder the sound, measured in decibels, dB).
Conversation is 60 dB; pain above 140dB
OSA requires ear protection above 90dB
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87. Deafness Nerve deafness
possibly nerve damage (CN VIII), but usually damage to hair cells from antibiotics, high pitched sounds, anticancer drugs, etc.
the louder the sound the quicker the loss of hearing
person may fail to notice loss until they have difficulty hearing frequencies of speech
Conduction deafness
perforated eardrum
otosclerosis
vibrations are not “conducted” to hair cells
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88. Physiology of Hearing
The events involved in hearing are seen in Figure
The auricle directs sound waves into the external auditory canal.
Sound waves strike the tympanic membrane, causing it to vibrate back and forth.
The vibration conducts from the tympanic membrane through the ossicles (through the malleus to the incus and then to the stapes).
The stapes moves back and forth, pushing the membrane of the oval window in and out.
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89. Physiology of Hearing - Review
The movement of the oval window sets up fluid pressure waves in the perilymph of the cochlea (scala vestibuli).
Pressure waves in the scala vestibuli are transmitted to the scala tympani and eventually to the round window, causing it to bulge outward into the middle ear.
As the pressure waves deform the walls of the scala vestibuli and scala tympani, they push the vestibular membrane back and forth and increase and decrease the pressure of the endolymph inside the cochlear duct.
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90. Physiology of Hearing - Review
The pressure fluctuations of the endolymph move the basilar membrane slightly, moving the hair cells of the spiral organ against the tectorial membrane; the bending of the hairs produces receptor potentials that lead to the generation of nerve impulses in cochlear nerve fibers.
Pressure changes in the scala tympani cause the round window to bulge outward into the middle ear.
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91. Hair Cell Physiology - Review
Hair cells convert mechanical deformation into electrical signals
As microvilli are bent, mechanically-gated channels in the membrane let in K+ ions
This depolarization spreads & causes voltage-gated Ca+2 channels at the base of the cell to open
Triggering the release of neurotransmitter onto the first order neuron
more neurotransmitter means more nerve impulses
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92. More on Pitch and Volume
Differences in pitch are related to differences in the width and stiffness of the basilar membrane and sound waves of various frequencies that cause a “standing wave.”
High-frequency (high-pitch) tone causes the basilar membrane to vibrate near the base of the cochlea (where it is stiff and narrow.)
Low-frequency (low-pitch) tone causes the basilar membrane to vibrate near the apex of the cochlea (where it is flexible and wide.)
Hair cells beneath the vibrating region of the basilar membrane convert the mechanical force (stimulus) into an electrical signal (receptor potential)
Sounds of the same pitch vibrate the same region of the membrane, and thus stimulate the same cells, but a louder sound causes a greater vibration amplitude -- which our brain interprets as “louder.”
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93. Auditory Pathway
Cochlear branch of CN VIII sends signals to cochlear and superior olivary nuclei (of both sides) within medulla oblongata
differences in the arrival of impulses from the ears, allows us to locate the source of a sound along the horizon (right vs. left)
Fibers ascend to the
medulla, most impulses then cross to the opposite side and then travel to the
midbrain (inferior colliculus)
to the thalamus
to the auditory area of the temporal lobe
primary auditory cortex (areas 41 & 42)
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94. Otoacoustic Emissions
The cochlea can produce sounds called otoacoustic emissions.
caused by vibrations of the outer hair cells that occur in response to sound waves and to signals from motor neurons.
vibration travels backwards toward the eardrum
can be recorded by sensitive microphone next to the eardrum
Purpose
as outer hair cells shorten, they stiffen the tectorial membrane
amplifies the responses of the inner hair cells
increasing our auditory sensitivity
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95. 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 sounds
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96. Applications Otosclerosis
a condition is which there is an overgrowth of spongy bone over the oval window that immobilizes the stapes.
prevents the transmission of sound waves to the inner ear and leads to conductive hearing loss
Principles of Human Anatomy and Physiology, 11e

97. Vestibular Apparatus
Notice: semicircular ducts with ampulla, utricle & saccule
Principles of Human Anatomy and Physiology, 11e

98. Physiology of Equilibrium (Balance)
Static equilibrium
maintain the position of the body (head) relative to the force of gravity
macula receptors within saccule & utricle
Dynamic equilibrium
maintain body position (head) during sudden movement of any type--rotation, deceleration or acceleration
crista receptors within ampulla of semicircular ducts
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99. Otolithic Organs: Saccule and Utricle
The maculae of the utricle and saccule are the sense organs of static equilibrium.
They also contribute to some aspects of dynamic equilibrium (Figure 17.21).
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100. Otolithic Organs: Saccule & Utricle
Cell types in the macula region
hair cells with stereocilia (microvilli) & one cilia (kinocilium)
supporting cells that secrete gelatinous layer
Gelatinous otolithic membrane contains calcium carbonate crystals called otoliths that move when you tip your head
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101. Detection of Position of Head
Movement of stereocilia or kinocilium results in the release of neurotransmitter onto the vestibular branches of the vestibulocochler nerve
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102. Membranous Semicircular Ducts
The three semicircular ducts, along with the saccule and utricle maintain dynamic equilibrium (Figure 17.22).
anterior, posterior & horizontal ducts detect different movements (combined 3-D sensitivity)
The cristae in the semicircular ducts are the primary sense organs of dynamic equilibrium.
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103. Crista: Ampulla of Semicircular Ducts
Small elevation within each of three semicircular ducts
Hair cells are covered with cupula (gelatinous material)
When you move, fluid in canal tends to stay in place, thus bending the cupula and bending the hair cells - and altering the release of neurotransmitter
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104. Detection of Rotational Movement
Nerve signals to the brain are generated indicating which direction the head has been rotated
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105. Equilibrium Pathways in the CNS
Most vestibular branch fibers of the vestibulocochlear nerve (CN VIII) enter the brain stem and terminate in the medulla; the remaining fibers enter the cerebellum.
Fibers from these areas connect to:
cranial nerves that control eye and head and neck movements (III,IV,VI & XI)
vestibulospinal tract that adjusts postural skeletal muscle contractions in response to head movements
The cerebellum receives constant updated sensory information which it sends to the motor areas of the cerebral cortex
motor cortex can then adjust its signals to maintain balance
Principles of Human Anatomy and Physiology, 11e

106. DEVELOPMENT OF THE EYES AND EARS
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107. Eyes
Eyes begin to develop when the ectoderm of the lateral walls of the prosencephalon bulges to form a pair of optic grooves (Figure 17.23a)
As the neural tube closes the optic grooves enlarge and move toward the surface of the ectoderm and are known as optic vesicles (Figure 17.23b)
When the optic vesicles reach the surface, the surface ectoderm thickens to form the lens placodes and the distal portions of the optic vesicles invaginate to form the optic cups (Figure 17.23c).
The optic cups remain attached to the prosencephalon by the optic stalks (Figure 17.23d).
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108. Principles of Human Anatomy and Physiology, 11e

109. Ears
Inner ear develops from a thickening of surface ectoderm called the otic placode (Figure 17.24a).
Otic placodes invaginate to form otic pits (Figure a and b)
Optic pits pinch off from the surface ectoderm to form otic vesicles (Figure 17.24d)
Otic vesicles will form structures associated with the membranous labyrinth of the inner ear.
Middle ear develops from the first pharyngeal (branchial) pouch.
The external ear develops from the first pharyngeal cleft (Figure 17.24).
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111. AGING AND THE SPECIAL SENSES
Age related changes in the eyes
Presbyopia
Cataracts
Weakening of the muscles that regulate the size of the pupil
Diseases such as age related macular disease, detached retina, and glaucoma
Decrease in tear production
Sharpness of vision as well as depth and color perception are reduced.
Principles of Human Anatomy and Physiology, 11e

112. AGING AND THE SPECIAL SENSES
After age 50 some individuals experience loss of olfactory and gustatory receptors.
Age related changes in the ears
Presbycusis – hearing loss due to damaged or loss of hair cells in the organ of Corti
Tinnitus (ringing in the ears) becomes more common
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113. DISORDERS: HOMEOSTATIC IMBALANCES
A cataract is a loss of transparency of the lens that can lead to blindness.
Glaucoma is abnormally high intraocular pressure, due to a buildup of aqueous humor inside the eyeball, which destroys neurons of the retina. It is the second most common cause of blindness (after cataracts), especially in the elderly.
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114. DISORDERS: HOMEOSTATIC IMBALANCES
Deafness is significant or total hearing loss. It is classified as sensorineural (caused by impairment of the cochlear or cochlear branch of the vestibulocochlear nerve) or conduction (caused by impairment of the external and middle ear mechanisms for transmitting sounds to the cochlea).
Meniere’s syndrome is a malfunction of the inner ear that may cause deafness and loss of equilibrium.
Otitis media is an acute infection of the middle ear, primarily by bacteria. It is characterized by pain, malaise, fever, and reddening and outward bulging of the eardrum, which may rupture unless prompt treatment is given. Children are more susceptible than adults.
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Principles of Human Anatomy and Physiology, 11e