Special Senses. The Senses. General senses. Special senses. Yong Jeong, MD, PhD Department of Bio and Brain Engineering

Transcription

1 8 Special Senses Yong Jeong, MD, PhD Department of Bio and Brain Engineering The Senses General senses Touch Pressure Pain Temperature Proprioception Special senses Smell Taste Sight Hearing Equilibrium 1

2 The Eye and Vision 70 percent of all sensory receptors are in the eyes Each eye has over a million nerve fibers Protection for the eye Most of the eye is enclosed in a bony orbit A cushion of fat surrounds most of the eye Accessory Structures of the Eye Eyelids and eyelashes Conjunctiva Lacrimal apparatus Extrinsic eye muscles 2

3 Site where conjunctiva merges with cornea Palpebral fissure Lateral commissure (canthus) Iris Eyelid Eyebrow Eyelid Eyelashes Pupil Lacrimal caruncle Medial commissure (canthus) Sclera (covered by conjunctiva) Figure 8.1 Accessory Structures of the Eye Eyelids Meet at the medial and lateral commissure (canthus) Eyelashes Tarsal glands produce an oily secretion that lubricates the eye Ciliary glands are located between the eyelashes 3

4 Accessory Structures of the Eye Conjunctiva Membrane that lines the eyelids Connects to the outer surface of the eye Secretes mucus to lubricate the eye and keep it moist Accessory Structures of the Eye Lacrimal apparatus = lacrimal gland + ducts Lacrimal gland produces lacrimal fluid; situated on lateral aspect of each eye Lacrimal canaliculi drain lacrimal fluid from eyes medially Lacrimal sac provides passage of lacrimal fluid towards nasal cavity Nasolacrimal duct empties lacrimal fluid into the nasal cavity 4

5 Lacrimal gland Excretory duct of lacrimal gland Conjunctiva Anterior aspect (a) Eyelid Eyelashes Tarsal glands Eyelid Figure 8.2a Lacrimal gland Excretory ducts of lacrimal gland Lacrimal sac Lacrimal canaliculus Nasolacrimal duct Inferior meatus of nasal cavity Nostril (b) Figure 8.2b 5

6 Accessory Structures of the Eye Function of the lacrimal apparatus Protects, moistens, and lubricates the eye Empties into the nasal cavity Lacrimal secretions (tears) contain: Dilute salt solution Mucus Antibodies Lysozyme (enzyme that destroys bacteria) Accessory Structures of the Eye Extrinsic eye muscles Six muscles attach to the outer surface of the eye Produce eye movements 6

7 Superior oblique muscle Superior oblique tendon Superior rectus muscle Conjunctiva Lateral rectus muscle Optic nerve Inferior rectus muscle Inferior oblique muscle (a) Figure 8.3a Trochlea Superior oblique muscle Superior oblique tendon Superior rectus muscle Axis at center of eye Inferior rectus muscle Medial rectus muscle Lateral rectus muscle (b) Figure 8.3b 7

8 Figure 8.3c Structure of the Eye Layers forming the wall of the eyeball Fibrous layer Outside layer Vascular layer Middle layer Sensory layer Inside layer 8

9 Ciliary body Ciliary zonule Cornea Iris Pupil Aqueous humor (in anterior segment) Lens Scleral venous sinus (canal of Schlemm) Vitreous humor (in posterior segment) (a) Sclera Choroid Retina Fovea centralis Optic nerve Central artery and vein of the retina Optic disc (blind spot) Figure 8.4a Ciliary body Iris Margin of pupil Aqueous humor (in anterior segment) Lens Cornea Ciliary zonule Vitreous humor in posterior segment Retina Choroid Sclera Fovea centralis Optic disc Optic nerve (b) Figure 8.4b 9

10 Structure of the Eye: The Fibrous Layer Sclera White connective tissue layer Seen anteriorly as the white of the eye Cornea Transparent, central anterior portion Allows for light to pass through Repairs itself easily The only human tissue that can be transplanted without fear of rejection Structure of the Eye: Vascular Layer Choroid is a blood-rich nutritive layer in the posterior of the eye Pigment prevents light from scattering Modified anteriorly into two structures Ciliary body smooth muscle attached to lens Iris regulates amount of light entering eye Pigmented layer that gives eye color Pupil rounded opening in the iris 10

11 Structure of the Eye: Sensory Layer Retina contains two layers Outer pigmented layer Inner neural layer Contains receptor cells (photoreceptors) Rods Cones Structure of the Eye: Sensory Layer Signals pass from photoreceptors via a twoneuron chain Bipolar neurons Ganglion cells Signals leave the retina toward the brain through the optic nerve Optic disc (blind spot) is where the optic nerve leaves the eyeball Cannot see images focused on the optic disc 11

12 Pigmented layer of retina Rod Cone Bipolar cells Ganglion cells (a) Pathway of light Figure 8.5a Pigmented layer of retina Neural layer of retina Central artery and vein of retina Optic disc Sclera Optic nerve Choroid (b) Figure 8.5b 12

13 Structure of the Eye: Sensory Layer Neurons of the retina and vision Rods Most are found towards the edges of the retina Allow dim light vision and peripheral vision All perception is in gray tones Structure of the Eye: Sensory Layer Neurons of the retina and vision Cones Allow for detailed color vision Densest in the center of the retina Fovea centralis lateral to blind spot Area of the retina with only cones Visual acuity (sharpest vision) is here No photoreceptor cells are at the optic disc, or blind spot 13

14 Structure of the Eye: Sensory Layer Cone sensitivity Three types of cones Different cones are sensitive to different wavelengths Color blindness is the result of the lack of one cone type Light absorption by cone populations 560 nm 530 nm (red cones) (green cones) 420 nm (blue cones) Wavelengths (nanometers) Figure

15 Lens Biconvex crystal-like structure Held in place by a suspensory ligament attached to the ciliary body Ciliary body Ciliary zonule Cornea Iris Pupil Aqueous humor (in anterior segment) Lens Scleral venous sinus (canal of Schlemm) Vitreous humor (in posterior segment) (a) Sclera Choroid Retina Fovea centralis Optic nerve Central artery and vein of the retina Optic disc (blind spot) Figure 8.4a 15

16 Lens Cataracts result when the lens becomes hard and opaque with age Vision becomes hazy and distorted Eventually causes blindness in affected eye Risk factors include: Diabetes mellitus Frequent exposure to intense sunlight Heavy smoking Figure

17 Two Segments, or Chambers, of the Eye Anterior (aqueous) segment Anterior to the lens Contains aqueous humor Posterior (vitreous) segment Posterior to the lens Contains vitreous humor Ciliary body Ciliary zonule Cornea Iris Pupil Aqueous humor (in anterior segment) Lens Scleral venous sinus (canal of Schlemm) Vitreous humor (in posterior segment) (a) Sclera Choroid Retina Fovea centralis Optic nerve Central artery and vein of the retina Optic disc (blind spot) Figure 8.4a 17

18 Anterior Segment Aqueous humor Watery fluid found between lens and cornea Similar to blood plasma Helps maintain intraocular pressure Provides nutrients for the lens and cornea Reabsorbed into venous blood through the scleral venous sinus, or canal of Schlemm Posterior Segment Vitreous humor Gel-like substance posterior to the lens Prevents the eye from collapsing Helps maintain intraocular pressure 18

19 Ophthalmoscope Instrument used to illuminate the interior of the eyeball Can detect diabetes, arteriosclerosis, degeneration of the optic nerve and retina Fovea centralis Macula Blood vessels Optic disc Retina Lateral Medial Figure

20 Pathway of Light Through the Eye Light must be focused to a point on the retina for optimal vision The eye is set for distance vision (over 20 feet away) Accommodation the lens must change shape to focus on closer objects (less than 20 feet away) Retina Light from distant source (a) Focal point Light from near source Focal point Retina (b) Figure

21 Pathway of Light Through the Eye Image formed on the retina is a real image Real images are: Reversed from left to right Upside down Smaller than the object Figure

22 Visual Fields and Visual Pathways Optic chiasma Location where the optic nerves cross Fibers from the medial side of each eye cross over to the opposite side of the brain Optic tracts Contain fibers from the lateral side of the eye on the same side and the medial side of the opposite eye Fixation point Right eye Left eye Optic chiasma Optic nerve Optic tract Optic radiation Thalamus Occipital lobe (visual cortex) Figure

23 Eye Reflexes Internal muscles are controlled by the autonomic nervous system Bright light causes pupils to constrict through action of radial, circular, and ciliary muscles Viewing close objects causes accommodation External muscles control eye movement to follow objects Viewing close objects causes convergence (eyes moving medially) A Closer Look Emmetropia eye focuses images correctly on the retina Myopia (nearsighted) Distant objects appear blurry Light from those objects fails to reach the retina and are focused in front of it Results from an eyeball that is too long 23

24 A Closer Look Hyperopia (farsighted) Near objects are blurry while distant objects are clear Distant objects are focused behind the retina Results from an eyeball that is too short or from a lazy lens Focal plane Correction None required (a) Emmetropic eye Concave lens (b) Myopic eye (nearsighted) Convex lens (c) Hyperopic eye (farsighted) 24

25 A Closer Look Astigmatism Images are blurry Results from light focusing as lines, not points, on the retina due to unequal curvatures of the cornea or lens Homeostatic Imbalances of the Eyes Night blindness inhibited rod function that hinders the ability to see at night Color blindness genetic conditions that result in the inability to see certain colors Due to the lack of one type of cone (partial color blindness) Cataracts when lens becomes hard and opaque, our vision becomes hazy and distorted 25

26 Homeostatic Imbalances of the Eyes Glaucoma can cause blindness due to increasing pressure within the eye Hemianopia loss of the same side of the visual field of both eyes; results from damage to the visual cortex on one side only The Ear Houses two senses Hearing Equilibrium (balance) Receptors are mechanoreceptors Different organs house receptors for each sense 26

27 Anatomy of the Ear The ear is divided into three areas External (outer) ear Middle ear (tympanic cavity) Inner ear (bony labyrinth) External (outer) ear Middle ear Internal (inner) ear Auricle (pinna) Vestibulocochlear nerve Semicircular canals Oval window Cochlea Vestibule Round window Pharyngotympanic (auditory) tube Tympanic membrane (eardrum) Hammer Anvil (malleus) (incus) Stirrup (stapes) External acoustic meatus Auditory ossicles (auditory canal) Figure

28 The External Ear Involved in hearing only Structures of the external ear Auricle (pinna) External acoustic meatus (auditory canal) Narrow chamber in the temporal bone Lined with skin and ceruminous (wax) glands Ends at the tympanic membrane The Middle Ear (Tympanic Cavity) Air-filled cavity within the temporal bone Only involved in the sense of hearing 28

29 The Middle Ear (Tympanic Cavity) Two tubes are associated with the inner ear The opening from the auditory canal is covered by the tympanic membrane The auditory tube connecting the middle ear with the throat Allows for equalizing pressure during yawning or swallowing This tube is otherwise collapsed Bones of the Middle Ear (Tympanic Cavity) Three bones (ossicles) span the cavity Malleus (hammer) Incus (anvil) Stapes (stirrup) Function Vibrations from eardrum move the hammer anvil stirrup inner ear 29

30 External (outer) ear Middle ear Internal (inner) ear Auricle (pinna) Vestibulocochlear nerve Semicircular canals Oval window Cochlea Vestibule Round window Pharyngotympanic (auditory) tube Tympanic membrane (eardrum) Hammer Anvil (malleus) (incus) Stirrup (stapes) External acoustic meatus Auditory ossicles (auditory canal) Figure 8.12 Inner Ear or Bony Labyrinth Includes sense organs for hearing and balance Filled with perilymph Contains a maze of bony chambers within the temporal bone Cochlea Vestibule Semicircular canals 30

31 External (outer) ear Middle ear Internal (inner) ear Auricle (pinna) Vestibulocochlear nerve Semicircular canals Oval window Cochlea Vestibule Round window Pharyngotympanic (auditory) tube Tympanic membrane (eardrum) Hammer Anvil (malleus) (incus) Stirrup (stapes) External acoustic meatus Auditory ossicles (auditory canal) Figure 8.12 Organs of Equilibrium Equilibrium receptors of the inner ear are called the vestibular apparatus Vestibular apparatus has two functional parts Static equilibrium Dynamic equilibrium 31

32 Semicircular canals Ampulla Vestibular nerve Vestibule (a) Figure 8.14a Static Equilibrium Maculae receptors in the vestibule Report on the position of the head Send information via the vestibular nerve Anatomy of the maculae Hair cells are embedded in the otolithic membrane Otoliths (tiny stones) float in a gel around the hair cells Movements cause otoliths to bend the hair cells 32

33 Membranes in vestibule Otoliths Otolithic membrane Hair tuft Hair cell Supporting cell Nerve fibers of (a) vestibular division of cranial nerve VIII Figure 8.13a Otolithic membrane Otoliths Hair cell Force of gravity Head upright Head tilted (b) Figure 8.13b 33

34 Dynamic Equilibrium These receptors respond to angular or rotary movements Crista ampullaris (in the ampulla of each semicircular canal) dynamic equilibrium receptors are located in the semicircular canals Tuft of hair cells covered with cupula (gelatinous cap) If the head moves, the cupula drags against the endolymph Semicircular canals Ampulla Vestibular nerve Vestibule (a) Figure 8.14a 34

35 Endolymph Ampulla Flow of endolymph (b) Cupula of crista ampullaris Direction of body movement Cupula Nerve fibers (c) Figure 8.14b-c Dynamic Equilibrium Action of angular head movements The movement of the cupula stimulates the hair cells An impulse is sent via the vestibular nerve to the cerebellum 35

36 Organs of Hearing Organ of Corti Located within the cochlea Receptors = hair cells on the basilar membrane Gel-like tectorial membrane is capable of bending hair cells Cochlear nerve attached to hair cells transmits nerve impulses to auditory cortex on temporal lobe Spiral organ of Corti Temporal bone Perilymph in scala vestibuli Vestibular membrane Afferent fibers of the cochlear nerve Temporal bone Cochlear duct (contains endolymph) (a) Perilymph in scala tympani Figure 8.15a 36

37 Hair (receptor) cells of spiral organ of Corti Tectorial membrane Vestibular membrane (b) Basilar membrane Supporting cells Fibers of the cochlear nerve Figure 8.15b Mechanism of Hearing Vibrations from sound waves move tectorial membrane Hair cells are bent by the membrane An action potential starts in the cochlear nerve Impulse travels to the temporal lobe Continued stimulation can lead to adaptation 37

38 EXTERNAL EAR MIDDLE EAR INTERNAL EAR Pinna Auditory canal Eardrum Hammer, anvil, stirrup Oval window Fluids in cochlear canals Upper and middle lower Pressure One vibration Amplitude Amplification in middle ear Spiral organ of Corti stimulated Time Figure 8.16 Mechanism of Hearing High-pitched sounds disturb the short, stiff fibers of the basilar membrane Receptor cells close to the oval window are stimulated Low-pitched sounds disturb the long, floppy fibers of the basilar membrane Specific hair cells further along the cochlea are affected 38

39 Stapes Scala vestibuli Oval window Perilymph Fibers of sensory neurons Round window (a) Scala tympani Basilar membrane Cochlear duct Fibers of basilar membrane Base (short, stiff fibers) 20,000 (High notes) 2, Frequency (Hz) Apex (long, floppy fibers) 20 (Low notes) (b) Figure 8.17 Olfaction The Sense of Smell Olfactory receptors are in the roof of the nasal cavity Neurons with long cilia Chemicals must be dissolved in mucus for detection Impulses are transmitted via the olfactory nerve Interpretation of smells is made in the cortex 39

40 Olfactory bulb Cribriform plate of ethmoid bone Olfactory tract Olfactory filaments of the olfactory nerve Olfactory mucosa Supporting cell Olfactory receptor cell (a) Mucus layer Route of inhaled air containing odor molecules Olfactory hairs (cilia) (b) Figure

41 The Sense of Taste Taste buds house the receptor organs Location of taste buds Most are on the tongue Soft palate Cheeks Epiglottis Palatine tonsil Lingual tonsil Fungiform papillae (a) Figure 8.19a 41

42 Circumvallate papilla Taste buds (b) Figure 8.19b The Tongue and Taste The tongue is covered with projections called papillae Filiform papillae sharp with no taste buds Fungiform papillae rounded with taste buds Circumvallate papillae large papillae with taste buds Taste buds are found on the sides of papillae 42

43 Structure of Taste Buds Gustatory cells are the receptors Have gustatory hairs (long microvilli) Hairs are stimulated by chemicals dissolved in saliva Structure of Taste Buds Impulses are carried to the gustatory complex by several cranial nerves because taste buds are found in different areas Facial nerve Glossopharyngeal nerve Vagus nerve 43

44 Taste Sensations Sweet receptors (sugars) Saccharine Some amino acids Sour receptors Acids Bitter receptors Alkaloids Salty receptors Metal ions Developmental Aspects of the Special Senses Formed early in embryonic development Eyes are outgrowths of the brain All special senses are functional at birth 44

45 Chemical Senses: Taste and Smell Both senses use chemoreceptors Stimulated by chemicals in solution Taste has four types of receptors Smell can differentiate a large range of chemicals Both senses complement each other and respond to many of the same stimuli Developmental Aspects of the Special Senses Eye problems Strabismus crossed eyes results from unequal pulls by the external eye muscles in babies Ophthalmia neonatorum conjunctivitis resulting from mother having gonorrhea. Baby s eyelids are swollen and pus is produced 45

46 Developmental Aspects of the Special Senses Eye problems Presbyopia old vision results from decreasing lens elasticity that accompanies aging Developmental Aspects of the Special Senses Ear problems Presbycusis type of sensorineural deafness Otosclerosis ear ossicles fuse 46

47 Electric nose, tongue Sensory substitution Braille Brain port 47

48 Retinal implant Weiland et al., 2005 Intracortical Visual Prosthesis 48

49 Cochlear Implant 49