Unit 11 The Senses PDF

Summary

This document provides an overview of the senses, including sensory perception, receptor classification, and processing. It covers general and special senses, pain, and the anatomy of sensory organs like the eye and ear.

Full Transcript

14.1 Sensory Perception
Figure 14.2 - Receptor Classification by Cell Type
Free nerve endings
(dendrites)

Encapsulated
nerve ending

Specialized nerve ending
 Sensitive Respond to Respond to Inform brain
to pain- stimuli from stimuli arising of one's
causing outside in internal movements
stimuli body viscera and
Most blood vessels
special
sense
organs
▪ Respond to stimuli arising outside body
▪ Receptors in skin for touch, pressure, pain, and
temperature
▪ Most special sense organs
▪ Respond to stimuli arising in internal viscera and blood
vessels
▪ Sensitive to chemical changes, tissue stretch, and
temperature changes
▪ Sometimes cause discomfort but usually person is
unaware of their workings.
▪ Respond to stretch in skeletal muscles, tendons, joints,
ligaments, and connective tissue coverings of bones
and muscles
▪ Inform brain of one's movements.
 Modified dendritic
endings of sensory
neurons

Found throughout
body

Vision, hearing, equili-
brium, smell, and
taste

All are housed in
complex sense organs
▪ General senses include tactile sensations (touch,
pressure, stretch, vibration), temperature, pain, and
muscle sense.
No “one-receptor-one-function”
relationship
Receptors can respond to multiple stimuli
 : discriminative touch
: deep pressure and vibration
: deep and continuous
pressure
: muscle stretch
tendon stretch
monitor joint position and motion
 Sensation Perception

the awareness of the conscious
changes in the interpretation of
internal and external those stimuli
environment
▪ Generating a signal

▪ Pathways of neurons conduct sensory impulses received from
receptors upward to appropriate cortical regions

▪ Interpretation of sensory input depends on specific location
of target neurons in sensory cortex
Everybody perceives pain at same stimulus intensity

▪ Pain tolerance varies
▪ “Sensitive to pain” means low pain tolerance, not
low pain threshold
▪ Genes help determine pain tolerance as well as
response to pain medications
▪ - stimulation of visceral organ receptors
o Felt as vague aching, gnawing, burning
o Activated by tissue stretching, ischemia, chemicals,
muscle spasms

▪ - pain from one body region perceived
as coming from different region
o Visceral and somatic pain fibers travel along same
nerves. Ex: left arm pain during heart attack
▪ NMDA (N-methyl-D-aspartate) receptors are activated by
long-lasting or intense pain
o Allow spinal cord to “learn” hyperalgesia
o Early pain management critical to prevent

pain felt in limb that has been amputated
▪ Epidural anesthesia during surgery to reduce phantom pain
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Senses: Maintain homeostasis, by providing information about the outside
world and the internal environment

Two types of senses:

Receptors that are widely distributed
General throughout the body
senses:
Skin, various organs, and joints

Specialized receptors confined to
Special structures in the head
senses:
Eyes, ears, nose, and mouth
 30

Sensory receptors:

1. Collect information from the
environment, and relay it to the CNS
on sensory neurons
2. Link nervous system to internal and
external changes or events.

3. Can be specialized cells or
multicellular structures
33
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Special senses of the body include:

Vision Taste Smell Hearing Equilibrium

All use special sensory receptor cells localized in the head region
The sense of touch is one of the general senses, mediated by general
receptors
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70% of body’s sensory receptors are in the eye.
Half of cerebral cortex* is involved in visual
processing

*Associated with higher level processes:
consciousness, thought, emotion, reasoning,
language, and memory
 36

Eyebrow

Only one-sixth of surface Eyelid
visible Eyelashes
Mostly enclosed and Conjunctiva
protected by fat cushion merges with
cornea
and bony orbit
Palpebral
fissure
Consists of accessory Lateral
structures and the commissure
eyeball
Iris

Eyelid Pupil Sclera Lacrimal Medial
caruncle commi
ssure
Levator palpebrae superioris muscle 37

Orbicularis oculi muscle
Eyebrow
Tarsal plate
Accessory structures include:
Palpebral
conjunctiva Eyebrows
Tarsal glands
Cornea Eyelids (palpebrae)
Palpebral
fissure Conjunctiva

Lacrimal apparatus
Eyelashes
Bulbar
conjunctiva
Extrinsic eye muscles
Conjunctival sac

Orbicularis oculi muscle
 38

1 Lacrimal gland 2 Excretory ducts of
the lacrimal gland. Tears flow
Lacrimal gland and ducts down and
3
that drain into nasal cavity across
the eyeball.
Lacrimal secretion (tears): 4 Lacrimal
canaliculi
Dilute saline solution
Lacrimal punctum 5 Lacrimal sac
Mucus
Lacrimal canaliculus
Antibodies
6 Nasolacrimal
Antibacterial lysozyme duct
Inferior meatus
of nasal cavity
Nostril
 39

Six strap-like extrinsic eye muscles
Superior oblique
tendon
▪ Originate from bony orbit and
insert on eyeball
Superior oblique
muscle
▪ Follow moving objects, maintain
Superior rectus
muscle shape, and hold it in orbit

Lateral rectus Four rectus muscles
muscle
▪ Superior, inferior, lateral, and
medial
Lateral view right eye Two oblique muscles
Inferior rectus Inferior oblique ▪ Superior and inferior
 40
Trochlea

Superior
Superior oblique
rectus
Lateral Medial
rectus rectus

Inferior Inferior
oblique rectus

Anterior view right eye
 41

Wall of eyeball contains three
layers
▪ Fibrous layer: Cornea and Sclera
▪ Vascular layer
▪ Inner layer
Internal cavity filled with fluids
called humors
Lens separates internal cavity into
anterior and posterior segments
 Ora serrata
Cornea Ciliary body
▪ Transparent anterior Ciliary zonule
1/6th of fibrous layer
o Lets light enter and Cornea
bends light as it enters Iris
eye
Pupil
▪ Epithelium covers both
surfaces
Anterior segment
o Outer surface protects (contains aqueous humor)
from abrasions
o Inner layer contains Lens
sodium pumps. Scleral venous sinus

Posterior segment (vitreous humor)
Sclera ▪ Sclera
Choroid o Opaque posterior region
Retina o Protects and shapes eyeball
Macula lutea o Anchors extrinsic eye muscles
Fovea centralis
o Posteriorly, sclera is
continuous with dura mater of
brain

Optic nerve

Optic disc
 Choroid
Ora serrata
Vascular layer Ciliary body

▪ Middle pigmented Ciliary zonule
layer of eye (uvea)
Cornea
▪ Three regions:
Iris
choroid, ciliary body,
and iris Pupil

o Choroid region
Anterior segment
Supplies blood (contains aqueous humor)

Brown pigment
Lens
prevents
Scleral venous sinus
scattering of light
Posterior segment (vitreous humor)
 Choroid
Ora serrata
Ciliary body Ciliary body

▪ Anteriorly, choroid Ciliary zonule
becomes ciliary body
Cornea
▪ Ring of tissue
Iris
surrounding lens
Pupil
▪ Smooth ciliary
muscles control shape
Anterior segment
of lens (contains aqueous humor)
▪ Ciliary zonule
(suspensory ligament) Lens
holds lens in position Scleral venous sinus

Posterior segment (vitreous humor)
 Choroid
Ora serrata
Iris Ciliary body
▪ Colored part of eye Ciliary zonule
that lies between
cornea and lens, Cornea
continuous with Iris
ciliary body Pupil
▪ Pupil: central opening
that regulates amount Anterior segment
(contains aqueous humor)
of light entering eye

Lens
Scleral venous sinus

Posterior segment (vitreous humor)
 47

Parasympathetic + Sympathetic +

Sphincter pupillae Iris (two muscles) Dilator pupillae
muscle contracts: Sphincter pupillae muscle contracts:
Pupil constricts Dilator pupillae Pupil dilates
(size decreases). (size increases).
 48

o P: Pupils; how much light enters your eye
o E: Pupils are equal in size
o R: Pupils are round
o L: Pupils react to light when your
doctor shines a bright light in your
eyes
o A: Pupils react to accommodation,
which is your eyes' ability to
change focus.
 49

Inner layer (retina)
▪ Retina originates as an outpocketing
of brain
▪ Contains:
o Photoreceptor cells
o Neurons
o Glial cells
▪ Delicate two-layered membrane
o Outer pigmented layer
o Inner neural layer
 50
Retina detachment

Photo: Richard Leung/Kings College Hospital. Community Eye Health Journal Vol. 19 No. 57 MARCH 2006
 51

Retina:
Neural layer of the retina
Neural layer
Pigmented layer ▪ Anterior end has
Choroid

Choroid
serrated edges called
Optic disc ora serrata
Sclera
▪ Three main types of
neurons:
o Photoreceptors,

Optic
bipolar cells, ganglion
nerve cells
▪ Optic disc
o Site where optic nerve
leaves eye (blind spot)
 52

Retina:
Pigmented layer of the
Neural layer
Pigmented layer retina
Choroid
▪ Single-cell-thick lining
next to choroid
Sclera
▪ Functions:
o Absorbs light and
prevents its scattering
Optic o Phagocytizes
nerve photoreceptor cell
fragments
o Stores vitamin A
 53
Photoreceptors
Bipolar Rod
Ganglion cells Cone
cells
Axons of
Rods ganglion
▪ Dim light, peripheral vision cells

receptors
▪ More numerous and more
sensitive to light than cones
▪ No color vision or sharp images
Cones
▪ Vision receptors for bright light
▪ High-resolution color vision Amacrine cell

Pathway of signal output Horizontal
Pathway of light cell Pigmented
layer of retina
 Choroid 54
Outer segments
Nuclei of of rods and cones
ganglion
cells

120 million photoreceptors (rods)
and 6 million photoreceptors (cones)

Axons of Pigmented
ganglion cells Nuclei Nuclei of layer of retina
of bipolar rods and
cells cones
 55

Central
▪ Macula lutea artery
area at posterior and vein
emerging
pole lateral to from the
blind spot optic disc
o Contains mostly
cones Optic disc
▪ Fovea centralis:
tiny pit in center Macula
lutea
of macula lutea
region with
Retina
best visual Lateral Medial
acuity
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Smell (olfaction) and taste (gustation):

Complementary senses that let us know
whether a substance should be savored
or avoided.
Chemoreceptors are used by these systems

Smell receptors detect chemicals
dissolved in nasal fluids
Chemicals must be
dissolved in aqueous
solution Taste receptors respond to chemicals
dissolved in saliva
Olfactory epithelium

▪ Roof of nasal cavity
▪ Covers superior nasal conchae
 Mitral cell
Olfactory (output cell)
tract
Glomeruli

Olfactory bipolar neurons: Olfactory bulb

Cribriform plate
o Covered by mucus of ethmoid bone

(solvent for odorants) Filaments of
olfactory nerve
Lamina propria
Olfactory connective tissue
gland Olfactory axon
Olfactory stem cell
Fascicles: Olfactory sensory
Olfactory

Make up filaments
neuron
epithelium
Supporting cell
Dendrite
of olfactory nerve Mucus Olfactory cilia

(cranial nerve I) Route of inhaled air
containing odor molecules
 Mitral cell
Olfactory (output cell)
tract
Glomeruli

Olfactory bulb

Cribriform plate
Lamina propria of ethmoid bone
connective tissue
Filaments of
olfactory nerve

Olfactory
gland Olfactory axon
Olfactory stem cell
Olfactory sensory
Olfactory neuron
epithelium
Supporting cell
Dendrite

Mucus Olfactory cilia

Route of inhaled air
containing odor molecules
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Humans have ~400 “smell” genes active in nose
▪ Each encodes a unique receptor protein
▪ Each odor binds to several different receptors
▪ Each receptor has one type of receptor protein

Pain and temperature receptors are also in nasal
cavities
▪ Respond to irritants, such as ammonia, or can “smell”
hot or cold (chili peppers, menthol)
In order to smell substance, it must be volatile
▪ Must be in gaseous state
▪ Odorant must also be able to dissolve in
olfactory epithelium fluid
Odorant binds
to its receptor. 

Receptor G protein Adenylate cAMP opens a cation
activates G activates cyclase channel, allowing Na+
protein (Golf). adenylate converts ATP to and Ca2+ influx and
cyclase cAMP. causing depolarization.
   
 Olfactory Mitral cell
tract (output cell)
Filaments of olfactory Glomeruli

nerves synapse with mitral Olfactory bulb

cells at glomeruli
Sent to frontal lobe Filaments of
olfactory nerve

Smell interpreted and
identified Olfactory stem cell
Olfactory sensory
neuron
Sent to hypothalamus,
amygdala, limbic system Olfactory cilia

Emotional response Route of inhaled air
containing odor molecules
Figure 14.3 – The Tongue
 Epiglottis
Sensory organs for taste Palatine
tonsil
Most located on tongue Lingual
in papillae tonsil

Foliate
o Fungiform papillae papillae

o Foliate papillae Vallate
papillae
o Vallate papillae

Few on soft palate, cheeks, pharynx, epiglottis Fungiform
papillae
 Vallate papilla
Each consists epithelial cells of
two types:
1. Gustatory epithelial cells
▪ Have microvilli called
gustatory hairs
▪ Some release serotonin or
ATP as neurotransmitter and
others lack synaptic vesicles
2. Basal epithelial cells - stem cells Taste buds
Connective
tissue
Gustatory
Taste fibers Hair
(microvilli)
of cranial
nerve
Taste receptors adapt
rapidly:
Partial – 3-5 sec
Complete – 1-5 min
Taste
pore
Stratified
squamous
epithelium
of tongue
Basal Gustatory
epithelial epithelial
cells cells Taste bud (210×)
Five basic taste sensations:
1. Sweet sugars, saccharin, alcohol, some amino acids, some lead
salts
2. Sour hydrogen ions in solution
3. Salty metal ions (inorganic salts); sodium chloride tastes saltiest
4. Bitter alkaloids such as quinine and nicotine, caffeine, and
nonalkaloids such as aspirin
5. Umami amino acids glutamate and aspartate; example: beef (meat)
or cheese taste, and monosodium glutamate
Possible sixth taste - taste for long-chain fatty acids from lipids
“Tastants” must:

▪ Be dissolved in saliva.
▪ Diffuse into taste pores.
▪ Contact gustatory “hairs”
Two main cranial nerve pairs carry taste impulses from
tongue to brain:
1. Facial nerve (VII) carries impulses from anterior two-
thirds of tongue
2. Glossopharyngeal (IX) carries impulses from
posterior one-third and pharynx
▪ Vagus nerve transmits from epiglottis and lower
pharynx
Fibers synapse in the solitary
nucleus of the medulla, then
travel to thalamus, and then to
gustatory cortex in the insula

Hypothalamus and limbic
system allow us to determine
appreciation of taste

Taste is 80% smell
Major areas:

External (outer) ear
Hearing ONLY

Middle ear (tympanic cavity)
Hearing ONLY

Internal (inner) ear
Hearing AND Equilibrium

Receptors for hearing and balance respond to separate stimuli and are activated independently.
 Middle Internal ear
External ear ear (labyrinth)

Auricle
(pinna)

Helix

Lobule

External
Tympanic Pharyngotympanic
acoustic membrane (auditory) tube
meatus
 Oval window
Entrance to Semicircular
mastoid antrum canals

Malleus Vestibule
Auditory Incus
ossicles Vestibular
Stapes nerve
Cochlear
Tympanic nerve
membrane
Cochlea

Round window Pharyngotympanic
(auditory) tube:
Connects middle ear to
nasopharynx
 Malleus Incus Epitympanic
Superior recess
Lateral

Anterior
View

▪ Malleus: the “hammer”
▪ Incus: the “anvil”
▪ Stapes: the “stirrup”

Pharyngo- Tensor Tympanic Stapes Stapedius
tympanic tympani membrane muscle
tube muscle (medial view)
Located in temporal bone behind eye socket
Two major divisions:
▪ Bony labyrinth:
o Vestibule, semicircular
canals, cochlea, fluid

▪ Membranous labyrinth:
respond to gravity and
o series of membranous sacs
changes in position of head
and ducts.
Semicircular canals
▪ Three canals oriented in three planes of space:
anterior, lateral, and posterior

▪ Ampulla: enlarged area of ducts of each canal that
houses equilibrium receptor region called the crista
ampullaris.
Receptors respond to angular
(rotational) movements of the head
Figure 14.7 – Cross Section of the Cochlea

Contains mechanoreceptor
hair cells

Organ of Corti

Scala vestibuli

Scala tympani
 Figure 14.8 – Hair Cells
Tectorial
membrane

stereocilia

hair cells

The stereocilia are tethered together by proteins that The tectorial membrane amplifies auditory stimuli by
open ion channels when the array is bent toward the deflecting the stereocilia of the outer hair cells. Sound
tallest member of their array and closed when the array is waves cause the tectorial membrane to shear against
bent toward the shortest member of their array. the hair cells, which displaces the stereocilia and
triggers the flow of transducer currents.
Figure 14.10 - Frequency Coding in the Cochlea
Figure 14.11 - Linear Acceleration Coding by Maculae
Otoliths

stereocilia

Otoliths

Motion and head position
Each crista has supporting cells and hair cells that extend
into gel-like mass called ampullary cupula.

Cristae respond to changes
in velocity of rotational
movements of head.
Inertia in ampullary cupula
causes endolymph in semicircular
ducts to move in direction
opposite body’s rotation, causing
hair cells to bend.
 Ampullary cupula
Crista
ampullaris
Endolymph

Hair bundle
(kinocilium
plus stereocilia)

Crista Hair cell
Membranous ampullaris
labyrinth
Supporting
Fibers of vestibular nerve
cell
Figure 14.12 - Rotational Coding by Semicircular Canals