HND 202 (Special Senses) PDF

Summary

This document provides an overview of special senses, focusing on eye structure, function and common disorders like cataracts, glaucoma, and more. It includes diagrams and detailed explanations of processes related to each topic. The document is suitable for an HND level study.

Full Transcript

**SPECIAL SENSES --**

**THE EYE**

**STRUCTURE:** The eyeball is roughly spherical and about 24mm in
diameter. It has a tough **fibrous coat** with an **opaque** posterior
part called the **sclera** which is continuous with the **strongly**
curved transparent **cornea.**

**ANATOMY OF THE EYES**

Light enters the eye through the **cornea**, passes through the
**aqueous humor**, the pupillary aperture of the **iris**, the **lens**
and **vitreous body** before striking the photosensitive **retina**
which lines the posterior **2/3** of the eye ball. The retina is
separated from the sclera by a **vascular** pigment called the
**choroid** which continues into the ciliary body and the iris. The eye
is usually directed in such a way that the image of the object focused
on falls on the **fovea** which is a **depression** in the retina. Nerve
fibres arising in the retina run across the retinal surface to pass out
the eyeball through **perforations** in the sclera.

**DIAGRAM OF THE EYE**

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**EXTERNAL PROTECTION OF THE EYE**

The human eye is protected by a strong **bony orbit** and by the **eye
lids** which are lined by the **conjuctival** on the inner surfaces. A
number of eye lashes project from the **margins** of the eyelid. The
eyelids also contain **tarsal glands** which secrete an **oily fluid**
that covers the edge of the lid and prevents tear fluid from flowing
over. The eyelids are closed by a muscled called **orbicularis oculi**
while the upper lid is raised by another muscle called the **levator
palpebrae superioris** supplied by a branch of the **oculomotor** nerve.
The eyelids close (blink) by reflex when the cornea, conjuctival, or eye
lashes are touched, when a bright light shines into the eye or when an
object suddenly approaches the eye.

Blinking occurs spontaneously about **20 times** a minute and probably
serves to renew the fluid film over the cornea. A blink last about **300
milliseconds** which implies a blackout for about **1/10** of our
walking time. The eyelids can also be closed voluntarily. Apart from
these, the lids normally close during **sneezing** and **sleep**. The
fluid that moistens the conjuctival and cornea is secreted partly by the
**lachrimal glands** in the upper and outer part of the orbit and partly
by the **accessory lachrimal** glands on the inner surfaces of the lids.
The rate of production of this tear fluid is usually adjusted to
compensate exactly for the rate of loss by evaporation when foreign body
or other irritants gets into the eye.

The discharge of tear fluid, the rate of secretion of tear fluid from
lachrimal glands into the upper conjunctival sac increases by **reflex**
activation of the **parasympathetically innervated glands**. If the rate
of secretion exceeds that of drainage into **Narso-Lachrimal** duct
through small **orifices** called **puncta lachrimalia**, tears spill
over to the cheek (It is referred to as Lachrimation). The tear fluid
produced during lachrimation is an **isotonic solution** of
**bicarbonate** and **Sodium chloride**. It has a ph of about **7.4** ad
low protein content. The fluid which also contains a **bacteriosidal
enzymes** (lysosymes) serves to wash foreign bodies or irritant
materials out of the conjuctival sac.

**PHYSIOLOGY**

1. **Cornea:** It is composed mainly of **collagen fibres anteriorly**.
The cornea is **bounded** by a **condensed** stomal layer covered by
a stratified epithelium of remarkable regularity. It contains some
of the oxygen required for its metabolism directly from the
atmosphere through its **anterior epithelium**. The **anterior**
surface of the cornea forms the **major** optical focusing component
of the eye. At the edge of the cornea the epithelium continues as
the conjunctiva. Posteriorly the cornea is bounded by an elastic
membrane and an endothelium.

2. **Anterior Chamber** **and** **Aqueous Humour:** The anterior
chamber of the eye is filled with a fluid called aqueous humor whose
composition is similar to that of the plasma **without** the
protein. It also contains less glucose and urea. The less glucose
contained in the aqueous humor is probably due to its utilization by
the lens and other tissues in the eye. The aqueous and vitreous
humor also contain high concentration of ascorbic acid (Vit. C). The
aqueous humor is **continually** been produced by the cilliary
glands. It drains into the **sinus venosus sclera** (veins located
under the nose) and the **venus plexus** which lies within the
sclera at the cornea scleral junction. The continuous production and
foo of the aqueous humor causes a higher pressure in the inside of
the eye ball than the outside. A maintenance of these intra ocular
pressure which is normally **10 -- 20mmHg** is very important and
crucial to a healthy sight. If this pressure rises unduly as is the
case of the drainage channel become blocked. Blood flow in the
retina and cheroidal circulation become impeded causing retinal
damage (**glaucoma**).

3. **The Lens:** This is composed of ribbon-like fibres arranged in a
concentric **lammae**. The cortex of the lens is **softer** than the
central nucleus. The lens has a very high protein content (about
35%) and ascorbic acid content. It is enclosed by a strong elastic
membranous capsule attached to the ciliary body by sensory
ligaments.

The thickness of the lens capsule is not uniformed. The part
covering the posterior surface is uniformly thin, while that
covering the anterior surface is thicker but with a thin central
portion. The anterior surface of the lens is much less curved than
the posterior surface. The increased convexity of the central
portion of the anterior surface **increases** the **optical power**
of the lens (accommodation). Although the lens has no blood supply,
it is a metabolically active tissue which continues to grow
throughout life. Only about **1/3** of the energy required by the
lens is obtained by **oxidative metabolism**.

As the lens ages, it becomes harder and experiences loss of
accommodation (presbyopia). At birth, the lens is pale yellow in
colour with a pigment that absorbs strongly in the near
ultra-violent. However, in old age, the lens becomes more yellow and
cloudy. In old age, the lens is very liable to become opaque
(cataract).

4. **The iris:** This is a heavily pigmented screen containing muscle
fibres which lies in front of the lens. The inner edge, forms the
margin of the circular pupil. It has a sphincter muscle which can
constrict the pupil to as little as **1mm** in diameter. It also has
some readially arranged **myoepithelial** which helps to **dilate**
the pupil although the sympathetically innervated dilator muscle
does not play a significant role in controlling the diameter of the
pupil. **Injuries** of the cervical cord which interrupts the
sympathetic pathway give rise to a small pupil. A condition known as
**miosis**. Such a condition which also paralyses the smooth muscle
of levator palpebral superioris causes the eyelid to droop (ptosis)
and the eyeball to retract (enophthalmos). These signs constitute
the **horners' syndrome**.

5. **The Retina:** This is **formed** from the optic vesicle which
grows out from the fore brain of the embryo. The retina is the light
sensitive portion of the eye. It contains the **cones** which are
responsible for **colour vision** and **the rods** which are mainly
responsible for **black** and **white vision** and for vision in the
dark. When either rods layers of neurons in the retina into **optic
nerves fibres** and the cerebral cortex.

The functional components of the retina are arranged in layers from the
outside to the inside as follows:

a. Pigmented layer

b. Layer of rods and cones projecting to the pigments

c. Outer nuclear layer containing the cell bodies of rods and cones

d. Outer plexiform layer

e. Inner nuclear layer

f. Inner plexiform layer

g. Ganglionic layer

h. Layer of optic nerve fibres

i. Inner limiting membrane.

**A minute areas** in the center of the retina called the **fovea** is
the part capable of acute and detailed vision. The central fovea which
is only **0.3mm** in diameter is composed almost entirely of **cones**.
These cones have a special structure that aids their detection of
details in the visual image. The foveal cones have special long and
slendar bodies in contrast to the much fatter cones located more
peripherally in the retina. In the foveal region, the blood vessels,
ganglion cells, inner nuclear layers of cells and plexiform layers are
all displaced to **one side** rather than resting directly on top of the
cones.

This arrangement, allows light to pass unimpeded to the cones. In
general, rods and cones are **composed** of:

1. An outer segment

2. Inner segment

3. The nucleous and

4. Synaptic body.

A **light sensitive** photochemical is usually contained in the outer
segment. In the rods, it is rhodopsin while in the cones, it is one of
the three colour photochemicals called colour pigment. Both rhodopsin
and the colour pigments are **conjugated** proteins. The protein portion
of the rods is called scotopsin while that of the cones is called
photopsin.

A black pigment called melanin in the pigment layer of the retina
prevents light reflection throughout the globe of the eyeball. This aids
clear vision. The pigment area also stores vit. A. The nutrient blood
supply for the internal layers of the retina is independent of the
either structures of the eye and it's derived from the central retinal
artery. Whereas the outer segment of the retina especially that of rods
and cones depend on diffusion from the choroid blood vessels for their
nutrition and oxygen.

**PHYSIOLOGY OF THE EYE**

For **effective** vision, rays of light reflected from an object must
enter the eye and be focused on the retina. This implies that these rays
must be refracted. To achieve this refraction, the eye uses its
**refracting** media comprising of the;

1. Cornea

2. Aqueous humour

3. Lens and

4. Vitreous humour

The lens has a refractive index of **1.413** while the rest have
**1.33** as their refractive index. The **greatest** refraction of a ray
entering the eye occurs between the lens and the cornea as well as when
it is leaving the lens.

**ACCOMMODATION**

This refers to the focusing of the lens system of the eyes to achieve a
high degree of visual acuity for both near and far object. This results
from the contraction or relaxation of the ciliary muscles of the eye.
Contraction causes an increased refractive power while relaxation causes
a decrease refractive power.

When the eyes suddenly changes distance of the fixation point, the lens
changes its strength appropriately to achieve a new state of focus
within a fraction of a second.

**PATHOLOGY OF VISION**

1. **EMMETROPIA (Normal Vision):** The eye is considered normal or
emmetropic if parallel rays of light from distant object are in
sharp focus on the retina. The emmetropic eye can see all distant
object clearly with its ciliary muscle in a relaxed state. However,
to see objects at close range, the ciliary muscle must contract and
produce appropriate accommodation.


2. **HYPEROPIA (Long sightedness):** This is usually either due to a
too short eyeball or a lens system that is too weak. In this
condition, parallel rays are not bent sufficiently by the relaxed
lens so as to focus on the retina. Images, focus behind the retina.
This can be correct by adding an extra refractive power through the
use of a convex lens in front of the eye.

3. **MYOPIA (Short Sightedness):** This is a condition where light rays
coming from distant object are focused in front of the retina. This
is usually due to too long eyeball or too much refractive power in
the lens system of the eyes. A myopic person has a definite limiting
far point for clear vision. This is corrected by placing a concave
spherical lens in front of the eyes.

Short-Sightedness (Myopia) \| Causes and Treatment \| Patient

4. **ASTIGMATISM:** This is a refractive error of the eye which causes
the virtual image in one plane to focus at a different distant from
that of the plane at right angle. This can occur as a result of
excessive curvature of the cornea in one plane of the eye. The
accommodating power of the eye can never compensate for astigmatism
because accommodation changes the curvature of the eye lens equally
in both plans. This disorder is however corrected with the use of
**cylindrical lens**.

**ABNORMALITIES OF THE EYES**

1. **Cataract:** This occurs mainly in older people and refers to a
cloudy or opaque area or areas in the lens. In the early stage of
formation, the proteins in some lens fibres becomes denatured and
later coagulate to form opaque areas in place of the normal
transparent protein fibre. This condition is usually corrected by
surgery. When this is done, the eye loses a large proportion of its
refractive power which must be replaced by a powerful convex lens in
front of the eye.

2. **GLAUCOMA:** The average normal intraocular pressure is about
**15mmHg** with a range of 12 -- 20mmHg. In a normal eye, this
pressure remains constant within [+] 2mmHg. Glaucoma is
a disease of the eye in which intraocular pressure become
pathologically high often reaching 60mmHg -- 70mmHg. Pressures about
25 -- 30mmHg can cause loss of vision when maintained for long
period. Extremely high pressures can cause blindness within hours.
High pressures compress the optic nerve thereby blocking appropriate
nutrition and causing the death of the fibre which leads to the
brain. This can be caused by any condition that blocks the
trabecular spaces. It is treated with eye drops that reduces the eye
secretion or increases the absorption of aqueous humour. When this
fails, surgery is employed to open the trabecular spaces.

**THE EAR**

The ear is the organ concerned with hearing and balancing. It has three
division; the external, middle and inner ear.

**DIAGRAM OF THE EAR**


**THE EXTERNAL EAR:** This is composed of the trumpet-like,
cartilaginous external ear (auricle) which may be helpful in localizing
the source of a sound. From the auricle, the external auditory meatus
which is about **2.5cm** long in the adult connects the external to the
**tympanic** membrane of the middle ear. The skin of the outer half of
the meatus possesses numerous ceruminous or wax secreting glands which
secretes a substance called **cerumen** which is waxy in texture. It
also helps to trap particles entering the meatus. The auditory meatus
also contains hair and sweat glands on its wall.

**THE MIDDLE EAR:** This starts from the tympanic membrane or ear drum
which is about 1cm in diameter. It is composed of radial and circular
collagenous fibres covered externally by stratified **squamous**
epithelium which is continuous with the skin. Internally, it is covered
by a mucus membrane comprising of ciliated columnar epithelium. The
outer surface of the membrane is concave while the inner surface is
convex.

The middle ear also contains a pharyngotympanic tube called Eustachian
tube which connects it to the nasal pharynx. The pharyngeal end of the
tube is normally closed but opened during swallowing to allow the air
pressure in the ear to be equalized with that of the atmosphere. Reduced
acuity in hearing occurs if the tube is blocked by a swelling of the
mucus membrane which usually occur during cold condition. The tube
therefore serves to equalize the air pressure within the ear cavity with
that of the exterior. This equalization is facilitated by swallowing.
The middle ear also contains three small bones called ossicles. They are
malleus, (hammer), incus (anvil) and stapes (stirrup).

The malleus articulates with the incus which further attaches to the
stapes. The **base** of the stapes is attached to the **margins** of the
fenestra vestibuli (oval window) by fibrous tissues. The ear drum and
the ossicles serves as a type of **transformer** that conveys vibrations
of the light medium (air) to the denser medium (water) of the internal
ear.

The area of the eardrum is about 90mm^2^ while that of the stapes is
only about 3.2mm^2^. This therefore creates more pressure in the fluid
under the stape which therefore causes the ear drum to move. This
mechanism is known as **impedance matching function.** In conditions of
a familiar and progressive deafness, in young people called
**otosclerosis**, the base of the stapes become joined by bones to the
margins of the fenestra vestibuli. This condition causes severe
deafness.

**THE INNER EAR:** The inner ear contains receptors for hearing and
equilibrium. It comprises the **cochlea** which is primarily concerned
with **hearing** as well as the semi-circular canals and **otolith**
organs which are concerned with the maintenance of balance. The cochlea
is a system of curled tubes, and consists of three (3) tubes curled side
by side. These are;

1. The scala vestibuli

2. The scala media

3. The scala tympani

The scala vestibuli and scala media are separated from each other by the
**Reissner's membrane** (vestibular membrane) while the scala tympani
and the scala media are separated from each other by the **basilar
membrane**. On the surface of the Basilar membrane, there is a structure
called the **organ of cort**; which contains a series of
**electromechanically sensitive** cell called the hair cells. They are
the receptive end organs that generate nerve impulses in response to
sound vibration. The Reissner's membrane maintains a special kind of
fluid in the scala media which is required for the normal function of
the sound receptive hair cell.

The inside of the cochlea contains a fluid known as perilymph while the
**cochlea duct** contains another fluid known as endolymph. The fluid in
the scala vestibule and scala tympani (Perilymph) is similar in chemical
composition to the cerebrospinal fluid except that it contains a higher
percentage of protein. The endolymph in the scala media also has high
potassium and low sodium composition like the intracellular fluid.

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**PATHOLOGY OF THE EAR**

Although ear disorders are rarely fatal, they impair hearing activity.
They include

1. **Inflammatory lesions:** Inflammations of the ear which includes
otitis media usually occur in children. They produce a serous
exudate (if viral) but may become suppurative if complicated by
bacteria infection, with organism streptococcus pneumonia, Herpes
influenza and murazela calaliz. Repeated cases of acute otitis media
leads to chronic diseases which may perforate the ear drum,
encroaching on the ossicles or labirinte spreading into the mastoid
cases and even penetrating into the cranial vault to produce a
temporal cerebritis or abscess.

2. **Otosclerosis:** This is an abnormal bone deposition at the rim of
the oval window into which the foot plate of the stapes fits. It
usually affect both ears. It begins in childhood and is familial
following autosomal dominant transmission with veritable penetrance.
It progresses slowly over time and results in a remarkable hearing
loss.

3. **Tumours:** Epithelial and mesenchyme tumours are rare in the ear
except basal cell or squirmous cell casinomas of the pinna. These
casinomas tend to occur in the elderly and may be associated with
actinic radiation. The basal cell or squirmous cell region of the
pinna commonly invade locally, like squirmous cell casinomas arising
in the external canal may invade the cranial cavity or metastasize
to regional nodes which are often fatal.

**HEARING ABNORMALITIES**

**Deafness:** This is usually divided into two types (a) those caused by
an impairment of the cochlea or the auditory nerve (b) those caused by
an impairment of the physical structure of the ear which conduct sound
wave to the cochlea. This is classified as conduction deafness.

**Nerve deafness** usually result in permanent deafness while in
**conduction deafness,** sound waves dcan still be conducted into the
cochlea by means of bone conduction by a sound generator applied to the
skull over the ear.

**THE CHEMICAL SENSES**

**Taste and Smell**

The senses of taste and smell allow us to separate undesirable or even
lethal food from those that are pleasant or nutritious. Both senses are
strongly tied to primitive, emotional and behavioural functions of our
nervous system.

**SENSE OF TASTE (GUSTATION)**: The sense of taste is confined to the
mouth region. The **structures** containing the receptors responsible
for the sensation of taste are the **taste bud**. They are about a
thousand in adult and are placed mainly on the peripheral part of the
**dorsum** of the tongue. They are mostly found in the groove
surrounding the valtale papillae. Though some occur on the soft palate
while a few occur on the epiglottis.

In children, they are more numerous and are more widely distributed over
the tongue and on the inside of the cheeks. The oval taste bud embedded
in the stratified epithelium covering the tongue contain thin
**fusiform** taste cells surrounded by supporting cells just like the
staves of a barrel. The taste cells have micro villi on their free
surfaces. The cells are elongated and cylindrical forming an opening at
the surface of the tongue. These opening are known as taste pores. The
taste buds are grouped into structures called papilla which are
distributed on different parts of the tongue. These papilla gives the
tongue a rough surface. All the nerve fibres that mediates the sense of
taste pass centrally to the medulla oblongata.

**PRIMARY SENSATIONS OF TASTE**

Psychophysiologic and neurophysiologic studies has identified at least
13 possible chemical receptor in the taste cells. They are:

1. 2 sodium receptor

2. 2 potassium

3. 1 chloride

4. 1 Adenosine

5. 1 inosine receptor

6. 2 sweet

7. 2 bitter

8. 1 glutamate

9. 1 hydrogen

These receptor capabilities have been grouped into five categories
called the primary sensations of taste namely;

1. Sour

2. Salty

3. Sweet

4. Bitter and

5. Umami taste.

**SOUR TASTE**

This is caused by acid (H^+^ (hydrogen ion)) and its intensity is
approximately proportional to the logarithm of the H^+^ conc. i.e. the
more acidic the food, the stronger the sour sensation. E.g. include
vinegar, which contains acetic acid, citrus fruit which contains citric
acid and sour milk which contains lactic acid.

**SALTY TASTE**

This is elicited by ionized salt mainly by the Na^+^ concentration of a
food. The quality of the taste varies from one salt to the other. The
cations of the salts especially sodium cations are mainly responsible
for the salty taste. Though the typical salt substance is NaCl,
saltiness is not a specific property of the chloride ion since sodium
bromate, sodium iodide, sodium sulphate and sodium nitrate all have
salty taste.

**SWEET TASTE**

The sweet taste is not caused by any single class of chemical. A number
of organic substances such as sucrose, glycerin, sodium cyclamate,
saccharine and a few other inorganic substance such as salts of lead and
beryllium all have sweet taste. The amino acid are sweet while
polypeptide are often bitter. The sweetest sugar is fructose followed by
sucrose followed by glucose, etc. Other substances with the sweet taste
include glygos, sugar, alcohols, aldehydes, ketones, amides, esters,
some amino acid and some small proteins.

**BITTER TASTE**

The bitter taste just like sweet taste is not caused by a single
chemical agent. The substances that give bitter taste are also almost
entirely organic. Two particular classes of substances are especially
likely to cause the bitter taste sensations. They are

1. Long chain organic substances that contain Nitrogen.

2. Long chain organic substances that contain alkaloids.

The alkaloids include many of the drugs sued in medicine e.g. quinine,
caffeine, strychnine, and nicotine.

**UMAMI TASTE**

Umami is a Japanese word meaning delicious which implies pleasant taste
sensation qualitatively different from sour, salty, sweet or bitter
taste. It is the dominant taste of foods containing L-glutamate such as
meat extract and ageing cheese.

**DIAGRAM OF TASTE BUD**

![New type of taste cell discovered in taste bu \|
EurekAlert!](media/image7.jpeg)

**THE SENSE OF SMELL (OLFACTION)**

This is the least understood of all, this is because it is poorly
developed in human being when compared with lower animal. The
**receptor** cell for the smell sensation olfactory cells which are
**bi-polar** nerve cells derived from the central nerve cells. The
mucosa end of the olfactory cells form a knob from which 4 -- 25
olfactory hairs (olfactory cilia) project into the mucus that coats the
inner surface of the nasal cavity. These projecting olfactory cilia
forms a dense mat in the mucus which reacts to odours in the air and
stimulate the olfactory cell. In between the olfactory cells in the
olfactory membrane, there are many small bow man's gland that secrete
mucus on the surface of the membrane.

صدق الله العظيم الاسراء اية 58. By Dr. Abdel Aziz M. Hussein Lecturer of
Physiology Member of American Society of Physiology. - ppt download

**PHYSIOLOGY OF SMELL**

The portion of each olfactory cell that responds to the olfactory
stimuli is the **olfactory cilia.** The deodorant substance on coming in
contact with the olfactory membrane surface diffuses into the mucus
which covers the cilia. It subsequently binds with receptor proteins on
the surface of the membrane of each cilium.

On excitation of the receptor protein, an α-subunit breaks away from the
G-protein on the inside of the folding protein and immediately activates
Adenyl cyclase which is attached to the inside of the ciliary membrane
near the receptor cell body. The activated cyclase in turn converts many
molecules of intracellular ATP into cyclic AMP's.

Finally, Cyclic Amp activates another membrane protein which is a
greater Na^+^ channel that opens its gate for large amount of Na^+^ to
pour through into the receptor cell cyntoplasm. The Na^+^ increases the
electrical potential in the positive direction inside the cell membrane.
Thus, exciting the olfactory neutron and transmitting action potentials
into the CNS through olfactory nerves. In addition to basic chemical
mechanism by which olfactory cells are stimulated. Several factors
affect the degree of stimulations. For instance,

1. Only volatile substances that can be sniffed into the nostrils can
be smelled.

2. The stimulating substances must be at least water soluble so that it
can pass through the mucus to reach the olfactory cilia.

3. The substance must be at least slightly lipid soluble because lipid
constituents of the cellium itself are a weak barrier to non-lipid
soluble odourant.