Sensory System

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Pathophysiologic manifestations
	Vision
	Hearing
	Taste and smell
Disorders
	Cataract
	Glaucoma
	Macular degeneration
	Meniere's disease
	Otosclerosis

T hrough the sensory system, a person receives stimuli that facilitate interaction with the surrounding world. Afferent pathways connect specialized sensory receptors in the eyes, ears, nose, and mouth to the brain ― the final station for continual processing of sensory stimuli. Alterations in sensory function may lead to dysfunctions of sight and hearing, as well as smell, taste, balance, and coordination.

PATHOPHYSIOLOGIC MANIFESTATIONS

Alterations can occur in all the senses.

Vision

Disorders of vision include alterations in ocular movement, visual acuity, accommodation, refraction, and color vision.

Ocular movement

The eyes constantly move to keep objects being viewed on the fovea, which is a small area of the retina that contains only cones and is responsible for the best peripheral visual acuity. The six extraocular muscles that move each eye are innervated by the oculomotor (III), trochlear (IV), and abducens (VI) cranial nerves. (See Extraocular control of eye movement .) Alterations in ocular movement include strabismus, diplopia, and nystagmus.

Strabismus. Strabismus occurs when one eye deviates from its normal position due to the absence of normal, parallel, or coordinated movement. The eyes may have an uncoordinated appearance, and the person may experience diplopia.

In children, types of strabismus are:

concomitant, in which the degree of deviation doesn't vary with the direction of gaze
nonconcomitant, in which the degree of deviation varies with the direction of gaze
congenital (present at birth or during the first 6 months)
acquired (present during the first 2? years)
latent (phoria; apparent only when the child is tired or sick)
constant.

Tropias are categorized into four types: esotropia (inward deviation), exotropia (outward deviation), hypertropia (upward deviation), and hypotropia (downward deviation).

Strabismic amblyopia is characterized by the loss of central vision in one eye; it typically results in esotropia (due to fixation in the dominant eye and suppression of images in the deviating eye). Strabismic amblyopia may result from hyperopia (farsightedness) or anisometropia (unequal refractive power).

Esotropia may result from muscle imbalance and may be congenital or acquired. In accommodative esotropia, the child's attempt to compensate for the farsightedness affects the convergent reflex, and the eyes cross.

Strabismus is frequently inherited, but its cause is unknown. In adults, strabismus may result from trauma. The incidence of strabismus is higher in patients with central nervous system disorders, such as cerebral palsy, mental retardation, and Down syndrome.

EXTRAOCULAR CONTROL OF EYE MOVEMENT

The six muscles that control the movement of each eye are innervated by three cranial nerves.


MUSCLE	DIRECTION OF MOVEMENT	INNERVATION


Superior oblique muscle	moves the eye down and in	Trochlear (cranial nerve [CN] IV)

Superior rectus muscle	moves the eye up and out	Oculomotor (CN III)

Medial rectus muscle	moves the eye inward	Oculomotor (CN III)

Lateral rectus muscle	moves the eye outward	Abducens (CN VI)

Inferior rectus muscle	moves the eye downward and outward	Oculomotor (CN III)

Inferior oblique muscle (not shown)	moves the eye up and in	Oculomotor (CN III)

Muscle imbalances may be corrected by glasses, patching, or surgery, depending on the cause. However, residual defects in vision and extraocular muscle alignment may persist even after treatment.

AGE ALERT In the absence of early intervention, children with strabismus may develop amblyopia as a result of cerebral suppression of visual stimuli. Deviation of an eye is the second most common symptom in a child with retinoblastoma. Therefore, acquired strabismus should always be checked.

Diplopia. Diplopia, or double vision, results when the extraocular muscles fail to work together and images fall on noncorresponding parts of the retinas. Diplopia usually begins intermittently or affects near or far vision exclusively. It can be classified as monocular (persisting when one eye is covered) or, more commonly, binocular (clearing when one eye is covered). Monocular diplopia may result from an early cataract, retinal edema or scarring, iridolysis (surgical lysis of adhesions of the iris), subluxated lens (partial dislocation of the lens of the eye), poorly fitting contact lens, or uncorrected refractive error. Binocular diplopia may result from ocular deviation or displacement, extraocular muscle palsies, or psychoneurosis, or after retinal surgery. Other causes of binocular diplopia include infection, neoplastic disease, metabolic disorders, degenerative disease, inflammatory disorders, and vascular disease.

Nystagmus. Nystagmus refers to involuntary oscillations or alternating movements of one or both eyes. These oscillations are usually rhythmic and may be horizontal, vertical, or rotary. They may be transient or sustained and may occur spontaneously or on deviation or fixation. Nystagmus may be classified as pendular or jerk. Nystagmoid movements usually have a fast and a slow component. The direction of the nystagmus is given by the fast component. (See Classifying nystagmus .)

Nystagmus is a supranuclear ocular palsy resulting from pathology in the visual perceptual area, vestibular system, or cerebellum. Causes of nystagmus include brain stem or cerebellar lesions, labyrinthine disease, stroke, encephalitis, Meniere's disease, multiple sclerosis, and alcohol and drug toxicity, including barbiturate, phenytoin (Dilantin), or carbamazepine (Tegretol) toxicity.

AGE ALERT In children, pendular nystagmus may be idiopathic or may result from early impairment of vision associated with such disorders as optic atrophy, albinism, congenital cataracts, and severe astigmatism.

Visual acuity

Visual acuity refers to the ability to see clearly. A lack of visual acuity is often associated with refractive errors. In nearsightedness, or myopia, the eye focuses the visual image in front of the retina, causing objects in close view to be seen clearly and those at a distance to be blurry. In farsightedness, or hyperopia, the eye focuses the visual image behind the retina, causing objects in close view to be blurry and those at a distance to be clear. Both these problems are caused by an alteration in the shape of the eyeball. Other causes of reduced visual acuity include aging, amblyopia, cataracts, glaucoma, papilledema, dark adaptation, and scotoma (an area of diminished visual acuity surrounded by an area of normal vision within the visual field).

Amblyopia is severely decreased visual acuity or virtual blindness in a structurally intact eye. It may be caused by toxins (including alcohol and tobacco) or may accompany such systemic diseases as diabetes mellitus or renal failure.

AGE ALERT With age, the pupil becomes smaller, which decreases the amount of light that reaches the retina. Older adults need about three times as much light as a younger person to see objects clearly.

Accommodation

Accommodation occurs as the thickness of the lens of the eye changes to maintain visual acuity. For near vision, the ciliary body contracts and relaxes the zonules, the lens becomes spherical, the pupil constricts, and the eyes converge. For far vision, the ciliary body relaxes, the zonules tighten, the lens becomes flatter, the eyes straighten, and the pupils dilate. The oculomotor nerve and coordinated brain stem pathways account for accommodation. Alterations in accommodation may be caused by pressure, inflammation, the aging process, or disorders affecting the oculomotor nerve. The result of impaired accommodation may be diplopia, blurred vision, or headache.

CLASSIFYING NYSTAGMUS

Nystagmus is classified as pendular or jerk. Each type has further classifications.

PENDULAR NYSTAGMUS

Oscillating: slow, steady oscillations of equal velocity around a center point; caused by congenital loss of visual acuity or multiple sclerosis.

Vertical or seesaw: rapid, seesaw movement in which one eye appears to rise while the other appears to fall; suggests an optic chiasm lesion.
JERK NYSTAGMUS

Convergence-retraction: irregular jerking of the eyes back into the orbit during upward gaze; can reflect midbrain tegmental (roof of the midbrain) damage.

Downbeat: irregular downward jerking of the eyes during downward gaze; can signal lower medullary damage.

Vestibular: horizontal or rotary movements of the eyes; suggests vestibular disease or cochlear dysfunction.

Alterations in refraction

Refraction is the process of bending light rays so that they fall on the retina. As rays of light reach the surface of the cornea from all directions, the cornea directs them toward the lens. The lens further bends the light and directs the light rays to one spot on the retina. The greater the refractive power, the more the light rays are bent. Emmetropia is the condition in which light rays fall exactly on the retina. Alterations in refraction occur when light is not properly focused. Causes include abnormalities in curvature of the cornea, focusing of the lens, and eye length. Results include myopia, hyperopia, and astigmatism. (See Refractive errors .)

Myopia. Myopia, or nearsightedness, occurs when light rays are focused in front of the retina. Near objects can be seen clearly, and distant objects appear blurry. This condition may occur if the eye is too long or the refractive power of the cornea or lens is too great. Myopia may also occur if hyperglycemia in uncontrolled diabetes causes lens swelling. A concave lens that bends light rays outward is used to correct myopia.

Hyperopia. Hyperopia, or farsightedness, occurs when light rays are focused behind the retina. Distant objects appear clear, and nearby objects are blurred. This condition occurs when the eye is too short or the refractive power of the cornea or lens is too low, and may be corrected with a convex lens that bends light rays inward.

AGE ALERT Presbyopia is a form of hyperopia that begins in middle age as the lens becomes firm and loses its elasticity. As a result, the refractive power of the lens is reduced, the eye loses its ability to accommodate, and near objects appear blurred. This condition is treated with a convex lens that bends light rays in different directions so they focus in a single point.

Astigmatism. Astigmatism occurs when unequal curvature of the cornea or eyeball causes light rays to focus on different points on the retina, resulting in distorted images. Astigmatism may occur in conjunction with other refractive disorders.

Color vision

The cones of the retina are responsible for color vision. Each cone contains one of three different visual pigments (red, green, or blue) that absorb light waves of different wavelengths.

Color blindness is inherited on the X chromosome and therefore usually affects males. Acquired color blindness may also be due to diabetes, bilateral strokes affecting the ventral portion of the occipital lobe, or disease of the macula or optic nerve.

AGE ALERT Older adults often experience impaired color vision, especially in the blue and green ranges, because cones in the retina deteriorate. Yellowing of the aging lens also impairs color vision.

Hearing

Sound waves normally enter the external auditory canal, then travel to the tympanic membrane in the middle ear, causing it to vibrate. This vibration causes the malleus to move, setting in motion the incus and, in turn, the stapes. The malleus, incus, and stapes are collectively referred to as the ossicles. The stapes presses on the oval window of the inner ear, setting in motion the fluid of the cochlea and stimulating hair cells. The hair cells carry impulses through the cochlear division of the auditory cranial nerve (VIII) to the brain. This type of sound transmission to the inner ear, called air conduction, is normally better than transmission through bone (bone conduction).

Alterations in hearing are classified as conductive or sensorineural. Mixed hearing loss combines aspects of conductive and sensorineural hearing loss.

Conductive hearing loss

Conductive hearing loss results from disorders of the external and middle ear that block sound transmission. Causes include obstruction of the external auditory canal, tumors or fluid in the middle ear, perforation of the tympanic membrane, trauma or infection that affects the ossicular chain, and fixation of the ossicles. Treatment includes hearing aids, tympanoplasty for chronic otitis media and trauma, and stapedectomy for otosclerosis.

REFRACTIVE ERRORS

TYPES OF PRESBYCUSIS

Presbycusis, sensorineural hearing loss affecting cochlear hair cells and nerve fibers, occurs in four known types: sensory, neural, metabolic, and cochlear conduction.

Sensory presbycusis begins in middle age and progresses slowly; loss of cochlear neurons parallels loss in the organ of Corti.
Neural presbycusis develops later in life; loss of cochlear neurons occurs without loss in the organ of Corti. It progresses rapidly and may be accompanied by other signs of central nervous system decline, including intellectual deterioration, memory loss, and loss of motor coordination.
Metabolic presbycusis tends to run in families, usually begins in middle age, and progresses slowly.
Cochlear-conduction presbycusis also starts in middle age and reflects changes in the motion mechanism of the cochlear duct.

Sensorineural hearing loss

Sensorineural hearing loss results from damage to the hair cells of the organ of Corti or cranial nerve VIII by very loud noises; infection; such ototoxic drugs as aminoglycoside antibiotics, aspirin, diuretics including ethacrynic acid (Edecrin) and furosemide (Lasix); tobacco and alcohol; meningitis; cochlear otosclerosis; Meniere's disease; or aging. Sensorineural hearing loss may be helped by hearing aids and cochlear implantation.

AGE ALERT The most common sensorineural hearing loss in older adults, presbycusis affects the cochlear hair cells and nerve fibers. It begins with the loss of high-frequency sounds and may progress to middle and low frequencies. (See Types of presbycusis .)

AGE ALERT Peripheral or central hearing disorders in children may lead to speech, language, and learning problems. Early identification and treatment of hearing loss is crucial so that early intervention may be started. (See Congenital hearing loss .)

Taste and smell

The senses of taste and smell are also subject to alterations.

Taste

The sensory receptors for taste are the taste buds, concentrated over the surface of the tongue and scattered over the palate, pharynx, and larynx. These buds can differentiate among sweet, salty, sour, and bitter stimuli. Taste and olfactory receptors together perceive more complex flavors. Much of what is considered taste is actually smell; food odors typically stimulate the olfactory system more strongly than related food tastes stimulate the taste buds.

A factor interrupting the transmission of taste stimuli to the brain may cause taste abnormalities. (See Taste pathways to the brain .) Taste abnormalities may result from trauma, infection, vitamin or mineral deficiencies, neurologic or oral disorders, and the effects of drugs. Moreover, because tastes are most accurately perceived in a fluid medium, mouth dryness may interfere with taste. Two major pathologic causes of impaired taste are aging, which normally reduces the number of taste buds, and heavy smoking (especially pipe smoking), which dries the tongue.

Alterations in taste may include:

ageusia, a complete loss of taste
hypogeusia, a partial loss of taste
dysgeusia, a distorted sense of taste
cacogeusia, an unpleasant or revolting taste of food.

AGE ALERT Young children are frequently unable to differentiate between an abnormal taste sensation and a simple taste dislike.

CONGENITAL HEARING LOSS

Hearing loss may be transmitted genetically as an autosomal dominant, autosomal recessive, or X-linked recessive trait. In neonates, it may result from trauma, toxicity, or infection during pregnancy or delivery.

Predisposing factors include:

family history of hearing loss or hereditary disorders (such as otosclerosis)
maternal exposure to rubella or syphilis during pregnancy
exposure to ototoxic drugs during pregnancy
prolonged fetal anoxia during delivery
congenital abnormality of ears, nose, or throat.

Premature or low-birth-weight infants are likely to have structural or functional hearing impairments. Infants with a serum bilirubin level more than 20 mg/dl also risk hearing impairment from bilirubin toxicity to the brain.

In addition, trauma during delivery may cause intracranial hemorrhage and damage to the cochlea or acoustic nerve.

Smell

As air travels between the septum and the turbinates of the nose, it touches sensory hairs (cilia) and olfactory nerve endings in the mucosal surface. The resultant stimulation of cranial nerve I sends impulses to the olfactory-receiving area, primarily in the frontal cortex. (See Olfactory perception .) Temporary impairment in the sense of smell can result from a condition that irritates and causes swelling of the nasal mucosa and obstructs the olfactory area in the nose, such as heavy smoking, rhinitis, or sinusitis. Permanent alterations in the sense of smell usually result when the olfactory neuroepithelium or a part of the olfactory nerve is destroyed. Permanent or temporary loss can also result from inhaling irritants, such as cocaine or acid fumes, that paralyze nasal cilia. Conditions such as aging, Parkinson's disease, Alzheimer's disease, or Kallmann syndrome (a congenital disorder) may also alter the sense of smell. Because combined stimulation of taste buds and olfactory cells produces the sense of taste, the loss of the sense of smell is usually accompanied by the loss of the sense of taste.

Alterations in smell include:

anosmia, a total loss of the sense of smell
hyposmia, an impaired sense of smell
parosmia, an abnormal sense of smell.

DISORDERS

The most common disorders of vision are cataract, glaucoma, and macular degeneration. Other common sensory disorders include Meniere's disease and otosclerosis.

Cataract

A cataract is a gradually developing opacity of the lens or lens capsule. Light shining through the cornea is blocked by this opacity, and a blurred image is cast onto the retina. As a result, the brain interprets a hazy image. Cataracts commonly occur bilaterally, and each progresses independently. Exceptions are traumatic cataracts, which are usually unilateral, and congenital cataracts, which may remain stationary. Cataracts are most prevalent in people aged older than 70 as part of the aging process. The prognosis is generally good; surgery improves vision in 95% of affected people.

Causes

Causes of cataracts include:

aging (senile cataracts)
congenital disorders
genetic abnormalities
maternal rubella during the first trimester of pregnancy
traumatic cataracts
foreign body injury
complicated cataracts
uveitis
glaucoma
retinitis pigmentosa
retinal detachment
diabetes mellitus
hypoparathyroidism
myotonic dystrophy
atopic dermatitis
exposure to ionizing radiation or infrared rays
drugs that are toxic to the lens―see below
prednisone (Deltasone)
ergot alkaloids
dinitrophenol
naphthalene
phenothiazines
pilocarpine
exposure to ultraviolet rays.

TASTE PATHWAYS TO THE BRAIN

OLFACTORY PERCEPTION

The exact mechanism of olfactory perception remains unknown. The most likely theory suggests that the sticky mucus covering the olfactory cells traps airborne odorous molecules. As the molecules fit into appropriate receptors on the cell surface, the opposite end of the cell transmits an electrical impulse to the brain by way of the olfactory nerve (cranial nerve I).

Pathophysiology

Pathophysiology may vary with each form of cataract. Congenital cataracts are particularly challenging. (See Congenital cataracts .) Senile cataracts show evidence of protein aggregation, oxidative injury, and increased pigmentation in the center of the lens. In traumatic cataracts, phagocytosis of the lens or inflammation may occur when a lens ruptures. The mechanism of a complicated cataract varies with the disease process; for example, in diabetes, increased glucose in the lens causes it to absorb water.

Typically, cataract development goes through four stages:

immature: the lens is not totally opaque
mature: the lens is completely opaque and vision loss is significant
tumescent: the lens is filled with water; may lead to glaucoma
hypermature: the lens proteins deteriorate, causing peptides to leak through the lens capsule; glaucoma may develop if intraocular fluid outflow is obstructed.

CONGENITAL CATARACTS

Congenital cataracts may be caused by:

chromosomal abnormalities
metabolic disease (such as galactosemia)
intrauterine nutritional deficiencies
infection during pregnancy (such as rubella).

Congenital cataracts may not be apparent at birth unless the eye is examined by funduscope.

If the cataract is removed within a few months of birth, the infant will be able to develop proper retinal fixation and cortical visual responses. After surgery, the child is likely to favor the normal eye; the brain suppresses the poor image from the affected eye, leading to underdeveloped vision (amblyopia) in that eye. Postoperatively, in the child with bilateral cataracts, vision develops equally in both eyes.

Signs and symptoms

Possible signs and symptoms of cataracts include:

gradual painless blurring and loss of vision due to lens opacity
milky white pupil due to lens opacity
blinding glare from headlights at night due to the inefficient reflection of light rays by the opacities
poor reading vision caused by reduced clarity of images
better vision in dim light than in bright light in patients with central opacity; as pupils dilate, patients can see around the opacity.

AGE ALERT Elderly patients with reduced vision may become depressed and withdraw from social activities rather than complain about reduced vision.

Complications

Complications of cataracts include:

blindness
glaucoma.

Surgical complications may include:

loss of vitreous humor
wound dehiscence from loosening of sutures and flat anterior chamber or iris prolapse into the wound
hyphema, which is a hemorrhage into the anterior chamber of the eye
vitreous-block glaucoma
retinal detachment
infection.

Diagnosis

Diagnosis is based on the following tests:

physical examination (shining a penlight on the pupil to show the white area behind the pupil, which remains unnoticeable until the cataract is advanced)
indirect ophthalmoscopy and slit-lamp examination to show a dark area in the normally homogeneous red reflex
visual acuity test to confirm vision loss.

Treatment

Cataract treatment may include:

extracapsular cataract extraction to remove the anterior lens capsule, and cortex and intraocular lens implant in the posterior chamber, typically performed by using phacoemulsification to fragment the lens with ultrasonic vibrations, then aspirating the pieces (See Comparing methods of cataract removal .)
intracapsular cataract extraction to remove the entire lens within the intact capsule by cryoextraction (the moist lens sticks to an extremely cold metal probe for easy and safe extraction; rarely performed today)
laser surgery after an extracapsular cataract extraction to restore visual acuity when a secondary membrane forms in the posterior lens capsule that has been left intact
discission (an incision) and aspiration may still be used in children with soft cataracts
contact lenses or lens implantation after surgery to improve visual acuity, binocular vision, and depth perception.

COMPARING METHODS OF CATARACT REMOVAL

Cataracts can be removed by extracapsular or intracapsular techniques.

EXTRACAPSULAR CATARACT EXTRACTION The surgeon may use irrigation and aspiration or phacoemulsification. To irrigate and aspirate, he makes an incision at the limbus, opens the anterior lens capsule with a cystotome, and exerts pressure from below to express the lens. He then irrigates and suctions the remaining lens cortex. In phacoemulsification, he uses an ultrasonic probe to break the lens into minute particles and aspirates the particles.


INTRACAPSULAR CATARACT EXTRACTION The surgeon makes a partial incision at the superior limbus arc. He then removes the lens using specially designed forceps or a cryoprobe, which adheres to the frozen lens to facilitate its removal.