The Skin, the Eye and the Ear

6.1a The physiology of the skin, the eye and the ear

This section focuses on the physiology of three of the sensory organs of the body: the skin, the eye and the ear.

The skin is considered as a physiological system in its own right, also known as the integumentary system (a term derived from the word integument, which means skin). In conventional practice, diseases of the skin are managed within the medical specialty of dermatology.

The eye and the ear are, technically speaking, complex sensory organs that form part of the nervous system. However, in conventional practice the diseases of the eye and the ear are managed within distinct specialties. Eye diseases are managed within the medical specialty of ophthalmology, and ear diseases are managed within the surgical specialty of otorhinolaryngology (meaning the study of the ear, nose and throat). This specialty embraces diseases that relate to two overlapping systems: the nervous system and the respiratory system.

In this section the diseases of the skin, the eye and the ear are considered separately, as if each is an individual system.

The physiology of the skin (the integumentary system)

The structure of the skin

The skin is composed of two thin layers known as the epidermis and the dermis. Throughout the body these two layers rest on a deeper layer of subcutaneous fat. The fascia, considered part of the musculoskeletal system, is the silvery fibrous connective tissue layer that underlies the subcutaneous fat and separates it from underlying muscles and bones. This is the glistening surface tissue that is seen surrounding the carcass when the skin of animals, for example, has been removed in the process of food production.

The hair follicles are specialized tubules of germinative epithelium that generate the cells and the protein keratin, which form the strand of hair. A hair develops at the base of a hair follicle, where numerous keratin-containing skin cells are compacted together. As the skin cells die, the keratin remains and this is pushed out of the follicle to form a single hair. The arrectores pilorum muscles are tiny smooth muscle structures that attach the base of a hair follicle to connective tissue fibers in the dermis. When the arrectores pilorum muscles contract, the hairs become erect and stand on end.

The nails are also composed of keratinized dead skin cells. They grow out of the nail bed, which is an area of tissue lined with the rapidly dividing epidermal skin cells of the germinative layer.

The dermis is also richly supplied with nerve endings and blood capillaries. A healthy blood supply gives the skin a reddish pink glow. Bile salts (yellow/green) from the liver and carotenes (red/yellow) obtained from the diet also contribute to skin color.

The role of the skin in the control of temperature

It is vital that the body maintains a steady temperature because the complex metabolic processes of the body work optimally within a very narrow temperature range. If the temperature rises, the metabolic processes speed up, and if it drops, they slow down. If the metabolic rate becomes too fast or slow, the fine balance between the different chemical reactions in the body can be lost and ill health will result, as evidenced in someone suffering either from a prolonged high fever or from hypothermia.

The skin plays only a minor role in heat production. The main heat-producing tissues are the skeletal muscles, the liver and the digestive organs. Nevertheless, the contraction of the arrectores pilorum muscles in the skin does also generate a certain amount of heat. These tiny but numerous muscles also cause the body hair to stand on end, a response that will tend to conserve heat in a furry animal.

However, the most important physiological mechanism for heat conservation in the human is the constriction of the capillary network in the skin. This is mediated by the sympathetic nervous system. When vasoconstriction occurs, the blood is held deep in the body, and the skin will start to feel cold, and look pale or even blue. A similar response occurs in acutely frightening or stressful situations.

The role of the skin in the loss of heat is also very important. By far the largest proportion of body heat is lost from the skin. This heat loss is minimized by vasoconstriction and the erection of body hair. Body fat and layers of clothing also reduce this loss of body heat. In contrast, the loss of heat is increased by the physiological responses of vasodilatation and sweating.

Dilatation of the blood vessels in the skin raises the surface temperature of the skin, and so heat loss to the outside environment is increased. Vasodilatation is mediated by the parasympathetic nervous system, and is controlled by the hypothalamus. Sweating, which occurs when the body temperature rises by a fraction of a degree, causes the skin to become moist. Moisture requires energy (heat) to evaporate, and thus in hot, dry weather the evaporation of the sweat has a cooling effect.

The cones are sensitive to different colors of light, but do not respond to light of low intensity. This is why it is not possible to distinguish colors in a darkened room.

The blind spot (optic disc) is the point at which all these nerve fibers converge to form the optic nerve. It is a tiny area of the retina that is devoid of rods and cones. Therefore, it is literally a blind spot, as it cannot respond to the light that falls on it. The macula lutea (yellow spot) is the region of the retina that holds the densest concentration of sensory cell bodies, and is the region that responds to light coming from the center of the field of vision. It is at the macula where fine detail and bright clear colors are distinguished.

The eye has to make two other adjustments to enable close vision. First, constriction of the pupils takes place. This reaction enables only a thin beam of light to pass through the lens. This aids the focusing of the image because a narrow beam of light is easier to focus. This principle is used in a pinhole camera. Second, the eyeballs converge inwards when viewing a close object. When extreme, convergence causes the viewer to appear cross-eyed. Convergence allows the image of the object being viewed to fall onto the center of each retina. Without convergence the viewer would experience double vision.

In distance vision (objects more than 6 meters away) constriction of the pupils and convergence are not necessary, and also, as mentioned, the ciliary muscle becomes fully relaxed. It follows from this that the most restful aspect of vision is distance vision (e.g. when gazing on a countryside scene), as none of the three adjustments for close vision is required.

Each eye receives slightly different images, and the differences are more pronounced for close objects. The visual center of the occipital lobe of the cerebrum is the location for the interpretation of the two slightly different images that come from each retina, thereby giving the viewer an appreciation of the distance of a viewed object. The ability to visually appreciate distances is called stereoscopic vision.

The extraocular muscles and accessory organs of the eye

From the perspective of the development of the ear in the embryo, the link that the middle ear has with the respiratory system becomes clearer. In the embryo, the middle ear forms from an upward pouching of the nasopharynx, whereas the inner ear develops outwards from the primitive nervous tissue. The middle ear and the interlinked mastoid air cells are lined with ciliated respiratory epithelium. The air and the surface microbes that they contain are in direct communication with the air and the surface microbes in the nasopharynx. This explains why respiratory infections can so readily involve the middle ear and lead to deafness and earache.

If the cause of the rash is believed to be infective, the rash, or its discharge, may be swabbed, and the swab sent for microbiological analysis.

Examination of skin scrapings and nail clippings

Skin scrapings and nail clippings are samples that can be obtained painlessly. Microbiological examination of these samples can reveal fungal infection and infestation by scabies mites.

Examination of a skin biopsy

Skin biopsy is a very useful technique in the diagnosis of skin disorders. If the problem is small and localized (e.g. a worrying mole) then a biopsy can both treat the condition by removing it, and also generate a sample for examination. This approach, known as excisional biopsy, is ideally performed in such a way that the diseased area is completely removed, with no portion left remaining. A wide excision may be required to ensure full removal of a suspected skin cancer such as a melanoma. If only a small ellipse of skin is removed, the wound can be sutured so that the resulting scar is almost invisible. However, a wide excision may require a graft of skin from another part of the body (usually the outer thigh) to permit full healing of the area from which the section of skin was removed.

If the skin rash is more extensive, an incisional biopsy can be performed to remove a long ellipse of skin from the edge of the rash. As is the case with excisional biopsy, the resulting wound will require closure by sutures. Examination of the incisional biopsy should reveal both normal and affected skin, and thus allow comparison of the two.

A punch biopsy removes a fine column of affected skin by means of a tubular sampling blade. This leaves a tiny hole, which may require a single stitch to stem bleeding.

Patch or prick testing for allergies

Patch testing is used to test for sensitivity to various allergens that can result in contact dermatitis (contact eczema). The test involves holding diluted samples of a battery of common allergens against a flat area of skin (usually of the back) for up to 48 hours by means of an adhesive strip of patches. The development of a thickened red area of skin under one of the patches is indicative of sensitivity to that allergen. Allergens that commonly cause positive reactions in the patch test include nickel, rubber and colophony (a common constituent of sticking plasters).

Patch testing is a specific test for contact eczema. The aim is to exclude a delayed allergic reaction (type 4 hypersensitivity) that manifests in dermatitis/eczema (redness, localized swelling and itch) after two days or more of exposure to the allergen.

Prick or scratch tests are allergy tests that are aimed at excluding the more immediate allergic reaction that leads to urticaria, edema and asthma (type 1 hypersensitivity). In prick or scratch testing, a diluted sample of allergen is allowed to penetrate under the epidermis via the prick or the scratch, and the skin is examined for the appearance of a characteristic wheal. This reaction tends to develop within seconds to minutes if the test is positive. Allergens that are commonly found to lead to positive reactions in prick or scratch testing include animal dandruff, pollen and dietary constituents such as egg and nuts.

Physical examination to exclude underlying medical conditions

Dermatologists have a thorough grounding in clinical medicine. If a rash is found that indicates a possible medical condition as the underlying cause, the dermatologist will proceed to examine the patient for other features of that disease.

Blood tests to exclude underlying medical conditions

Blood tests may be ordered to exclude a suspected underlying medical diagnosis. For example, the blood may be tested for autoantibodies if an autoimmune condition such as systemic lupus erythematosus (SLE) is suspected as the cause of the rash.

Investigation of disorders of the eye

Eye disorders are often first picked up during examination by an optometrist (also known as optician). The optometrist routinely tests for clear, unrestricted sight by means of tests for visual acuity, the integrity of the visual fields, color vision and eye movements. The optometrist will also examine the internal structure of the eye by means of a hand-held ophthalmoscope. The optometrist may also check the visual fields and also the internal pressure of the eye by means of tonometry (see below), and also take a high-resolution photograph of the retina to check for signs of disease.

A hospital ophthalmologist will also perform these investigations, but has access to other powerful tools of examination, including the slit lamp, fluorescein angiography and imaging tests.

Examination of visual acuity

Acuity can be tested simply by means of the Snellen chart, probably the most familiar test associated with the optometrist. The Snellen chart consists of rows of letters (or pictures for those patients who are unable to read) of progressively decreasing height. The patient is placed at a fixed distance from the chart and is asked, for each eye in turn, what is the smallest size of letter that they can read with confidence. This is then compared with what is known to be a normal and healthy level of acuity.

The optometrist will then proceed to explore to what extent correcting the vision by means of a lens will improve the acuity. The degree to which a lens can correct the vision depends on the exact cause of the impairment in acuity. If the impairment is due totally to a problem in the focusing of the image by the lens in the eye, a perfectly suited lens should be able to offer the patient a return to normal visual acuity. If, however, the problem is a result of, for example, cataract or retinal damage, a lens may not be able to improve vision very much.

Examination of the visual fields

The visual field is the term used to describe the width and height of the view from each eye when the person is looking straight ahead. In health, even when looking straight ahead, movement that occurs almost to the side of the head can be detected because of the extent of the visual field. The visual field is less extensive to the medial side of the eye because the bridge of the nose gets in the way. However, objects can be seen when they are held almost at a right angle to the direction of the gaze on the lateral side of the eye.

There is a small area of the visual field, slightly lateral to the area on which the eye focuses, in which the image of the object becomes less distinct. This area is the blind spot, and corresponds to the area on the retina overlying the origin of the optic nerve, known as the optic disc.

Mapping of the visual fields and the blind spot is performed by means of asking the patient to register when they have seen tiny lights on a screen. This test can reveal restrictions that are characteristic of certain diseases, including chronic simple glaucoma and damage to the optic nerve chiasm by pituitary tumors.

Examination of color vision

Color blindness can be diagnosed by means of pictures that are made up of many dots of different colors. Color blindness will prevent an observer from distinguishing certain aspects of the pictures.

Examination of the eye movements

The eye movements are assessed by asking the patient to follow a moving object in the field of vision while keeping the head still. During the test the examiner watches for divergence or convergence of the eyes, and questions the patient about any episodes of double vision. This examination can reveal the presence of a squint (strabismus).

Examination of the structure of the eye by ophthalmoscope

The ophthalmoscope is a hand-held instrument through which the examining practitioner can focus on the various internal structures of the eye, ideally with the patient in a darkened room. The ophthalmoscope should allow inspection of the cornea, the iris and lens, the vitreous and aqueous humors, the pattern of vessels on the retina, and the optic nerve head (the disc).

Ophthalmoscopic examination of the retina is the only means by which a doctor can make a direct, but non-invasive, inspection of part of the nervous system. In addition to visualization of the optic nerve head, examination with an ophthalmoscope can reveal the characteristic changes that occur in a wide range of eye diseases, including cataract, vitreous detachment, retinal detachment, diabetic retinopathy and the changes that result from high blood pressure.

Examination of the structure of the eye by means of the slit lamp

The slit lamp (or bio-microscope) allows the examining practitioner to obtain a high-quality view of the external and internal structures of the eye. Prior to a slit lamp examination, a few drops of a mydriatic (a drug that causes widening of the pupils) are placed into the patient’s eyes. This can have the effect of causing blurred vision until the drug wears off, and so the patient is advised not to drive until this side effect has faded. Once the mydriatic has taken effect, the patient sits in a chair in a darkened room and, to ensure immobility, places their head against a headrest attached to the slit lamp. The magnifying lens of the slit lamp can then be focused on the various structures of each eye in turn. A fluorescent dye called fluorescein can be instilled into the eye to reveal scratches and ulcers on the corneal surface. These damaged areas fill up with fluorescein, and will fluoresce green when viewed through the slit lamp.

Examination of the intraocular pressure by means of the slit lamp and tonometry

The intraocular pressure can be assessed by means of a sensitive pressure gauge called a tonometer. The measurement of the pressure can be made during a slit lamp examination during which the tonometer is held against each of the corneas in turn. This non-invasive examination, which takes a matter of seconds, is uncomfortable but not painful.

Examination of the blood flow to the retina using fluorescein angiography

Fluorescein angiography is a more invasive technique, which involves the injection of fluorescein into the circulation. The retina is then illuminated with blue light, which causes the fluorescein flowing through the retinal arteries to fluoresce with a bright green light. A photograph of the fluorescing vessels is then taken by means of a specialized camera. This examination can reveal more detail about the damage to the retinal circulation that can result from conditions such as chronic diabetes mellitus or atherosclerosis.

Imaging tests including ultrasound, CT and MRI scans

The ultrasound scan is a frequently used tool in ophthalmology to assess the health of the vitreous humor, the retina and the posterior coats of the eye. It is particularly useful when a cataract in the lens prevents slit lamp examination of the structures behind the lens.

CT and MRI are of value in assessing the shape of the orbit and the pathways of the optic nerves as they pass from the optic nerve head to the brain.

Electrophysiological tests

Specialized electrophysiological tests can be used to assess the responses of the nerves in the retina, optic nerve pathways and the visual cortex (at the back of the brain) to visual stimuli (such as flashing lights) presented to the eyes.

Culture and examination of samples taken by swab from the eye

Infections of the conjunctiva can be investigated by means of culture and examination of samples taken by means of swab from the conjunctival secretions.

Investigation of disorders of the ear

Visual inspection of the external ear and eardrum

Speech audiometry is a variant of audiometry in which a recorded word list, rather than pure tones, is presented to each ear.

Testing of the flexibility of the middle ear by means of impedance tympanometry

Impedance tympanometry is a less patient-dependent non-invasive test which assesses objectively the degree to which the eardrum reflects the pure tones with which it is presented by an audiometer. This is a very useful test in assessing the degree to which glue ear is compromising hearing in babies and young children.

Electrophysiological tests (electric response audiometry)

The nerve responses to a sound wave that reaches the inner ear can be tested by means of a similar method to that used to test the nerve responses in the visual pathways. In electric response audiometry, a sound stimulus is applied to the outer ear. The response to this stimulus in the nerves that originate in the inner ear, and which travel via the auditory nerve to the auditory cortex in the brain, can be assessed by means of sensory electrodes placed against the bones of the middle ear, the base of the neck and the skull.

Because this non-invasive technique requires no response from the patient, it can be used in babies and young children, and also, by dint of its objectivity, to provide evidence in cases involving litigation for industrial deafness.

6.1c Diseases of the skin

The skin is able to react rapidly to a very wide range of environmental and internal factors, and in some cases this leads to disease. Known triggers for skin disease include genetic susceptibility, degeneration from aging, infectious agents, physical trauma, allergic reactions, light, heat, cold, psychological stress and self-harm. However, in many cases of skin disease the underlying cause is never clarified. Any one trigger can lead to a diverse range of manifestations of skin disease and it is often not very clear exactly why one person under stress develops itch and another psoriasis, or why antibiotics in one person will cause a painful blistering reaction and in another a rash of red spots.

From a more holistic perspective, it is generally appreciated that the skin, as it is the most superficial organ, might readily express symptoms and signs as an indication of a deeper imbalance. These would be the result of a combination of both internal and external factors, which would begin to explain the diversity of skin diseases.

The aim of this section is to introduce the wide range of ways in which the skin can manifest symptoms, and also the common treatment approaches used in dermatology. This section is split into two parts, which are designed to be studied in separate study sessions.

Generalized diseases in which the skin can be involved include peripheral vascular disease, diabetes mellitus, thyroid disease, Cushing’s syndrome, Addison’s disease, rheumatoid arthritis, chronic liver disease and a wide range of infectious diseases. As all these diseases have already been described in some length in earlier sections, their skin manifestations (with the exception of some of the important infectious skin diseases) are not mentioned further here.

The conditions discussed in this section are:

Part I: Skin infections, acne and scaling conditions

•Bacterial infections:

–cellulitis and erysipelas

–boils, abscesses and folliculitis

–impetigo

–scalded skin syndrome

–leprosy

•Viral infections:

–warts

–molluscum contagiosum

–rashes in generalized viral infections

–herpes simplex infections

–herpes zoster infections

–hand, foot and mouth disease

•Fungal infections:

–tinea (athlete’s foot and ringworm)

–candidal (yeast) infections

–pityriasis (tinea) versicolor

•Skin infestations:

–scabies

–head, pubic and body lice

–fleas and papular urticaria

•Acne:

–acne vulgaris

–acne rosacea

–exogenous eczema

–endogenous eczema

•Psoriasis:

–plaque psoriasis

–scalp psoriasis

–guttate psoriasis.

•Erythroderma

Part II: Moles and tumors, connective tissue disorders and other common skin conditions

•Moles and other nevi:

–freckles and melanocytic nevi (common moles)

–stork marks and blue spots in newborns

–strawberry nevi

–port-wine stains

–Campbell de Morgan red spots

–spider nevi

•Skin tumors – benign lumps:

–seborrheic warts (senile keratoses)

–skin tags

–dermatofibromata

–epidermal cysts (sebaoceous cysts), lipomas and milia

–keloid scars

•Skin tumors – malignant skin tumors:

–solar keratoses

–basal cell carcinoma (BCC)

–squamous cell carcinoma (SCC) and Bowen’s disease

–Paget’s disease of the nipple

–malignant melanoma

–Kaposi’s sarcoma

–lymphoma and the skin

•Connective tissue disorders:

–systemic lupus erythematosus (SLE) and discoid lupus erythematosus (DLE)

–dermatomyositis

–scleroderma and morphea

•Disorders of hair growth:

–excessive hair growth

–abnormal scalp hair loss

•Other common skin conditions:

–urticaria and angio-edema

–prickly heat (miliaria)

–polymorphic light eruption (PLE)

–chilblains

–xanthelasmata and xanthomata

–lichen planus

–pityriasis rosea

–pruritus

–skin ulcers

–reactions to drugs.

Part I: Skin infections, acne and scaling conditions

Bacterial infections

CELLULITIS AND ERYSIPELAS

Cellulitis is a rapidly spreading streptococcal or staphylococcal infection of the subcutaneous and deeper tissues. Erysipelas is a term given to the most superficial forms of cellulitis, but clinically there is no clear distinction between the two conditions. Both manifest as a spreading redness and swelling of the skin and underlying tissues, and are accompanied by fever, malaise and enlarged local lymph nodes.