Sweat gland

Structure

Generally, sweat glands consist of a secretory unit that produces sweat, and a duct that carries the sweat away. The *secretory coil *or base, is set deep in the lower dermis and hypodermis, and the entire gland is surrounded by adipose tissue.

Each sweat gland receives several nerve fibers that branch out into bands of one or more axons and encircle the individual tubules of the secretory coil. Capillaries are also interwoven among sweat tubules.

Distribution

The number of active sweat glands varies greatly among different people, though comparisons between different areas (ex. axillae vs. groin) show the same directional changes (certain areas always have more active sweat glands while others always have fewer). According to Henry Gray's estimates, the palm has around 370 sweat glands per cm2; the back of the hand has 200 per cm2; the forehead has 175 per cm2; the breast, abdomen, and forearm have 155 per cm2; and the back and legs have 60–80 per cm2.

In the finger pads, sweat glands pores are somewhat irregularly spaced on the epidermal ridges. There are no pores between the ridges, though sweat tends to spill into them. The thick epidermis of the palms and soles causes the sweat glands to become spirally coiled.

Other animals

Non-primate mammals have eccrine sweat glands only on the palms and soles. Apocrine glands cover the rest of the body, though they are not as effective as humans' in temperature regulation (with the exception of horses'). Prosimians have a 1:20 ratio of follicles with apocrine glands versus follicles without. They have eccrine glands between hairs over most of their body (while humans have them between the hairs on their scalp).

The overall distribution of sweat glands varies among primates: the rhesus and patas monkeys have them on the chest; the squirrel monkey has them only on the palms and soles; and the stump-tailed macaque, Japanese monkey, and baboon have them over the entire body.

Domestic animals have apocrine glands at the base of each hair follicle, but eccrine glands only in foot pads and snout. Their apocrine glands, like those in humans, produce an odorless oily milky secretion evolved not to evaporate and cool but rather coat and stick to hair so odor-causing bacteria can grow on it. Eccrine glands on their foot pads, like those on palms and soles of humans, did not evolve to cool either but rather increase friction and enhance grip.

Dogs and cats have apocrine glands that are specialized in both structure and function located at the eyelids (Moll's glands), ears (ceruminous glands), anal sac, clitoral hood, and circumanal area.

History

The pores of eccrine sweat pores were first identified by the Italian physiologist Marcello Malpighi. Sweat glands themselves were first discovered by the Czech physiologist, Johannes Purkinjé in 1833. The differing densities of sweat glands in different body regions was first investigated in 1844 by the German anatomist Karl Krause. Sweat glands were first separated into kinds by the French histologist Louis-Antoine Ranvier, who separated them in 1887 regarding their type of secretion into holocrine glands (sebaceous glands) and the merocrine glands (sweat glands), the latter were then in 1917 divided into apocrine and eccrine sweat glands. In 1987, apoeccrine glands were identified.

Types

Eccrine

Main article: Eccrine sweat gland

Eccrine sweat glands are everywhere except the lips, ear canal, foreskin, glans penis, labia minora, clitoral hood, and clitoris. They are ten times smaller than apocrine sweat glands, do not extend as deeply into the dermis, and excrete directly onto the surface of the skin. The proportion of eccrine glands decreases with age.

The clear secretion produced by eccrine sweat glands is termed sweat or sensible perspiration. Sweat is mostly water, but it does contain some electrolytes, since it is derived from blood plasma. The presence of sodium chloride gives sweat a salty taste.

The total volume of sweat produced depends on the number of functional glands and the size of the surface opening. The degree of secretory activity is regulated by neural and hormonal mechanisms (men sweat more than women). When all of the eccrine sweat glands are working at maximum capacity, the rate of perspiration for a human being may exceed three liters per hour, and dangerous losses of fluids and electrolytes can occur.

Eccrine glands have three primary functions:

• Thermoregulation: sweat (through evaporation and evaporative heat loss) can lead to cooling of the surface of the skin and a reduction of body temperature.
• Excretion: eccrine sweat gland secretion can also provide a significant excretory route for water and electrolytes.
• Protection: eccrine sweat gland secretion aids in preserving the skin's acid mantle, which helps protect the skin from colonization from bacteria and other pathogenic organisms.

Apocrine

Main article: Apocrine sweat gland

Apocrine sweat glands are found in the armpit, areola (around the nipples), perineum (between the anus and genitals), in the ear, and the eyelids. The secretory portion is larger than that of eccrine glands (making them larger overall). Rather than opening directly onto the surface of the skin, apocrine glands secrete sweat into the pilary canal of the hair follicle.

Before puberty, the apocrine sweat glands are inactive; The substance secreted is thicker than eccrine sweat and provides nutrients for bacteria on the skin: the bacteria's decomposition of sweat is what creates the acrid odor. Apocrine sweat glands are most active in times of stress and sexual excitement.

In mammals (including humans), apocrine sweat contains pheromone-like compounds to attract other organisms within their species. Study of human sweat has revealed differences between men and women in apocrine secretions and bacteria.

Apoeccrine

Some human sweat glands cannot be classified as either apocrine or eccrine, having characteristics of both; such glands are termed apoeccrine. They are larger than eccrine glands, but smaller than apocrine glands. Their secretory portion has a narrow portion similar to secretory coils in eccrine glands as well as a wide section reminiscent of apocrine glands.

Apoeccrine glands, found in the armpits and perianal region, have ducts opening onto the skin surface. They are presumed to have developed in puberty from the eccrine glands, and can comprise up to 50% of all axillary glands. Apoeccrine glands secrete more sweat than both eccrine and apocrine glands, thus playing a large role in axillary sweating. Apoeccrine glands are sensitive to cholinergic activity, though they can also be activated via adrenergic stimulation. Like eccrine glands, they continuously secrete a thin, watery sweat.

Others

Specialized sweat glands, including the ceruminous glands, mammary glands, ciliary glands of the eyelids, and sweat glands of the nasal vestibulum, are modified apocrine glands. Ceruminous glands are near the ear canals, and produce cerumen (earwax) that mixes with the oil secreted from sebaceous glands. Mammary glands use apocrine secretion to produce milk.

Sweat

Sweat glands are used to regulate temperature and remove waste by secreting water, sodium salts, and nitrogenous waste (such as urea) onto the skin surface. The main electrolytes of sweat are sodium and chloride, though the amount is small enough to make sweat hypotonic at the skin surface. Eccrine sweat is clear, odorless, and is composed of 98–99% water; it also contains NaCl, fatty acids, lactic acid, citric acid, ascorbic acid, urea, and uric acid. Its pH ranges from 4 to 6.8. On the other hand, the apocrine sweat has a pH of 6 to 7.5; it contains water, proteins, carbohydrate waste material, lipids, and steroids. The sweat is oily, cloudy, viscous, and originally odorless; it gains odor upon decomposition by bacteria. Because both apocrine glands and sebaceous glands open into the hair follicle, apocrine sweat is mixed with sebum.

Mechanism

Both apocrine and eccrine sweat glands use merocrine secretion, where vesicles in the gland release sweat via exocytosis, leaving the entire cell intact. In both apocrine and eccrine sweat glands, the sweat is originally produced in the gland's coil, where it is isotonic with the blood plasma there. When the rate of sweating is low, salt is conserved and reabsorbed by the gland's duct; high sweat rates, on the other hand, lead to less salt reabsorption and allow more water to evaporate on the skin (via osmosis) to increase evaporative cooling.

Secretion of sweat occurs when the myoepithelial cell cells surrounding the secretory glands contract. Eccrine sweat increases the rate of bacterial growth and volatilizes the odor compounds of apocrine sweat, strengthening the latter's acrid smell.

Normally, only a certain number of sweat glands are actively producing sweat. When stimuli call for more sweating, more sweat glands are activated, with each then producing more sweat.

Stimuli

Thermal

Both eccrine and apocrine sweat glands participate in thermoregulatory sweating, which is directly controlled by the hypothalamus. Thermal sweating is stimulated by a combination of internal body temperature and mean skin temperature. In eccrine sweat glands, stimulation occurs via activation by acetylcholine, which binds to the gland's muscarinic receptors.

Emotional

Emotional sweating is stimulated by stress, anxiety, fear, and pain; it is independent of ambient temperature. Acetylcholine acts on the eccrine glands and adrenaline acts on both eccrine and apocrine glands to produce sweat. Emotional sweating can occur anywhere, though it is most evident on the palms, soles of the feet, and axillary regions. Sweating on the palms and soles is thought to have evolved as a fleeing reaction in mammals: it increases friction and prevents slipping when running or climbing in stressful situations.

Gustatory

Gustatory sweating refers to thermal sweating induced by the ingestion of food. The increase in metabolism caused by ingestion raises body temperature, leading to thermal sweating. Hot and spicy foods also lead to mild gustatory sweating in the face, scalp and neck: capsaicin (the compound that makes spicy food taste "hot"), binds to receptors in the mouth that detect warmth. The increased stimulation of such receptors induces a thermoregulatory response.

Antiperspirant

Unlike deodorant, which simply reduces axillary odor without affecting body functions, antiperspirant reduces both eccrine and apocrine sweating. Antiperspirants, which are classified as drugs, cause proteins to precipitate and mechanically block eccrine (and sometimes apocrine) sweat ducts. The metal salts found in antiperspirants alters the keratin fibrils in the ducts; the ducts then close and form a "horny plug". The main active ingredients in modern antiperspirants are aluminum chloride, aluminum chlorohydrate, aluminum zirconium chlorohydrate, and buffered aluminum sulfate.

On apocrine glands, antiperspirants also contain antibacterial agents such as trichlorocarbanilide, hexamethylene tetramine, and zinc ricinoleate. The salts are dissolved in ethanol and mixed with essential oils high in eugenol and thymol (such as thyme and clove oils). Antiperspirants may also contain levomethamphetamine.

Pathology

Some diseases of the sweat glands include:

; Fox-Fordyce disease : The apocrine sweat glands become inflamed, causing a persistent, itchy rash, usually in the axillae and pubic areas. ; Frey's Syndrome: If the auriculotemporal nerve is damaged (most often as a result of a Parotidectomy), excess sweat can be produced in the rear of the cheek area (just below the ear) in response to stimuli that cause salivation. ; Heatstroke: When the eccrine glands become exhausted and unable to secrete sweat. Heatstroke can lead to fatal hyperpyrexia (extreme rise in body temperature). ; Hidradenitis suppurativa: Occurs when the skin and sweat glands become inflamed with swollen lumps. These are typically painful and break open, releasing fluid or pus. The most commonly affected areas are the underarms, under the breasts, and the groin. ; Hyperhidrosis: (also known as polyhidrosis or sudorrhea) is a pathological, excessive sweating that can be either generalized or localized (focal hyperhidrosis); focal hyperhidrosis occurs most often on the palms, soles, face, scalp and axillae. Hyperhidrosis is usually brought on by emotional or thermal stress, but it can also occur or with little to no stimulus. Local (or asymmetrical) hyperhidrosis is said to be caused by problems in the sympathetic nervous system: either lesions or nerve inflammation. Hyperhidrosis can also be caused by trench foot or encephalitis. ; Milaria rubra: Also called prickly heat. Milaria rubra is the rupture of sweat glands and migration of sweat to other tissues. In hot environments, the skin's horny layer can expand due to sweat retention, blocking the ducts of eccrine sweat glands. The glands, still stimulated by high temperatures, continues to secrete. Sweat builds up in the duct, causing enough pressure to rupture the duct where it meets the epidermis. Sweat also escapes the duct to adjacent tissues (a process called milaria). Hypohydrosis then follows milaria (postmiliarial hypohydrosis). ; Osmidrosis: Often called bromhidrosis, especially in combination with hyperhidrosis. Osmohidrosis is excessive odor from apocrine sweat glands (which are overactive in the axillae). Osmidrosis is thought to be caused by changes in the apocrine gland structure rather than changes in the bacteria that acts on sweat.

Tumors

Sweat gland tumors include:

• Acrospiroma
• Aggressive digital papillary adenocarcinoma
• Apocrine gland carcinoma
• Ceruminoma
• Cutaneous myoepithelioma
• Cylindroma
• Eccrine carcinoma
• Hidradenoma papilliferum
• Hidrocystoma
• Microcystic adnexal carcinoma
• Mucinous carcinoma
• Papillary eccrine adenoma
• Poroma
• Porocarcinoma
• Syringadenoma papilliferum
• Syringofibroadenoma
• Syringoma

Adenolipomas are lipomas associated with eccrine sweat glands.

As signs in other illnesses

Many diseases cause sweat gland dysfunction:

• Acromegaly, a result of excess growth hormone, causes the size of sweat glands increase, which leads to thicker skin.
• Aquagenic wrinkling of the palms, in which white papules develop on the palms after exposure to water, can sometimes come with abnormal aquaporin 5 in the sweat glands.
• Cystic fibrosis can be diagnosed by a sweat test, as the disease causes the sweat glands ducts to reabsorb less chloride, leading to higher concentrations of chloride in the secreted sweat.
• Ectodermal dysplasia can present a lack of sweat glands.
• Fabry disease, characterized by excess globotriaosylceramide (GL3), causes a decrease in sweat gland function due to GL3 deposits in the eccrine glands.
• GM1 gangliosidoses, characterized by abnormal lipid storage, leads to vacuolization in eccrine sweat gland cells.
• Hunter syndrome can include metachromin granules and mucin in the cytoplasm of the eccrine sweat gland cells.
• Hypothyroidism's low levels of thyroid hormone lead to decreased secretions from sweat glands; the result is dry, coarse skin.
• Kearns–Sayre syndrome, a disease of the mitochondria, involves abnormal mitochondria in eccrine sweat glands.
• Lafora disease is a rare genetic disorder marked by the presence of abnormal polyglucosan deposits. These "Lafora bodies" appear in the ducts of sweat glands, as well as the myoepithelial cells of apocrine glands.
• Lichen striatus, a self-limited eruption of small, slightly scaly papules, includes a lymphoid infiltrate around eccrine sweat glands.
• Metachromatic leukodystrophy, a lysosomal storage disease, leads to the accumulation of lipopigments and lysosomal residual bodies in the epithelial cells of sweat glands.
• Neuronal ceroid lipofuscinosis causes abnormal deposits of lipopigment in sweat gland epithelial cells (among other places).
• Neutral lipid storage disease includes abnormal lipid deposits in cells, including those of the sweat gland.
• Niemann-Pick disease type C, another lipid storage disease, includes abnormal lipid storage in sweat glands.
• Schindler disease causes cytoplasmic vacuoles that appear to be empty or contain filamentous material to manifest in eccrine sweat gland cells.
• Small fiber peripheral neuropathy can damage the nerves that control the sweat glands. The sweat gland nerve fiber density test can diagnose this condition.

Gallery

Notes

References

References

1. {{Terminologia Anatomica. A16.0.00.029
2. "sudoriferous".
3. Bolognia, Jorizzo, Schaffer. (2012). "Dermatology. Structure and Function of Eccrine, Apocrine and Sebaceous Glands". Elsevier Saunders.
4. (2013). "Regional variations in transepidermal water loss, eccrine sweat gland density, sweat secretion rates and electrolyte composition in resting and exercising humans". Extreme Physiology & Medicine.
5. Spearman, Richard Ian Campbell. (1973). "The Integument: A Textbook For Skin Biology". CUP Archive.
6. (April 2003). "Integrated principles of zoology". McGraw-Hill.
7. Marples, Mary J.. (1965). "The ecology of the human skin". Thomas.
8. (1 January 2000). "Dermatology". Springer Berlin Heidelberg.
9. "Human Pheromones". Macalaster College.
10. (2007). "Therapeutic Uses of Botulinum Toxin". Humana Press.
11. Böni, R.. (2002). "Current Problems in Dermatology". KARGER.
12. Kreyden, Oliver Philip. (2002). "Hyperhidrosis and Botulinum Toxin in Dermatology: 18 Tables". Karger Publishers.
13. McMurtrie, Hogin. (28 November 2006). "McMurtrie's Human Anatomy Coloring Book: A Systemic Approach to the Study of the Human Body: Thirteen Systems". Sterling Publishing Company, Inc..
14. Frontera, Walter R.. (2007). "Clinical Sports Medicine: Medical Management and Rehabilitation". Elsevier Health Sciences.
15. "Apocrine Sweat Glands".
16. (2007). "disease". Saunders.
17. (2006). "Frey's Syndrome". New England Journal of Medicine.
18. (January 2022). "Molecular pathology of skin adnexal tumours". Histopathology.
19. (29 July 2011). "Pediatrics for Medical Students". Lippincott Williams & Wilkins.
20. "Ectodermal dysplasia". U.S. National Library of Medicine.
21. Elstein, Deborah. (1 January 2010). "Fabry Disease". Springer.
22. Martin, J. J.. (31 January 1984). "Visual System in Myelin Disorders". Springer.
23. (November 1992). "Diagnosis by axilla skin biopsy in an early case of Lafora's disease". Journal of Neurology, Neurosurgery, and Psychiatry.
24. (1990). "Lipofuscin and Ceroid Pigments".
25. (August 2001). "Diagnostic value of electron microscopy in a case of juvenile neuronal ceroid lipofuscinosis". Ultrastructural Pathology.
26. (19 December 1975). "Niemann-Pick disease (Crocker's type C): A histological study of the distribution and qualitative differences for the storage process". Acta Neuropathologica.
27. (1 January 2010). "Functional Ultrastructure: Atlas of Tissue Biology and Pathology". Springer.
28. "Sweat Gland Nerve Fiber Density". Therapath.
29. (2005). "Histologic Diagnosis of Inflammatory Skin Diseases An Algorithmic Method Based on Pattern Analysis". Ardor Scribendi.
30. (2007). "apocrine sweat gland". Houghton Mifflin Company.
31. "skin disease". Encyclopædia Britannica, Inc..
32. "hyperhidrosis". Encyclopædia Britannica, Inc..
33. (1970). "Responses of the burro to desert heat stress". Journal of Applied Physiology.
34. Caceci, Thomas. "Integument I: Skin". Virginia–Maryland Regional College of Veterinary Medicine.
35. (2007). "apocrine sweat gland". Saunders.
36. Draelos, Zoe Diana. (2010). "Preventive Dermatology". Springer.
37. Gray, Henry. (1918). "Anatomy of the Human Body". Lea & Febiger.
38. (November 1994). "Innervation and vasculature of human sweat glands: an immunohistochemistry-laser scanning confocal fluorescence microscopy study". The Journal of Neuroscience.
39. "Cutaneous Apocrine Gland Tumors". The Merck Veterinary Manual.
40. (2009). "apocrine sweat gland". Elsevier.
41. Neas, John F.. "Embryology Atlas". Benjamin Cumings.
42. Randall, Walter C.. (September 1946). "Quantitation and Regional Distribution of Sweat Glands in Man 1". Journal of Clinical Investigation.
43. (2003). "sweat gland". Saunders.
44. (2003). "Textbook of Small Animal Surgery". Elsevier Health Sciences.
45. Van Lommel, Alfons T. L.. (2003). "From Cells to Organs: A Histology Textbook and Atlas". Springer.