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European Journal of Applied Physiology
Published in: European Journal of Applied Physiology 4/2020

Open Access 01-04-2020 | Cytokines | Invited Review

Physiological mechanisms determining eccrine sweat composition

Authors: Lindsay B. Baker, Anthony S. Wolfe

Published in: European Journal of Applied Physiology | Issue 4/2020

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Abstract

Purpose

The purpose of this paper is to review the physiological mechanisms determining eccrine sweat composition to assess the utility of sweat as a proxy for blood or as a potential biomarker of human health or nutritional/physiological status.

Methods

This narrative review includes the major sweat electrolytes (sodium, chloride, and potassium), other micronutrients (e.g., calcium, magnesium, iron, copper, zinc, vitamins), metabolites (e.g., glucose, lactate, ammonia, urea, bicarbonate, amino acids, ethanol), and other compounds (e.g., cytokines and cortisol).

Results

Ion membrane transport mechanisms for sodium and chloride are well established, but the mechanisms of secretion and/or reabsorption for most other sweat solutes are still equivocal. Correlations between sweat and blood have not been established for most constituents, with perhaps the exception of ethanol. With respect to sweat diagnostics, it is well accepted that elevated sweat sodium and chloride is a useful screening tool for cystic fibrosis. However, sweat electrolyte concentrations are not predictive of hydration status or sweating rate. Sweat metabolite concentrations are not a reliable biomarker for exercise intensity or other physiological stressors. To date, glucose, cytokine, and cortisol research is too limited to suggest that sweat is a useful surrogate for blood.

Conclusion

Final sweat composition is not only influenced by extracellular solute concentrations, but also mechanisms of secretion and/or reabsorption, sweat flow rate, byproducts of sweat gland metabolism, skin surface contamination, and sebum secretions, among other factors related to methodology. Future research that accounts for these confounding factors is needed to address the existing gaps in the literature.
Appendix
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Literature
Adams WS, Leslie A, Levin MH (1950) The dermal loss of iron. Proc Soc Exp Biol Med 74:46–48PubMed
Ahmed AA, Nordlind K, Schultzberg M, Liden S (1996) Proinflammatory cytokines and their corresponding receptor proteins in eccrine sweat glands in normal and cutaneous leishmaniasis human skin. An immunohistochemical study. Exp Dermatol 5:230–235PubMed
Allan JR, Wilson CG (1971) Influence of acclimatization on sweat sodium concentration. J Appl Physiol 30:708–712PubMed
Allsopp AJ, Sutherland R, Wood P, Wootton SA (1998) The effect of sodium balance on sweat sodium secretion and plasma aldosterone concentration. Eur J Appl Physiol Occup Physiol 78:516–521PubMed
al-Tamer YY, Hadi EA, Alsss B II (1997) Sweat urea, uric acid and creatinine concentrations in uraemic patients. Urol Res 25:337–340PubMed
Amatruda TT, Welt LG (1953) Secretion of electrolytes in thermal sweat. J Appl Physiol 5:759–772
Armstrong LE, Costill DL, Fink WJ, Bassett D, Hargreaves M, Nishibata I, King DS (1985a) Effects of dietary sodium on body and muscle potassium content during heat acclimation. Eur J Appl Physiol Occup Physiol 54:391–397PubMed
Armstrong LE, Hubbard RW, Szlyk PC, Matthew WT, Sils IV (1985b) Voluntary dehydration and electrolyte losses during prolonged exercise in the heat. Aviat Sp Environ Med 56:765–770
Armstrong LE, Hubbard RW, Jones BH, Daniels JJ (1986) Preparing Alberto Salazar for the heat of the Olympic marathon. Physician Sports Med 14:73–81
Aruoma OI, Reilly T, MacLaren D, Halliwell B (1988) Iron, copper and zinc concentrations in human sweat and plasma; the effect of exercise. Clin Chim Acta Int J Clin Chem 177:81–87
Baker LB, Stofan JR, Lukaski HC, Horswill CA (2011) Exercise-induced trace mineral element concentration in regional versus whole-body wash-down sweat. Int J Sport Nutr Exerc Metab 21:233–239PubMed
Bergeron MF (2003) Heat cramps: fluid and electrolyte challenges during tennis in the heat. J Sci Med Sport Sports Med Aust 6:19–27
Boehm KD, Yun JK, Garner C, Strohl KP, Elmets CA (1994) In situ detection of cytokine messenger RNAs in the eccrine sweat gland of normal human skin. Lymph Cytok Res 13:9–13
Boisvert P, Candas V (1994) Validity of the Wescor's sweat conductivity analyzer for the assessment of sweat electrolyte concentrations. Eur J Appl Physiol Occup Physiol 69:176–178PubMed
Bovell DL, Quinton P (2002) The immunocytochemical localisation of anion exchangers (AE) in the reabsorptive duct of the human eccrine sweat gland. J Physiol 544:107P
Boysen TC, Yanagawa S, Sato F, Sato K (1984) A modified anaerobic method of sweat collection. J Appl Physiol 56:1302–1307PubMed
Briggman JV, Tashian RE, Spicer SS (1983) Immunohistochemical localization of carbonic anhydrase I and II in eccrine sweat glands from control subjects and patients with cystic fibrosis. Am J Pathol 112:250–257PubMedPubMedCentral
Brown DJ (1985) The pharmacokinetics of alcohol excretion in human perspiration. Methods Find Exp Clin Pharmacol 7:539–544PubMed
Brown WK, Sargent F 2nd (1965) Hidromeiosis. Arch Environ Health 11:442–453PubMed
Brune M, Magnusson B, Persson H, Hallberg L (1986) Iron losses in sweat. Am J Clin Nutr 43:438–443PubMed
Brunner H (1906) Über Glykogen in der gesunden und kranken. Haut Verh Dtsch derm Gesellschaft 9:521–535
Brusilow SW, Ikai K (1968) Urocanic acid in sweat: an artifact of elution from the epidermis. Science 160:1257–1258PubMed
Buono MJ, Sjoholm NT (1988) Effect of physical training on peripheral sweat production. J Appl Physiol (1985) 65:811–814
Buono MJ (1999) Sweat ethanol concentrations are highly correlated with co-existing blood values in humans. Exp Physiol 84:401–404PubMed
Buono MJ, McKenzie BK, Kasch FW (1991) Effects of ageing and physical training on the peripheral sweat production of the human eccrine sweat gland. Age Age 20:439–441
Clunes MT, Lindsay SL, Roussa E, Quinton PM, Bovell DL (2004) Localisation of the vacuolar proton pump (V-H+-ATPase) and carbonic anhydrase II in the human eccrine sweat gland. J Mol Histol 35:339–345PubMed
Cohn JR, Emmett EA (1978) The excretion of trace metals in human sweat. Ann Clin Lab Sci 8:270–275PubMed
Collins KJ, Weiner JS (1962) Observations on arm-bag suppression of sweating and its relationship to thermal sweat-gland 'fatigue'. J Physiol 161:538–556PubMedPubMedCentral
Colombani P, Spati S, Spleiss C, Frey-Rindova P, Wenk C (1997) Exercise-induced sweat nitrogen excretion: evaluation of a regional collection method using gauze pads. Z Ernahrungswiss 36:237–243PubMed
Costa F, Calloway DH, Margen S (1969) Regional and total body sweat composition of men fed controlled diets. Am J Clin Nutr 22:52–58PubMed
Costill DL (1977) Sweating: its composition and effects on body fluids. Ann N Y Acad Sci 301:160–174PubMed
Costill DL, Cote R, Miller E, Miller T, Wynder S (1975) Water and electrolyte replacement during repeated days of work in the heat. Aviat Sp Environ Med 46:795–800
Costill DL, Cote R, Fink W (1976) Muscle water and electrolytes following varied levels of dehydration in man. J Appl Physiol 40:6–11PubMed
Czarnowski D, Gorski J, Jozwiuk J, Boron-Kaczmarska A (1992) Plasma ammonia is the principal source of ammonia in sweat. Eur J Appl Physiol Occup Physiol 65:135–137PubMed
DeRuisseau KC, Cheuvront SN, Haymes EM, Sharp RG (2002) Sweat iron and zinc losses during prolonged exercise. Int J Sport Nutr Exerc Metab 12:428–437PubMed
di Sant'Agnese PA, Powell GF (1962) The eccrine sweat defect in cystic fibrosis of the pancreas. Ann N Y Acad Sci 93:555–559
Didierjean L, Gruaz D, Frobert Y, Grassi J, Dayer JM, Saurat JH (1990) Biologically active interleukin 1 in human eccrine sweat: site-dependent variations in alpha/beta ratios and stress-induced increased excretion. Cytokine 2:438–446PubMed
Dill DB, Hall FG, Edwards HT (1938) Changes in composition of sweat during acclimatization to heat. Am J Physiol 123:412–419
Dobson RL (1965) The human eccrine sweat gland: structural and functional interrelationships. Arch Environ Health 11:423–429PubMed
Dobson RL, Sato K (1972) The secretion of salt and water by the eccrine sweat gland. Arch Dermatol 105:366–370PubMed
Eichner ER (2008) Genetic and other determinants of sweat sodium. Curr Sports Med Rep 7:S36–S40
Elizondo RS (1973) Local control of eccrine sweat gland function. Feder Proc 32:1583–1587
Ely MR, Kenefick RW, Cheuvront SN, Chinevere T, Lacher CP, Lukaski HC, Montain SJ (2013) The effect of heat acclimation on sweat microminerals: artifact of surface contamination. Int J Sport Nutr Exerc Metab 23:470–479PubMed
Embden R, Tachau H (1910) Uber das Vorkommen von Serin im menschlichen. Schweisse Biochem Ztschr 28:230
Fellmann N, Grizard G, Coudert J (1983) Human frontal sweat rate and lactate concentration during heat exposure and exercise. J Appl Physiol Respir Environ Exerc Physiol 54:355–360PubMed
Foy H, Kondi A (1957) Anaemias of the tropics; relation to iron intake, absorption and losses during growth, pregnancy and lactation. J Trop Med Hyg 60:105–118PubMed
Gibinski K, Kumaszka F, Zmudzinski J, Giec L, Waclawczyk J, Dosiak J (1973) Sodium 24Na and potassium 42K availability for sweat production after intravenous injection and their handling by sweat glands. Acta biologica et medica Germanica 30:697–708PubMed
Gibinski K, Zmudzinski JZJ, Kumaszka F, Giec L, Waclawczyk J (1974) Calcium transit to thermal sweat. Acta biologica et medica Germanica 32:199–204PubMed
Gibson LE, Cooke RE (1959) A test for concentration of electrolytes in sweat in cystic fibrosis of the pancreas utilizing pilocarpine by iontophoresis. Pediatrics 23:545–549PubMed
Gitlitz PH, Sunderman FW Jr, Hohnadel DC (1974) Ion-exchange chromatography of amino acids in sweat collected from healthy subjects during sauna bathing. Clin Chem 20:1305–1312PubMed
Goodwin ML, Harris JE, Hernández A, Gladden LB (2007) Blood lactate measurements and analysis during exercise: a guide for clinicians. J Diab Sci Technol 1:558–569
Gordon RS Jr, Cage GW (1966) Mechanism of water and electrolyte secretion by the eccrine sweat gland. Lancet 1:1246–1250PubMed
Green JM, Pritchett RC, Crews TR, McLester JR, Tucker DC (2004) Sweat lactate response between males with high and low aerobic fitness. Eur J Appl Physiol 91:1–6PubMed
Greenleaf JE, Castle BL, Ruff WK (1972) Maximal oxygen uptake, sweating and tolerance to exercise in the heat. Int J Biometeorol 16:375–387PubMed
Hammond KB, Turcios NL, Gibson LE (1994) Clinical evaluation of the macroduct sweat collection system and conductivity analyzer in the diagnosis of cystic fibrosis. J Pediatr 124:255–260PubMed
Hargreaves M, Morgan TO, Snow R, Guerin M (1989) Exercise tolerance in the heat on low and normal salt intakes. Clin Sci (Lond) 76:553–557
Henkin SD, Sehl PL, Meyer F (2010) Sweat rate and electrolyte concentration in swimmers, runners, and nonathletes. Int J Sports Physiol Perform 5:359–366PubMed
Hier SW, Cornbleet T, Bergeim O (1946) The amino acids of human sweat. J Biol Chem 166:327–333PubMed
Hjortskov N, Jepsen LT, Nielsen B, Juul A, Skakkebaek NE (1995) Pilocarpine iontophoresis test: an index of physiological sweat secretion? Clin Physiol 15:409–414PubMed
Hussain R, Patwardhan VN (1959) Iron content of thermal sweat in iron-deficiency anaemia. Lancet 1:1073–1074PubMed
Ikai K, Sato K, Sugiyama K, Otsuka Y, Nitta H (1969) Comparison of human sweat electrolyte concentration in mental, thermal and exercise perspiration. Nagoya Med J 15:47–66PubMed
Inoue Y, Nakao M, Okudaira S, Ueda H, Araki T (1995) Seasonal variation in sweating responses of older and younger men. Eur J Appl Physiol Occup Physiol 70:6–12PubMed
Inoue Y, Havenith G, Kenney WL, Loomis JL, Buskirk ER (1999) Exercise- and methylcholine-induced sweating responses in older and younger men: effect of heat acclimation and aerobic fitness. Int J Biometeorol 42:210–216PubMed
Jacob RA, Sandstead HH, Munoz JM, Klevay LM, Milne DB (1981) Whole body surface loss of trace metals in normal males. Am J Clin Nutr 34:1379–1383PubMed
Jacobsen E (1952) The metabolism of ethyl alcohol. Pharmacol Rev 4:107–135PubMed
Johnson RE, Pitts GC, Consolazio FC (1944) Factors influencing chloride concentration in human sweat. Am J Physiol 141:575–589
Jones PM, McCullom V, Moore G, Eckhardt J (2008) How soon is "promptly"? storage and handling of samples for the analysis of sweat chloride lab. Medicine 39:547–549
Kaiser D, Songo-Williams R, Drack E (1974) Hydrogen ion and electrolyte excretion of the single human sweat gland. Pflugers Arch Eur J Physiol 349:63–72
Kirby CR, Convertino VA (1986) Plasma aldosterone and sweat sodium concentrations after exercise and heat acclimation. J Appl Physiol 61:967–970PubMed
Kirschbaum C, Hellhammer DH (2000) Salivary cortisol. In: Fink G (ed) Encyclopedia of stress, 2nd edn. Academic, New York, pp 405–409
Klesges RC et al (1996) Changes in bone mineral content in male athletes. Mechanisms of action and intervention effects. JAMA 276:226–230PubMed
Kondo N, Shibasaki M, Aoki K, Koga S, Inoue Y, Crandall CG (2001) Function of human eccrine sweat glands during dynamic exercise and passive heat stress. J Appl Physiol (1985) 90:1877–1881
Konikoff F, Shoenfeld Y, Magazanik A, Epstein J, Shapira Y (1986) Effects of salt loading during exercise in a hot dry climate. Biomed Pharmacother 40:296–300PubMed
Kozlowski S, Saltin B (1964) Effect of sweat loss on body fluids. J Appl Physiol 19:1119–1124PubMed
Kuno Y (1956) Human perspiration. Charles C. Thomas Publisher, Springfield
Kutchai HC (1998) Cellular membranes and transmembrane transport of solute and water. In: Berne RM, Levy MN (eds) Physiology. Mosby Press, St. Louis, pp 3–20
Ladell WSS, Shephard RJ (1961) Aldosterone inhibition and acclimatization to heat. Proc Physiol Soc 3–4:19P–20P
Lemon PW, Yarasheski KE, Dolny DG (1986) Validity/reliability of sweat analysis by whole-body washdown vs. regional collections. J Appl Physiol 61:1967–1971PubMed
Lobitz WC Jr, Mason HL (1948) Chemistry of palmar sweat; discussion of studies on chloride, urea, glucose, uric acid, ammonia nitrogen and creatinine. Arch Derm Syphilol 57:907–915PubMed
Lugg JW, Ellis FP (1954) Some water-soluble vitamins in the sweat of tropically acclimatized European men. Br J Nutr 8:71–77PubMed
Mack GW, Nadel ER (1996) Body fluid balance during heat stress in humans. In: Fregly MJ, Blatteis CM (eds) Handbook of physiology, section 4, environmental physiology, vol 1. Oxford University Press for the American Physiological Society, New York, pp 187–214
Maughan RJ, Shirreffs SM (1998) Fluid and electrolyte loss and replacement in exercise. In: Harries M, Williams C, Stanish WD, Micheli LL (eds) Oxford textbook of sports medicine, 2nd edn. Oxford University Press, New York, pp 97–113
McCance RA (1938) The effect of salt deficiency in man on the volume of the extracellular fluids, and on the composition of sweat, saliva, gastric juice and cerebrospinal fluid. J Physiol 92:208–218PubMedPubMedCentral
McCubbin AJ, Costa RJS (2018) The impact of dietary sodium intake on sweat sodium concentration in response to endurance exercise: a systematic review. Int J Sports Sci 8:25–37
Mickelsen O, Keys A (1943) The composition of sweat, with special reference to the vitamins. J Biol Chem 149:479–490
Mishra A, Greaves R, Massie J (2005) The relevance of sweat testing for the diagnosis of cystic fibrosis in the genomic era. Clin Biochem Rev 26:135–153PubMedPubMedCentral
Mitchell HH, Hamilton TS (1949) The dermal excretion under controlled environmental conditions of nitrogen and minerals in human subjects, with particular reference to calcium and iron. J Biol Chem 178:345–361PubMed
Mitsubayashi K, Suzuki M, Tamiya E, Karube I (1994) Analysis of metabolites in sweat as a measure of physical condition. Anal Chim Acta 289:27–34
Montagna W, Parakkal PF (1974a) Apocrine Glands. In: Montagna W, Parakkal PF (eds) The structure and function of skin, 3rd edn. Academic, New York, pp 332–365
Montagna W, Parakkal PF (1974b) Sebaceous glands. In: Montagna W, Parakkal PF (eds) The structure and function of skin, 3rd edn. Academic, New York, pp 280–331
Montain SJ, Cheuvront SN, Lukaski HC (2007) Sweat mineral-element responses during 7 h of exercise-heat stress. Int J Sport Nutr Exerc Metab 17:574–582PubMed
Mosher HH (1933) Simultaneous study of constituents of urine and perspiration. J Biol Chem 99(3):781–790
Nadel ER (1979) Control of sweating rate while exercising in the heat. Med Sci Sports 11:31–35PubMed
Nyman E, Palmlov A (1936) The elimination of ethyl alcohol in sweat. Skand Arch Physiol 74:155–159
Ogawa T, Asayama M, Miyagawa T (1982) Effects of sweat gland training by repeated local heating. Jpn J Physiol 32:971–981PubMed
Pandolf KB, Cadarette BS, Sawka MN, Young AJ, Francesconi RP, Gonzalez RR (1988) Thermoregulatory responses of middle-aged and young men during dry-heat acclimation. J Appl Physiol (1985) 65:65–71
Patterson MJ, Galloway SD, Nimmo MA (2000) Variations in regional sweat composition in normal human males. Exp Physiol 85:869–875PubMed
Patterson MJ, Galloway SD, Nimmo MA (2002) Effect of induced metabolic alkalosis on sweat composition in men. Acta Physiol Scand 174:41–46PubMed
Paulev PE, Jordal R, Pedersen NS (1983) Dermal excretion of iron in intensely training athletes. Clin Chim Acta 127:19–27PubMed
Phillips M, McAloon MH (1980) A sweat-patch test for alcohol consumption: evaluation in continuous and episodic drinkers. Alcohol Clin Exp Res 4:391–395PubMed
Pilardeau PA, Chalumeau MT, Harichaux P, Vasseur P, Vaysse J, Garnier M (1988) Effect of physical training on exercise induced sweating in men. J Sports Med Phys Fit 28:176–180
Prasad AS, Schulert AR, Sandstead HH, Miale A Jr, Farid Z (1963) Zinc, iron, and nitrogen content of sweat in normal and deficient subjects. J Lab Clin Med 62:84–89PubMed
Quinton PM (1981) Effects of some ion transport inhibitors on secretion and reabsorption in intact and perfused single human sweat glands. Pflugers Archiv Eur J Physiol 391:309–313
Quinton PM (1999) Physiological basis of cystic fibrosis: a historical perspective. Physiol Rev 79:S3–S22PubMed
Reddy MM, Quinton PM (1994b) Rapid regulation of electrolyte absorption in sweat duct. J Membr Biol 140:57–67PubMed
Reitamo S, Anttila HS, Didierjean L, Saurat JH (1990) Immunohistochemical identification of interleukin I alpha and beta in human eccrine sweat-gland apparatus. Br J Dermatol 122:315–323PubMed
Robertshaw D (1983) Apocrine sweat glands. In: Goldsmith LA (ed) Biochemistry and physiology of the skin, vol 1. Oxford University Press, New York, pp 642–653
Robinson S, Robinson AH (1954) Chemical composition of sweat. Physiol Rev 34:202–220PubMed
Robinson S, Gerking SD, Turrell ES, Kincaid RK (1950) Effect of skin temperature on salt concentration of sweat. J Appl Physiol 2:654–662PubMed
Robinson S, Nicholas JR, Smith JH, Daly WJ, Pearcy M (1955) Time relation of renal and sweat gland adjustments to salt deficiency in men. J Appl Physiol 8:159–165PubMed
Robinson S, Maletich RT, Robinson WS, Rohrer BB, Kunz AL (1956) Output of NaCl by sweat glands and kidneys in relation to dehydration and to salt depletion. J Appl Physiol 8:615–620PubMed
Roohani N, Hurrell R, Kelishadi R, Schulin R (2013) Zinc and its importance for human health: an integrative review. J Res Med Sci 18:144–157PubMedPubMedCentral
Rothman S, Sullivan MB (1949) Amino acids on the normal skin surface. J Investig Dermatol 13:319–321PubMed
Sato K (1973) Stimulation of pentose cycle in the eccrine sweat gland by adrenergic drugs. Am J Physiol 224:1149–1154PubMed
Sato K (1977) The physiology, pharmacology, and biochemistry of the eccrine sweat gland. Rev Physiol Biochem Pharmacol 79:51–131PubMed
Sato K (1983) The physiology and pharmacology of the eccrine sweat gland. In: Goldsmith L (ed) Biochemistry and physiology of the skin. Oxford University Press, New York, pp 596–641
Sato K (1993) The mechanism of eccrine sweat secretion. In: Gisolfi CV, Nadel ER (eds) Exercise, heat, and thermoregulation Perspectives in exercise science and sports medicine, vol 6. Brown & Benchmark, Dubuque, pp 85–117
Sato K, Dobson RL (1970) The effect of intracutaneous d-aldosterone and hydrocortisone on human eccrine sweat gland function. J Investig Dermatol 54:450–462PubMed
Sato K, Sato F (1987b) Sweat secretion by human axillary apoeccrine sweat gland in vitro. Am J Physiol 252:R181–187PubMed
Sato K, Sato F (1990) Na+, K+, H+, Cl, and Ca2+ concentrations in cystic fibrosis eccrine sweat in vivo and in vitro. J Lab Clin Med 115:504–511PubMed
Sato K, Feibleman C, Dobson RL (1970) The electrolyte composition of pharmacologically and thermally stimulated sweat: a comparative study. J Investig Dermatol 55:433–438PubMed
Sato K, Leidal R, Sato F (1987) Morphology and development of an apoeccrine sweat gland in human axillae. Am J Physiol 252:R166–180PubMed
Sato K, Kang WH, Saga K, Sato KT (1989) Biology of sweat glands and their disorders. I. Normal sweat gland function. J Am Acad Dermatol 20:537–563PubMed
Sato K, Ohtsuyama M, Samman G (1991) Eccrine sweat gland disorders. J Am Acad Dermatol 24:1010–1014PubMed
Schulz H, Heck H (2003) Glycogen depletion as indication of ammonia determination in exercise testing. Eur J Sport Sci 3:1–9
Shibasaki M, Crandall CG (2010) Mechanisms and controllers of eccrine sweating in humans. Front Biosci (Schol Ed) 2:685–696
Shirreffs SM, Maughan RJ (1997) Whole body sweat collection in humans: an improved method with preliminary data on electrolyte content. J Appl Physiol 82:336–341PubMed
Shwachman H, Antonowicz I (1962) The sweat test in cystic fibrosis. Ann N Y Acad Sci 93:600–624
Sigal CB, Dobson RL (1968) The effect of salt intake on sweat gland function. J Investig Dermatol 50:451–455PubMed
Silvers S, Forster W, Talbert GA (1928) Simultaneous study of the constituents of the sweat, urine and blood, also gastric acidity and other manifestations resulting from sweating VI Sugar. Am J Physiol 84:577–582
Talbert GA (1919) Effect of work and heat on the hydrogen concentration of the sweat. Am J Physiol 50:433–442
Talbert GA (1922) Further studies on the hydrogen ion concentration of human sweat. Am J Physiol 61:493–500
Talbert GA, Haugen CO (1927) Simultaneous study of the constituents of the sweat, urine, and blood, also gastric acidity and other manifestations resulting from sweating I Chlorides. Am J Physiol 81:74–80
Talbert GA, Silvers S, Johnson W (1927) Simultaneous study of the constituents of the sweat urine and blood, also gastric acidity and other manifestations resulting from sweating II Total nitrogen of sweat and urine; total non-protein nitrogen of blood. Am J Physiol 81:81–85
Thapar GS, Shenolikar IS, Tulpule PG (1976) Sweat loss of nitrogen and other nutrients during heavy physical activity. Indian J Med Res 64:590–596PubMed
Tian YW, Stacey MC (2003) Cytokines and growth factors in keratinocytes and sweat glands in chronic venous leg ulcers An immunohistochemical study. Wound Repair Regen 11:316–325PubMed
Tipton MJ, Pandolf KB, Sawka MN, Werner J, Taylor NAS (2008) Physiological adaptation to hot and cold environments. In: Taylor NAS, Groeller H (eds) Physiological bases of human performance during work and exercise. Elsevier, Edinburgh, pp 379–400
Van Heyningen R, Weiner JS (1952) A comparison of arm-bag sweat and body sweat. J Physiol 116:395–403PubMedCentral
Vellar OD (1968a) Studies on sweat losses of nutrients I Iron content of whole body sweat and its association with other sweat constituents, serum iron levels, hematological indices, body surface area, and sweat rate. Scand J Clin Lab Investig 21:157–167
Vellar OD (1968b) Studies on sweat losses of nutrients. II. The influence of an oral iron load on the iron content of whole body cell-free sweat. Scand J Clin Lab Investig 21:344–346
Vellar OD, Askevold R (1968) Studies on sweat losses of nutrients. 3. Calcium, magnesium, and chloride content of whole body cell-free sweat in healthy unacclimatized men under controlled environmental conditions. Scand J Clin Lab Investig 22:65–71
Verde T, Shephard RJ, Corey P, Moore R (1982) Sweat composition in exercise and in heat. J Appl Physiol 53:1540–1545PubMed
Vimieiro-Gomes AC, Magalhaes FC, Amorim FT, Machado-Moreira CA, Rosa MS, Lima NR, Rodrigues LO (2005) Comparison of sweat rate during graded exercise and the local rate induced by pilocarpine. Braz J Med Biol Res 38:1133–1139PubMed
Waller MF, Haymes EM (1996) The effects of heat and exercise on sweat iron loss. Med Sci Sports Exerc 28:197–203PubMed
Webster HL (1983) Laboratory diagnosis of cystic fibrosis. Crit Rev Clin Lab Sci 18:313–338PubMed
Weiner JS, Hellmann K (1960) The sweat glands. Biol Rev 35:141–186
Weiner JS, van Heyningen R (1949) Lactic acid and sweat gland function. Nature 164(4165):351–352PubMed
Weintraub LR, Demis DJ, Conrad ME, Crosby WH (1965) Iron excretion by the skin Selective localization of iron-59 in epithelial cells. Am J Pathol 46:121–127PubMedPubMedCentral
Wenger CB (1972) Heat of evaporation of sweat: thermodynamic considerations. J Appl Physiol 32:456–459PubMed
Wescor (2005) Sweat Chek™ sweat conductivity analyzer model 3120 instruction/service manual. Wescor Inc, USA
Wheeler EF, el-Neil H, Willson JO, Weiner JS (1973) The effect of work level and dietary intake on water balance and the excretion of sodium, potassium and iron in a hot climate. Br J Nutr 30:127–137PubMed
Whitehouse AGR (1935) The dissolved constituents of human sweat. Proc R Soc Lond Ser B Biol Sci 117:139–154
Yuyama H (1935) On the histological examination of distribution of glycogen in the skin of leprosy with special reference to the relationship between the function of sweat glands and the changes of glycogen content. J Derm Urol 37:811–832
Zhou Y, Han H, Naw HPP, Lammy AV, Goh CH (2016) Real-time colorimetric hydration sensor for sport activities. Mater Des 90:1181–1185
Metadata
Title
Physiological mechanisms determining eccrine sweat composition
Authors
Lindsay B. Baker
Anthony S. Wolfe
Publication date
01-04-2020
Publisher
Springer Berlin Heidelberg
Published in
European Journal of Applied Physiology / Issue 4/2020
Print ISSN: 1439-6319
Electronic ISSN: 1439-6327
DOI
https://doi.org/10.1007/s00421-020-04323-7

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