Oral rehydration therapy in the second decade of the twenty-first century

被引：77

作者：

Binder H.J. ^{[1
]}

Brown I. ^{[2
]}

Ramakrishna B.S. ^{[3
]}

Young G.P. ^{[2
]}

机构：

[1] Department of Internal Medicine, Yale School of Medicine, New Haven, CT 06520

[2] Flinders Centre for Innovation in Cancer, Flinders University, Adelaide, SA

[3] SRM Institutes for Medical Sciences, Vadapalani

来源：

Current Gastroenterology Reports | 2014年 / 16卷 / 3期

关键词：

Acute diarrhea; Dual-action oral rehydration solution; Fermentable/resistant starch; Oral rehydration solution; Short-chain fatty acids;

D O I：

10.1007/s11894-014-0376-2

中图分类号：

学科分类号：

摘要：

Oral rehydration solution (ORS) was established as the cornerstone of therapy for dehydration secondary to acute infectious diarrhea approximately 40 years ago. The efficacy of ORS is based on the ability of glucose to stimulate Na and fluid absorption in the small intestine via a cyclic AMP-independent process. Despite the establishment that ORS is the primary reason for the substantial reduction in morbidity and mortality from diarrhea in children in developing countries, the use of ORS has lagged for many reasons. This review highlights efforts to establish a major reformulation of ORS following the demonstration that short-chain fatty acids (SCFA) stimulate colonic Na and fluid absorption by a cyclic AMP-independent mechanism. The addition of high-amylose maize starch (HAMS), a microbially-fermentable (or 'resistant') starch, to ORS results in delivery of non-absorbed carbohydrate to the colon where it is fermented to SCFA. To date, three randomized controlled trials with a HAMS-ORS in south India have demonstrated a substantial decrease in diarrhea duration in both adults and children hospitalized for acute diarrhea. Significant efforts are now underway to establish this dual-action, modified HAMS-hypoosmolar ORS solution as the standard ORS for the treatment of dehydration from acute diarrhea. © The Author(s) 2014.

引用

共 54 条

[1]

Pierce N.F., Banwell J.G., Rupak D.M., Mitra R.C., Caranasos G.J., Et al., Effect of intragastric glucose-electrolyte infusion upon water and electrolyte balance in Asiatic cholera, Gastroenterology, 55, pp. 333-343, (1968)

[2]

Hirschhorn N., Kinzie J.L., Sachar D.B., Northrup R.S., Taylor J.O., Et al., Decrease in net stool output in cholera during intestinal perfusion with glucose containing solutions, N Engl J Med, 279, pp. 176-181, (1968)

[3]

Series E., Water with sugar and salt, Lancet, 2, pp. 300-301, (1978)

[4]

Schultz S.G., Curran P.F., Coupled transport of sodium and organic solutes, Physiol Rev, 50, pp. 637-718, (1970)

[5]

Schultz S.G., Zalusky R., Ion transport in isolated rabbit ileum. II. The interaction between active sodium and active sugar transport, J Gen Physiol, 47, pp. 1043-1059, (1964)

[6]

Wright E.M., Loo D.D., Hirayama B.A., Biology of human sodium glucose transporters, Physiol Rev, 91, pp. 733-794, (2011)

[7]

Field M., Fromm D., Al-Awqati Q., Greenough III W.B., Effect of cholera enterotoxin on ion transport across isolated ileal mucosa, J Clin Invest, 51, pp. 796-804, (1972)

[8]

Field M., Intestinal ion transport and the pathophysiology of diarrhea, Journal of Clinical Investigation, 111, 7, pp. 931-943, (2003)

[9]

Field M., Rao M.C., Chang E.B., Intestinal electrolyte transport and diarrheal disease, N Engl J Med, 321, (1989)

[10]

Desjeux J.-F., Briend A., Butzner J.D., Oral rehydration solution in the year 2000: Pathophysiology, efficacy and effectiveness, Bailliere's Clinical Gastroenterology, 11, 3, pp. 509-527, (1997)

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