Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0024523 (malabsorption)
 7,319 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Juvenile rats fed a diet containing 1% lead acetate for 7 weeks, in addition to an impaired growth rate and renal function derangements, suffered malabsorption of glucose and certain amino acids, as assessed by an in vivo perfusion technique. The reduction in glucose absorption ranged between 10% and 31% when the carbohydrate was pumped in concentrations of 2-80 mM. This alteration was compatible with a noncompetitive type of transport inhibition. The intestinal absorption of glycine, lysine, and phenylalanine were, respectively, decreased 22, 18, and 15% when these amino acids were present at 1 mM levels. Sodium transport was severely reduced (57.6 +/- 17.9 (SEM) vs. 124.2 +/- 17.4 muEq/min-cm) and intestinal mucosa (Na+-K+)-ATPase was concomitantly lower in the lead-intoxicated rats (186.4 +/- 19.0 vs 268.4 +/- 29.8 nmol P/min-mg protein). However, this enzyme was not altered in liver and kidney. Furthermore, intestinal mucosa fructose-1,6-diphosphatase, succinic dehydrogenase, pyruvate kinase, and tryptophan hydroxylase were not different in experimental and control animals. These studies substantiate the presence of functional and biochemical abnormalities in the intestinal mucosa of young rats when fed substantial amounts of a soluble lead salt. It is, therefore, reasonable to accept the possibility that physiologic damage occurs in tissues directly subjected to high and persistent levels of a toxic agents, as it occurs in other organs, underscoring the parallelism between transport mechanisms at the renal and intestinal levels.
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PMID:Experimental lead poisoning and intestinal transport of glucose, amino acids, and sodium. 13 38

Magnesium is an essential cofactor for many enzymatic reactions, especially those involved in energy metabolism. Deficits of magnesium are prevalent due to inadequate intake or malabsorption and due to the renal loss of magnesium that occurs in certain disease states (alcoholism, diabetes) and with drug therapy (diuretics, aminoglycosides, cisplatin, digoxin, cyclosporin, amphotericin B). Protracted deficits of magnesium in humans and animals result in neurological disturbances, including hyperexcitability, convulsions and various psychiatric symptoms ranging from apathy to psychosis, some of which can be reversed with magnesium supplementation, others requiring correction of the dysregulation mechanism. Although the role of magnesium in neuronal function is not completely understood, a lowering of CSF or brain magnesium can induce epileptiform activity and there is an association between decreased CSF magnesium and the development of seizures. CSF concentrations of magnesium are normally higher than magnesium plasma ultrafiltrate (diffusible) concentrations due to the active transport of magnesium across the blood-brain barrier. Under conditions of magnesium deficiency, CSF concentrations decline, although this decline lags behind and is less pronounced than the changes observed in plasma magnesium concentrations. Decreases in CSF magnesium concentrations correlate with the alterations observed in extracellular brain magnesium concentrations in animals following the dietary deprivation of magnesium. CSF magnesium concentrations can readily be repleted following magnesium supplementation, although high dose magnesium therapy, such as that used in the treatment of convulsions in eclampsia, will only increase CSF magnesium concentrations to a very limited degree (approximately 11-18 per cent) above physiological concentrations. Greater increases in CSF magnesium may occur in neonates since neonatal swine, following treatment with magnesium, have CSF magnesium concentrations that are similar to their plasma concentrations. There has been a recent resurgence of interest in magnesium deficiency and its neurological consequences due to the finding that magnesium, at physiological concentrations, blocks N-methyl-D-aspartate (NMDA) receptors in neurones. NMDA receptors are normally activated by glutamate and/or aspartate which represent the principal neurotransmitters for excitatory synaptic transmission in vertebrate CNS. Magnesium deficiency produces epileptiform activity in the CNS which can be blocked by NMDA receptor antagonists. Other mechanisms, including alterations in Na+/K(+)-ATPase activity, cAMP/cGMP concentrations and calcium currents in pre- and postsynaptic membranes, may also be at least partially responsible for the neuronal effects associated with low brain magnesium. Further studies are necessary to increase our understanding of the neurological implications of magnesium deficit in the central nervous system.
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PMID:Brain and CSF magnesium concentrations during magnesium deficit in animals and humans: neurological symptoms. 129 67

Decline in the specific activities of intestinal cytosolic glucose-6-phosphate dehydrogenase (G6PD) and isocitrate dehydrogenase (ICDH); brush border glucoamylase, and isomaltase; and basolateral (Na+, K+)-ATPase activities were observed during the establishment, acute phase and decline phase of infection in Giardia lamblia-infected mice. The degree of decline in the activities of various enzymes correlated well with the number of trophozoites counted in the jejunum. There appeared to be a gradual recovery of enzymatic activities during the decline phase of infection, when the number of trophozoites also declined. The decline in activities of these enzymes may contribute to malabsorption of nutrients during giardiasis.
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PMID:Alterations in enzymatic activities of the intestinal mucosa during the course of Giardia lamblia infection in mice. 1667 Jul 64

Intrinsic factor is produced by the gastric parietal cell. Its secretion is stimulated via all pathways known to stimulate gastric acid secretion: histamine, gastrin, and acetylcholine. There is, however, a different mode of secretion for both substances: atropine, vagotomy, and H2 receptor antagonists inhibit both intrinsic factor and acid secretion, but secretin and the hydrogen-potassium ATPase antagonist omeprazole have no effect on intrinsic factor while substantially reducing acid secretion. Cobalamin in food is bound to animal protein. Cobalamin deficiency due to inadequate dietary intake is rarely seen in extreme vegetarians (vegans). In the stomach cobalamin is liberated from its protein binding by peptic digestion and bound to R-proteins. Hypochlorhydria or achlorhydria, whether medically induced or not, may impair cobalamin uptake. The cobalamin-R-protein complex is split by pancreatic enzymes in the duodenum, where cobalamin is bound to intrinsic factor. Pancreatic insufficiency may lead to cobalamin deficiency. Lack of intrinsic factor is the commonest cause of cobalamin deficiency; very rarely, aberrant forms of intrinsic factor are produced, but the clinical syndrome is similar. Gram-negative anaerobe bacteria bind the cobalamin-intrinsic factor complex, and bacterial overgrowth of the small intestine diminishes cobalamin resorption. Parasitic infections with fish tape-worm and Giardia lamblia are also associated with cobalamin malabsorption. The cobalamin-intrinsic factor complex binds to the ileal receptors in the terminal ileum. Cobalamin absorption may be impaired after resection or by diseases affecting more than 50 cm of the terminal ileum, such as Crohn's disease, coeliac disease, tuberculosis, lymphoma or radiation. There is clearly a wide diversity in the aetiology of cobalamin deficiency, which requires a versatile diagnostic approach.
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PMID:Intrinsic factor secretion and cobalamin absorption. Physiology and pathophysiology in the gastrointestinal tract. 177 33

Several studies pointed out an altered stool pattern as the most common side effect of auranofin therapy. The major mechanism in the aetiology of auranofin-induced impairment in bowel habit seems to be the inhibition of Na+/K+ ATPase in the gut. In vitro experiments proved that auranofin can affect active bile acid (BA) reabsorption in rat terminal ileum; this action, due to the ability of the drug to reduce Na+ pump activity by inhibiting Na+/K+ ATPase, may make a significant contribution to the auranofin-induced diarrhoea. The ability of auranofin to reduce the Na+ gradient necessary for active BA reabsorption, however, could cause a decrease of serum BA levels in patients taking auranofin before or without the development of an overt diarrhoea. We measured fasting and postprandial serum conjugated BA levels in 10 female rheumatoid arthritis patients before and after one month and two months' auranofin treatment. No patient developed diarrhoea during the chrysotherapy. When oral gold salt therapy was started, we observed a slight decrease in serum BA levels, but difference was not statistically significant. We can conclude that auranofin therapy does not cause BA malabsorption in patients who do not develop diarrhoea during the treatment.
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PMID:Effect of oral gold salt therapy on bile acid absorption in rheumatoid arthritis patients. 233 51

In the United States and other developed countries thiamin deficiency is often related to chronic alcoholism. A number of mechanisms may be involved in the pathogenesis of thiamin deficiency in the alcoholic population. An important cause is inadequate intake of thiamin. Moreover, there may be decreased converstion of thiamin to the active coenzyme, reduced hepatic storage of the vitamin in patients with fatty metamorphosis, ethanol inhibition of intestinal thiamin transport, and impaired thiamin absorption secondary to other states of nutritional deficiency. The present discussion focuses on the mechanism of ethanol-related thiamin malabsorption. Under normal conditions thiamin transport in animals and humans is biphasic. At low or physiological thiamin concentrations, transport is a saturable, carrier-mediated, active process; but at higher concentrations, the transport of thiamin is predominantly passive. Ethanol reduces the rate of intestinal absorption and the net transmural flux of thiamin. Furthermore, ethanol inhibits only the active and not the passive component of thiamin transport by impeding the cellular exit of thiamin across the basolateral or serosal membrane. The impairment of thiamin movement out of the enterocyte correlates with a fall in the activity of Na-K ATPase. Bound to the basolateral membrane, Na-K ATPase is believed to be involved in the kinetics of active transport. Ethanol also increases the fluidity of enterocyte brush border and basolateral membranes. Since ethanol increases membrane fluidity it is possible that tahe impairment of thiamin transport and the diminution of Na-K ATPase activity may be related, at least partly, to a physical perturbation of the enterocyte membrane.
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PMID:Mechanisms of thiamin deficiency in chronic alcoholism. 625 54

The pathogenesis of diarrhea caused by rotavirus infection was studied in miniature swine piglets. The animals were inoculated orally with 2 X 10(7) plaque-forming units of porcine rotavirus (OSU strain). During the height of diarrhea, intestinal function was investigated by in vivo perfusion of a 30-cm segment of proximal jejunum and a 30-cm segment of distal ileum. Absorption of Na+ and water decreased and 3-O-methylglucose transport was markedly reduced, P less than 0.01 compared to control animals. Mucosal lactase and sucrase levels were depressed in both the jejunum and ileum, P less than 0.001. Na+,K+-ATPase activity was significantly depressed only in the ileum, P less than 0.001. These changes were associated with a marked reduction in villous height, suggesting that the diarrhea could be an osmotic diarrhea due to nutrient (carbohydrate) malabsorption. Fresh stool samples were obtained and analyzed immediately for NA+,K+, osmolarity, glucose, and lactose; the osmotic gap was also determined. Stool osmolarity continually increased from 248 +/- 20 mosm/liter prior to inoculation to 348 +/- 20 mosm/liter at 75 +/- 1 hr postinoculation (P less than 0.005); the majority of the fecal osmotic gap could be accounted for by the amount of lactose present in the stools. Stool sodium increased from 34 +/- 6 mM prior to inoculation to a maximum of 65 +/- 4 mM at 53 +/- 1 hr postinoculation, P less than 0.001. There was no significant change in potassium concentration.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Pathogenesis of rotavirus-induced diarrhea. Preliminary studies in miniature swine piglet. 648 82

The many causes of clinical magnesium deficiency can be placed into 2 categories: diminished intake of magnesium, and enhanced losses of magnesium, either through the gastrointestinal tract or through the kidneys. Examples of the first category include alcoholism, starvation, anorexia due to neoplastic disease and/or chemotherapy. Examples of the second category include severe diarrhoeal states, gastrointestinal fistulae, malabsorption, diuretic therapy and gentamicin therapy. Estimates of the prevalence of clinical hypomagnesaemia range from 6 to 11% in hospitalised patients. Serum predictors of associated clinical magnesium depletion include hypokalaemia (42%), hyponatraemia (23%), hypophosphataemia (22%) and hypocalcaemia (20%). Experimental and clinical observations strongly support the view that magnesium and potassium are closely linked at the cellular level. Magnesium has been demonstrated to be important in cell energetics (Mg++-activated ATPase), in maintenance of the integrity of cell membranes, retardation of cell loss of potassium, as well as enhancing repletion of cell potassium. While translation of these experimental observations into clinical terms encompasses a wide spectrum of illnesses, there is special relevance in considering the role of magnesium in repletion and maintenance of cell potassium in 2 clinical instances: (a) patients treated with digitalis and diuretics; and (b) hypertensive patients. In these types of patients not only potassium but also magnesium should be administered together to avoid the problem of cell potassium depletion and refractory potassium repletion associated with coexisting and uncorrected magnesium depletion.
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PMID:Magnesium deficiency. Causes and clinical implications. 649 96

Only in the duodenum and in the colon calcium is absorbed by a cellular 1,25 alpha-Vitamin D3-dependent transport mechanism. Calcium absorption is highest in the proximal large intestine, about ten times higher than in the duodenum or in the descending colon. 1,25 alpha-Vitamin D3 stimulates calcium transport by genomic (slow effect: synthesis of cytosolic calcium binding protein CabP and basolateral Ca-ATPase) and non-genomic action (rapid effect: transcaltachyia, liponomic effect at the brush border membrane). CabP-dependent translocation across the cytosol is thought to be rate limiting step of cellular calcium transport. However, only about 50% of calcium absorption is cellular mediated but the same amount of calcium convectively is absorbed by transepithelial water flow across the paracellular pathway (solvent drag effect). 1,25 alpha-Vitamin D3 not only activates cellular calcium absorption but also increases paracellular permeability for calcium by an unknown mechanism. However, essential steps in the cascade from the interaction of 1,25 alpha-Vitamin D3 with the specific receptor over the regulation of the synthesis of calcium binding and transporting proteins to the induction of cellular calcium transport are not as yet clearly understood. The exact feedback mechanism of synchronized calcium transport across the distinct subcellular compartments seems also to be resolved. Cellular calcium transport is not found in the jejunum or in the ileum, what can be explained by the absence of specific 1,25 alpha-Vitamin D3-dependent carrier systems in these segments. On the other hand calcium is secreted across the jejunum and ileum by an anomalous solvent drag effect. Hence, intestinal calcium metabolism seems to underlie an eneteroenteral circuit: 1,25 alpha-Vitamin D3-controlled cellular calcium absorption across the duodenum is followed by paracellular calcium secretion across the jejunum and ileum. The carrier in the proximal colon which works at the optimal level already under normal nutritional condition could be of physiological importance for the reclamation of unabsorbed dietary calcium and for the reabsorption of calcium that is secreted across the distal small intestine. Under certain pathophysiological conditions, i.e. malabsorption in proximal segments or malnutrition, calcium in addition may be conserved by the 1,25 alpha-Vitamin D3-sensitive carrier in the descending colon.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:[New findings on the mechanism and regulation of intestinal calcium transport]. 780 57

In the rapidly increasing elderly population, diarrhoea as a result of drug therapy is an important consideration. The elderly consume a disproportionately large number of drugs for multiple acute and chronic diseases. Drugs can compromise both immune and nonimmune responses. Aging decreases the quality and proportion of T cells which in turn reduces the production of secretory IgA, the primary immune response of the gut. Acid production in the stomach decreases with increasing age and this compromise its vital 'self-sterilising' function, thus increasing the risk of diarrhoea due to viral, bacterial and protozoal pathogens. Other nonimmune defence mechanisms include the motility of the small intestine and the host-protective commensal bacteria of the colon. Drug induced hypomotility may result in bacterial overgrowth, deconjugation of bile salts and diarrhoea. Less commonly, diarrhoea may occur due to hypermotility because of a cholinergic-like syndrome. In the colon the host-protective commensal bacteria provide a powerful defence against pathogens. Disruption of this commensal population by antibiotic therapy may result in Clostridium difficile supra-infection which causes diarrhoea through toxin production. This is especially important in the elderly patient on chemotherapy for malignancy and those with multiple diseases. The organism responds to vancomycin, metronidazole and bacitracin. Metronidazole is the suggested drug of choice, with vancomycin reserved for relapses. Drugs also cause diarrhoea by interfering with normal physiological processes. Drugs impair fluid absorption by activating adenylate cyclase within the small intestinal enterocyte which increases the level of cyclic AMP. This causes active secretion of Cl- and HCO3-, passive efflux of Na+, K+ and water and inhibition of Na+ and Cl- into the enterocyte. Examples of these drugs (secretagogues) are bisacodyl, misoprostol and chenodeoxycholic acid (used to dissolve cholesterol gallstones). Drugs may also affect a second mechanism that regulates water and electrolyte transport, the Na+, K+ exchange pump. The energy for this pump is provided by the ATPase mediated breakdown of ATP. ATPase may be inhibited by digoxin, auranofin, colchicine and olsalazine. A number of drugs cause osmotic diarrhoea including antacids containing magnesium trisilicate or hydroxide. Lactulose is being used increasingly in compensated liver disease to increase protein tolerance and prevent hepatic encephalopathy. Sorbitol, an osmotic laxative agent also used in some liquid pharmaceutical preparations, induces diarrhoea by virtue of its osmotic potential. Another mechanism by which drugs cause diarrhoea is by mucosal damage of the small and large bowel. In the small intestine mucosal damage causes diarrhoea and fat malabsorption, as may occur with neomycin and colchicine. In the colon, for example, gold salts and penicillamine cause colitis of varying severity. Though the causes of diarrhoea are diverse, a drug-associated aetiology should always be considered and actively sought and addressed to prevent the complications of dehydration, electrolyte imbalance and undernutrition.
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PMID:Mechanisms of drug-induced diarrhoea in the elderly. 978 28


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