Reversal of protein losing enteropathy with prednisone in adults with modified fontan operations: long term palliation or bridge to cardiac transplantation? (1/137)

Protein losing enteropathy (PLE), defined as severe loss of serum protein into the intestine, occurs in 4-13% of patients after the Fontan procedure and carries a dismal prognosis with a five year survival between 46% and 59%. Chronically raised systemic venous pressure is thought to be responsible for the development of PLE in these patients, with perhaps superimposed immunological or inflammatory factors. The success rate of contemporary medical, transcatheter, and surgical treatments attempting to reduce systemic venous pressure ranges from 19% to 40%. Prednisone treatment for PLE has been tried, with variable success rates reported in children. The effect of prednisone in adult patients with PLE after the Fontan procedure is largely unknown. Two cases of PLE in adults (a 39 year old woman and a 25 year old man) after modified Fontan procedure who responded dramatically to oral prednisone treatment are reported, suggesting that a trial of this "non-invasive" treatment should be considered as long term palliation or bridge to cardiac transplantation.  (+info)

Disseminated Langerhans' cell histiocytosis and massive protein-losing enteropathy. (2/137)

Symptomatic involvement of the gastrointestinal (GI) tract as a prominent symptom in Langerhans' cell histiocytosis (LCH) is uncommon, occurring in less than 1 to 5% of all cases, even when the disease is in its disseminated form. Up to now, there have been reports of 18 cases of LCH with GI manifestations, including our 2 cases, with diarrhea (77.7%), protein-losing enteropathy (33.3%) and bloody stool being the most frequent findings. The authors present two patients with severe diarrhea and refractory hypoalbuminemia, and with the protein-losing enteropathy documented by Cr51-labeled albumin studies. A review of the literature indicated that the presence of GI symptoms is often associated with systemic disease as well as with poor prognosis, mainly under 2 years of age. Radioisotopes are useful for documenting protein loss in several diseases with high specificity and sensitivity, and their utilization in the cases reviewed here permitted diagnoses in 6 children, as well as improved therapeutic management.  (+info)

Parenteral nutrition in the management of a dog with lymphocytic-plasmacytic enteritis and severe protein-losing enteropathy. (3/137)

Management of lymphocytic-plasmacytic enteritis in a dog with whipworm infestation, hypoproteinemia, and ascites is described. Short-term parenteral nutrition hastened normalization of serum proteins, resolution of diarrhea, and weight gain. A description of the potential benefits, limitations, and possible complications of parenteral nutrition in refractory inflammatory bowel disease is given.  (+info)

Prevention and suppression by azathioprine of venom-induced protein-losing gastropathy in dogs. (4/137)

Irrigation of the dog's oxyntic glandular mucosa contained in a chronically prepared, vagally denervated, separated pouch of the dog's stomach with a solution (0.5 mg ml-1) of lyophilized venom of the hooded cobra (Naja naja) increases the permeability of the mucosa. If irrigation with venom solution is repeated at weekly intervals, the mucosa responds with increasing plasma-shedding which reaches a peak of 1-2 ml min-1 from roughly 60 cm2 of mucosa in 4-6 weeks. Plasma shedding in response to irrigation with venom gradually declines, leaving a permanent residual response of different magnitude in different dogs. Giving naive dogs the immunosuppressant azathioprine by mouth in a dose of 5 mg kg-1 day-1, beginning 1 week before the first irrigation with venom solution and continuing for 4 weeks, postpones the plasma-shedding response until the sixth or seventh week of venom irrigation. The plasma-shedding response is wholly or partially suppressed by further administration of azathioprine by mouth in a dose of 3.3 mg kg-1 day-1. These data support the hypothesis that the plasma-shedding response to repeated venom irrigation involves the immune system of the stomach.  (+info)

99mTc-human serum albumin scans in children with protein-losing enteropathy. (5/137)

Protein-losing enteropathy (PLE) can be diagnosed scintigraphically using 99mTc-human serum albumin (HSA) scans. METHODS: To evaluate the usefulness of this method in detecting enteric protein loss, we retrospectively reviewed the 99mTc-HSA scans of 18 children presenting consecutively with PLE. RESULTS: Enteric 99mTc-HSA uptake was noted in 12 patients (8 boys, 4 girls) with a mean age of 7.4 y. Early dynamic images showed abdominal uptake that was most likely in the small bowel in 91% of the scans. Delayed images showed abnormal accumulation that was localized in the colon in 73% and in the small bowel in 27% of the scans. A 4-mo follow-up scan obtained in 3 patients showed reduced HSA uptake after a high-protein, low-fat, medium-chain triglyceride oil-based diet and fat-soluble vitamins. Mean serum albumin, total protein, gammaglobulin, and calcium levels were significantly decreased. Ten patients (from 4 families) were diagnosed to have primary intestinal lymphangectasia. One patient had active Salmonella enterocolitis, and 1 had giardiosis. 99mTc-HSA was normal in the remaining 6 patients (3 boys, 3 girls) with a mean age of 3.5 y (range, 2-5 y). Mean serum albumin, total protein, gammaglobulin, and calcium levels were less decreased than those of the first group. Five of these patients had primary intestinal lymphangactesia (associated with infantile systemic hyalinosis in 1 patient). The remaining patient had normal duodenal biopsy, and the cause of protein loss remained unknown. CONCLUSION: The 99mTc-HSA scan is useful in the evaluation of children with PLE, especially those with severe hypoproteinemia and hypoalbuminemia, presumably reflecting a high rate of protein loss.  (+info)

Protein-losing enteropathy is associated with peritoneal functional abnormalities in peritoneal dialysis patients. (6/137)

OBJECTIVE: To evaluate the relationship between acquired peritoneal transport disorders and the presence of protein-losing enteropathy (PLE), and their contribution to the protein malnutrition in peritoneal dialysis (PD) patients. PATIENTS AND METHODS: We studied 31 clinically stable PD patients that received a fat overload diet for 3 days. We measured intestinal absorption of fecal fat (normal < 6 g/24-hour stool) and nitrogen (normal < 2 g/24-hr stool), intestinal protein permeability [fecal clearance of alpha1-antitrypsin (Calpha1AT) (normal < 12 mL/24-hr stool)], and nutritional markers [normalized protein nitrogen appearance (nPNA), half-life medium-term proteins, and body mass index]. Peritoneal solute transport was measured by mass transfer coefficient (MTC), and water transport by peritoneal ultrafiltration (UF) capacity. To define protein maldigestion it was necessary to find high fecal nitrogen values with normal Calpha1AT; PLE was defined when both values were elevated. RESULTS: High fecal nitrogen (mean 2.1+/-1 g/24-hr stool) and fat (mean 5.8+/-3.6 g/24-hr stool) were found in 15 patients; 6 patients had high Calpha1AT levels (PLE). These 6 patients showed a worse nutritional status: lower albumin (3.57+/-0.57 g/dL vs 3.98+/-0.38 g/dL, p < 0.05) and transferrin (243+/-70 mg/dL vs 272+/-44.3 mg/dL, p < 0.05), as well as lower triglycerides (131.3+/-31.7 mg/dL vs 187+/-116 mg/dL, p< 0.05). Higher urea MTCs were found in 10 patients, normal in 7, and lower in 14. Higher creatinine MTCs were found in 8 patients, normal in 15, and lower in 8. Normal peritoneal UF capacity was found in 25 and lower in 6 patients. These 6 patients showed higher urea and creatinine MTCs and Calpha1AT. A positive linear correlation between Calpha1AT, urea MTC (r = 0.56, p < 0.01), and creatinine MTC (r = 0.46, p < 0.01) was found. A similar situation occurred between Calpha1AT, fecal fat (r = 0.45, p < 0.05), and fecal nitrogen (r = 0.43, p < 0.05). Thirteen patients with previous history of peritonitis showed higher Calpha1AT than those without peritonitis (10.2+/-8 mL/24-hr stool vs 5.2+/-4.4 mL/24-hr stool, p < 0.05). CONCLUSIONS: We confirm that protein and fat malabsorption, maldigestion, and PLE are present in some PD patients. Higher fecal Calpha1AT is associated with malnutrition and poorer showings of the viability markers of peritoneal membrane function.  (+info)

Reduced heparan sulfate accumulation in enterocytes contributes to protein-losing enteropathy in a congenital disorder of glycosylation. (7/137)

Intestinal biopsy in a boy with gastroenteritis-induced protein-losing enteropathy (PLE) showed loss of heparan sulfate (HS) and syndecan-1 core protein from the basolateral surface of the enterocytes, which improved after PLE subsided. Isoelectric focusing analysis of serum transferrin indicated a congenital disorder of glycosylation (CDG) and subsequent analysis showed three point mutations in the ALG6 gene encoding an alpha1,3-glucosyltransferase needed for the addition of the first glucose to the dolichol-linked oligosaccharide. The maternal mutation, C998T, causing an A333V substitution, has been shown to cause CDG-Ic, whereas the two paternal mutations, T391C (Y131H) and C924A (S308R) have not previously been reported. The mutations were tested for their ability to rescue faulty N:-linked glycosylation of carboxypeptidase Y in an ALG6-deficient Saccharomyces cerevisiae strain. Normal human ALG6 rescues glycosylation and A333V partially rescues, whereas the combined paternal mutations (Y131H and S308R) are ineffective. Underglycosylation resulting from each of these mutations is much more severe in rapidly dividing yeast. Similarly, incomplete protein glycosylation in the patient is most severe in rapidly dividing enterocytes during gastroenteritis-induced stress. Incomplete N:-linked glycosylation of an HS core protein and/or other biosynthetic enzymes may explain the selective localized loss of HS and PLE.  (+info)

Surgical management of Menetrier's disease with protein-losing gastropathy. (8/137)

Three patients with Menetrier's disease and protein-losing gastropathy who were studied during a 12 year period have been presented. The characteristic findings which differentiate them from patients with hypertrophic hypersecretory gastropathy, including the Zollinger-Ellison syndrome, are: 1) hypertrophy of gastric mucosa with giant rugal folds involving the fundus, cardia and body of the stomach but sparing the antrum; 2) muscosal hypertrophy consisting of gastric mjcus-secreting cells while parietal cells and chief cells are diminished in number and may be absent from many microscopic sections; 3) gastric secretion of large volume containing excess mucus, low to absent hydrochloric acid and protein concentration 5 or 6 times normal (1.7 mg/ml); 4) hypoalbuminemia and hypoglobulinemia due to loss of serum proteins fron gastric mucosa into the gastric lumen; 5) rare association with gastric ulcer. Unlike the Zollinger-Ellison syndrome none of our patients had duodenal ucler or multiple endocrine adenomatosis or a family history of these conditions. We have found no authenticated reports in the literature which document a relationship of Menetrier's disease ( as defined above) with multiple endocrine adenomatosis. Menetrier's disease with protein-losing gastropathy is a potentially lethal disorder of unknown cause with no specific treatment. Resection of the site of gastric protein losses as first done by Waugh is logical and effective. One of our three patients died in hospital before gastrectomy was done. Two others have done well for 11 months and 12 years, respectively, after total gastrectomy with Roux-en-Y esophagojejunostomy and Hunt-Lawrence jejunal pouch.  (+info)

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