Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0023890 (cirrhosis)
42,195 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The functional hepatic nitrogen clearance during amino acid infusion is a measure of liver cell mass. The clinical feasibility of the test has so far been limited by methodological problems. A simplified procedure was used to measure the urea-nitrogen synthesis rate and functional hepatic nitrogen clearance in nine subjects with normal liver function and in nine patients with cirrhosis. The method was based on only four consecutive 2-hr urine collections and five blood samples. Total body water was calculated from a nomogram based on age and anthropometric data, whereas the gut urea hydrolysis was assigned one fixed fraction of synthesis (0.17 in control subjects and 0.26 in patients with cirrhosis). Finally, a solution of a single amino acid, alanine, was infused as substrate for urea synthesis. Urea-nitrogen synthesis rate increased linearly with increasing alpha-amino-nitrogen concentration, and the slope of the regression (functional hepatic nitrogen clearance) was reduced in cirrhosis from 37.5 +/- 7.0 L/hr to 18.4 +/- 6.7 L/hr; p less than 0.005. The hepatic nitrogen clearance was linearly related to the clinical status (Child-Pugh score), to routine liver function tests and to galactose elimination capacity (r = 0.869), a well-established, quantitative, liver function measure. The simplified method makes the measurement of hepatic nitrogen clearance suitable for routine clinical use. The test might prove useful to study the alterations of nitrogen metabolism in cirrhosis, with special reference to hepatic encephalopathy.
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PMID:Hepatic amino-nitrogen clearance to urea-nitrogen in control subjects and in patients with cirrhosis: a simplified method. 199 17

An attempt was made to estimate noninvasively portal pressure (PP) in patients with chronic liver disease, using the theory of quantification, a kind of multivariate analysis. Forty-one patients with liver cirrhosis and 22 patients with chronic hepatitis in whom hepatic venous catheterization had been performed were studied. Seventeen parameters (age, sex, mean blood pressure, red blood cell count, platelet count, prothrombin time, lactate dehydrogenase, alkaline phosphatase, total bilirubin, albumin, gamma-globulin, indocyanine green retention at 15 min, blood urea nitrogen, hepatomegaly, splenomegaly, ascites and edema) were selected for the estimation of PP. The estimated PP correlated significantly with the data obtained by hepatic venous catheterization with a high correlation coefficient of 0.835 (p less than 0.01). An investigation using the theory of quantification was also undertaken to determine which of the 17 parameters selected above was most useful in estimating PP. Among the 17 parameters indocyanine green retention at 15 min, red blood cell count, prothrombin time, hepatomegaly and splenomegaly seemed to contribute significantly to the estimation of PP. When the formula was applied to 31 successive patients with chronic liver disease (external samples), the correlation between the estimated and measured PP was 0.455 (p less than 0.01). These results indicate that the formula is clinically useful in estimating PP in patients with chronic liver disease.
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PMID:[Estimation of portal pressure using the theory of quantification]. 201 41

This case describes a patient with cholesteryl ester storage disease who underwent liver transplantation for progressive cirrhosis, portal hypertension, ascites, and uncontrollable gastrointestinal bleeding. Four and one-half years posttransplant, her growth improved, cholesterol levels have returned to normal, and she is clinically well except for mild hypersplenism and an elevated blood urea nitrogen (BUN) and creatinine. Serum triglycerides remain elevated, but there have been no signs of progressive renal, intestinal, vascular, or pulmonary disease.
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PMID:Liver transplantation for cholesteryl ester storage disease. 207 31

The liver is actively involved in the metabolism of the sulphur-containing essential amino acid, methionine. Methionine is transformed into S-adenosyl-L-methionine (SAMe) and then into sulphur-containing metabolites (cysteine, taurine and glutathione) via the trans-sulphuration pathway. Liver disease may affect the trans-sulphuration pathway and decrease the clearance of methionine, which leads to increased fasting methionine concentrations in blood and reduced formation of cysteine and glutathione. There is evidence that this defect, located at the level of SAMe-synthetase, may cause nutritional defects and contribute to negative nitrogen balance whenever non-essential sulphur-containing amino acids are not supplied in adequate amounts. In addition, cirrhotic patients may be at increased risk of hepatotoxicity after treatment with substances which are detoxified via glutathione. The SAMe-synthetase block may be overcome by administration of oral or intravenous SAMe, which improves the fasting amino acid profile and increases the hepatic glutathione concentration. Controlled studies on long term SAMe treatment in patients with cirrhosis are needed to confirm this possible beneficial effect.
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PMID:Mechanisms and consequences of the impaired trans-sulphuration pathway in liver disease: Part II. Clinical consequences and potential for pharmacological intervention in cirrhosis. 208 82

The major biological functions of S-adenosyl-L-methionine (SAMe) include methylation of various molecules (transmethylation) and synthesis of cysteine (trans-sulphuration). A stable double salt of SAMe has been found to be effective in intrahepatic cholestasis. The mechanism of its therapeutic effect is not fully understood but presumably involves methylation of phospholipids. Methylation of plasma membrane lipids may affect membrane fluidity and viscosity, which modulate the activities of a number of membrane-associated enzymes, for example, the activity of enzymes involved in Na+/Ca++ exchange (e.g. sarcolemmal vesicles), Na+/K+ adenosine triphosphatase (ATPase) [e.g. hepatocyte plasma membranes], and Na+/H+ exchange (e.g. plasma membranes of colonic cells). Recently, patients with cirrhosis were shown to have an acquired metabolic block in the hepatic conversion of methionine to SAMe. These patients, when administered conventional elemental diets, develop abnormally low plasma concentrations of cysteine and choline, 2 nonessential nutrients present in low concentrations in most elemental diets. These low concentrations probably reflect systemic deficiencies attributable to reduced endogenous syntheses of cysteine and choline caused by limited availability of hepatic SAMe. Such cirrhotic patients are often in negative nitrogen balance and have abnormal hepatic functions, which are corrected by cysteine and choline supplements. Noncirrhotic patients on parenteral elemental diets also become deficient in cysteine and choline. Consequently, these patients may require SAMe as an essential nutrient to normalise their overall hepatic transmethylation and trans-sulphuration activities.
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PMID:Biochemistry and pharmacology of S-adenosyl-L-methionine and rationale for its use in liver disease. 208 85

Ammonia is generated from a large number of metabolically important reactions. Despite its central importance in whole body nitrogen homeostasis excess ammonia is neurotoxic and its concentration must be kept low. Ammonia generated in most extrahepatic tissues is detoxified by incorporation into glutamine (amide). This glutamine may be used in a number of biosynthetic reactions (e.g. in pyrimidine synthesis). Alternatively, as a means of maintaining nitrogen balance, glutamine may be released to the blood. Resting skeletal muscle is particularly important 1) as a "sink" for removal of blood ammonia, and 2) as a major source of circulating glutamine. However, during vigorous exercise skeletal muscle may become a net contributor of ammonia to the blood. A few tissues and cell types (e.g. lymphocytes, macrophages, enterocytes, colonocytes, thymocytes, fibroblasts, bone) and tumors exhibit marked rates of glutamine utilization. In the kidney, glutamine is an important source of urinary ammonia. Ammonia generated from 1) the breakdown of nitrogenous substances in the gut, and 2) from the use of glutamine as a metabolic fuel in the small intestine, is taken up by the liver wherein it is detoxified by conversion to urea and to a lesser extent, glutamine. Some portal vein glutamine acts as a source of urea nitrogen. Ultimately, however, most excess ammonia nitrogen is detoxified indirectly (via glutamine (blood)----glutamine (small intestine)----ammonia (portal vein) or directly in the liver as urea. Portal-systemic shunting of blood, as occurs in chronic cirrhosis of the liver or following the surgical construction of a portacaval shunt results in portal blood bypassing the normal ammonia detoxification machinery of the liver. Under this condition blood ammonia levels rise markedly, increasing the burden on extrahepatic tissues, such as skeletal muscle, brain, and kidney, in maintaining ammonia homeostasis. The most commonly employed animal model of human liver disease is the rat in which an end-to-side portacaval shunt (PCS) has been surgically constructed. Brain glutamine synthetase activity is not increased in PCS rats and in some areas of the brain there may even be a decrease in activity. The brain glutamine synthetase appears to be working at near maximal capacity. Thus, the PCS rats exhibit profound neurological dysfunction when administered ammonium salts in amounts easily tolerated by normal animals. Because of the limited capacity of brain to remove excess ammonia, a rational approach to the treatment of patients with liver disease should include a regimen directed toward lowering the associated hyperammonemia.
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PMID:Ammonia metabolism in normal and portacaval-shunted rats. 210 90

Plasma amino acid and venous blood ammonia concentrations were measured in six patients with well-compensated cirrhosis and in six healthy volunteers, both in the fasting state and serially for 5 h following ingestion of 30 g mixed protein and 30 g amino acid mixture, administered on separate occasions. Mean fasting plasma concentrations of threonine, serine, proline, glycine, and of the three branched-chain amino acids, valine, isoleucine and leucine, were significantly reduced in the cirrhotic patients compared with the control subjects, while mean (+/- 1 s.d.) fasting venous blood ammonia concentrations were comparable 71.2 +/- 31.4 cf. 56.0 +/- 25.4 mumol/L. Following the oral protein and amino acid loads, increases were observed in plasma amino acid concentrations in the majority of subjects with a return to baseline values by the end of the study. Changes in the circulating concentrations of most amino acids were independent of their concentration in the oral protein and amino acid loads, and their relative distribution in the circulation varied over time. The increases in the concentrations of the three branched-chain amino acids did, however, reflect their concentrations in the two nitrogen loads and did remain constant, relative to one another, over time. There were wide intra- and inter-individual variations in plasma amino acid concentrations following protein and amino acid ingestion in both study groups, and in general no significant differences in responses were observed between them. Similarly, no significant inter-group differences were observed in the ammonia response to the two nitrogen loads. No fundamental differences exist in the ways in which patients with well-compensated cirrhosis handle oral protein or amino acid loads of the magnitude employed in the present study.
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PMID:Amino acid tolerance in cirrhotic patients following oral protein and amino acid loads. 210 85

Nutritional support in patients with advanced cirrhosis is difficult due to protein, fluid and salt restrictions. Successful liver transplantation should improve nutrient tolerance. We randomly assigned 28 hypoalbuminemic cirrhotic patients to receive, immediately after liver transplantation, one of three regimens: group 1, no nutritional support (n = 10); group 2, total parenteral nutrition (TPN) (35 kcal/kg/day) with standard amino acids (1.5 g/kg/day) (n = 8); or group 3, isocaloric isonitrogenous TPN with added branched-chain amino acids (n = 10). Therapy was continued for 7 days posttransplant. Jaundice resolution was unaffected by nutritional support. Nitrogen balance favored both TPN groups. Branched-chain amino acid (BCAA) aromatic amino acid ratios were highest in group 3. Coma scores and serum ammonia levels were similar in all groups. Both TPN groups achieved respirator independence earlier; this difference was not statistically significant. Group 1 patients stayed longest in ICU; the difference was statistically significant. TPN with either standard or BCAA- enriched amino acids is tolerated well immediately after successful liver transplant. Positive nitrogen balance is achieved; large protein loads do not worsen encephalopathy. Nutritional support may improve respiratory muscle function, allowing earlier weaning from ventilatory support. A shortened length of ICU stay justifies the expense of TPN.
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PMID:Nutritional support after liver transplantation: a randomized prospective study. 179 69

To study the consequences of hyperglycemia on glucose and nitrogen metabolism in cirrhosis, an hyperglycemic clamp was performed in 5 cirrhotic patients and 5 normal controls during two subsequent periods of 90 min, at 7.78 and then at 13.89 mmol/l. In the first period, glucose infusion and metabolic clearance rates were decreased in cirrhotics vs controls (p less than 0.05). In the second period, this difference between the two groups disappeared because of a more important enhancement in cirrhotics. Baseline plasma C peptide levels and those during hyperglycemia were the same during hyperglycemia in both groups, but plasma insulin level rose more in cirrhotics (p less than 0.05). Baseline insulin secretion following IV glucagon was reduced in cirrhotics vs controls (p less than 0.05), but became normal in the hyperglycemic state. Plasma glucagon levels were enhanced at all times in cirrhotics vs controls (p less than 0.01), but dropped more in cirrhotics vs controls (p less than 0.05). Insulin responsiveness, defined as the "glucose consumption: plasma insulin concentration" ratio was reduced in cirrhotics at 7.78 mmol/l (p less than 0.01), but was the same in both groups at 13.80 mmol/l because of a more important enhancement in cirrhotics, reflecting an improvement of insulin action probably at the post-receptor level and of non-insulin-mediated glucose transport. Hyperglycemia induced a drop in plasma concentration and muscular release of all aminoacids, excepted alanine, between the basal state and the end of the study. Aminoacid concentration rose only in cirrhotics, without any change in muscular output. In the same time, blood ammonia level rose only in cirrhotics, without reduction of muscular uptake.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Consequences of hyperglycemia on glucose and nitrogen metabolism in liver cirrhosis. A study using a hyperglycemic clamp]. 219 90

This study was conducted to determine whether an amino acid solution enriched with branched-chain amino acids altered protein catabolic rates and plasma ammonia in patients with cirrhosis. Nine stable subjects were given two peripheral intravenous infusions: a standard amino acid solution (solution A) and a branched-chain-enriched solution containing 97% more leucine (solution B). Each solution was given for separate 9-day (group 1, n = 6) or 3-day (group 2, n = 3) periods. Amino acid solutions delivered 0.7 gm protein.kg-1.day-1. Diets provided an additional 0.3 gm protein plus maintenance calories. Protein turnover was assessed by a primed continuous infusion of [1-14C] leucine in six patients (three patients in group 1 and three patients in group 2). Nitrogen balance and urinary 3-methyl histidine excretion were determined in group 1 patients. Compared with solution A, solution B increased leucine flux and leucine oxidation but had no significant effect on protein synthesis or catabolism based on the plasma specific activity of either leucine or alpha-ketoisocaproic acid. The additional leucine infused with solution B was quantitatively oxidized. Nitrogen balance did not differ with the two solutions and there was also no difference in the urinary excretion of 3-methyl histidine, suggesting that muscle protein catabolism was unchanged. Plasma ammonia concentration decreased significantly during the infusion of solution B and was associated with a slight fall in plasma glucagon concentration. The results indicated that a branched-chain-enriched amino acid solution did not alter protein synthesis or catabolism although it did lower the plasma ammonia when compared with a standard amino acid formula in stable cirrhotic patients.
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PMID:Effects of branched-chain amino acids on nitrogen metabolism in patients with cirrhosis. 219 23


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