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Query: UMLS:C0015695 (fatty liver)
 13,941 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The lipid content of hepatocytes is regulated by the integrated activities of cellular enzymes that catalyze lipid uptake, synthesis, oxidation, and export. When "input" of fats into these systems (either because of increased fatty acid delivery, hepatic fatty acid uptake, or fatty acid synthesis) exceeds the capacity for fatty acid oxidation or export (i.e., "output"), then hepatic steatosis occurs. Genetic causes of increased fatty acid input promote excessive hepatic lipogenesis. These include mutations that cause leptin deficiency or leptin receptor inhibition and mutations that induce insulin, insulin-like growth factors, or insulin-responsive transcription factors. Genetic causes of impaired hepatic fatty acid oxidation inhibit the elimination (i.e., output) of fat from the liver. These include mutations that inhibit various components of the peroxisomal and/or mitochondrial pathways for fatty acid beta-oxidation. Environmental factors, such as diets and toxins, can also unbalance hepatic fatty acid synthesis and oxidation. Hepatic lipogenesis is increased by dietary sucrose, fructose, or fats and certain toxins, such as ethanol. Hepatic fatty acid oxidation is inhibited by choline- or methionine-deficient diets and other toxins, such as etomoxir. Animals with genetic or environmental induction of hepatic lipogenesis appear to be useful models for human nonalcoholic fatty liver disease in which hyperinsulinemia and defective leptin signaling are conspicuous at early stages of the disease process.
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PMID:Animal models of steatosis. 1129

Fatty liver is a relatively common incidental finding on imaging studies. Although generally a benign condition, fat in the liver can be troubling for clinicians because it can cause persistently elevated liver enzyme levels. The finding of fatty liver may also indicate the presence of nonalcoholic steatohepatitis (NASH). NASH is a histologic diagnosis applied to a constellation of liver biopsy findings that appear similar to alcoholic liver disease but are found in the absence of alcohol abuse. NASH is typically identified during the evaluation of elevated aminotransferase levels after exclusion of viral, metabolic, and other causes of liver disease. Obesity is a major risk factor; the role of diabetes is less certain, although evidence is accumulating that hyperinsulinism may play an important pathophysiologic role. About 15% to 40% of NASH patients develop hepatic fibrosis, a precursor to cirrhosis. Exactly how many patients with NASH progress to cirrhosis is unknown, but 1% to 2% of liver transplants are now performed because of a pretransplant diagnosis of NASH. Specific and effective treatments are needed but until the pathogenesis of this common liver disease is better understood, weight loss will remain the mainstay of treatment for obese patients.
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PMID:Fatty liver and nonalcoholic steatohepatitis. 1150 Nov 94

Nonalcoholic steatohepatitis (NASH) is increasingly recognized as a relatively prevalent disorder (ie, occurring in 3% of adults) that may progress to cirrhosis in 15% to 40% of those who are afflicted. NASH is a subset of a broader diagnostic category, nonalcoholic fatty liver disease, a term applied to a condition involving the presence of excess fat in the liver with or without inflammation and cellular injury. A diagnosis of NASH is established by the presence of morphologic changes on liver biopsy similar to those seen in alcoholic hepatitis, including hepatocellular fat accumulation, evidence of lobular inflammation and cell injury, and in some cases, progressive fibrosis. Obesity and type 2 diabetes, two conditions associated with insulin resistance, are major risk factors for the development of NASH. Accumulating evidence suggests that the hyperinsulinemia associated with insulin resistance may be important in the pathogenesis of NASH. Clinical trials will now determine whether treatment of insulin resistance is an effective therapy for NASH.
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PMID:Evolving pathophysiologic concepts in nonalcoholic steatohepatitis. 1182 39

The primary genetic, environmental, and metabolic factors responsible for causing insulin resistance and pancreatic beta-cell failure and the precise sequence of events leading to the development of type 2 diabetes are not yet fully understood. Abnormalities of triglyceride storage and lipolysis in insulin-sensitive tissues are an early manifestation of conditions characterized by insulin resistance and are detectable before the development of postprandial or fasting hyperglycemia. Increased free fatty acid (FFA) flux from adipose tissue to nonadipose tissue, resulting from abnormalities of fat metabolism, participates in and amplifies many of the fundamental metabolic derangements that are characteristic of the insulin resistance syndrome and type 2 diabetes. It is also likely to play an important role in the progression from normal glucose tolerance to fasting hyperglycemia and conversion to frank type 2 diabetes in insulin resistant individuals. Adverse metabolic consequences of increased FFA flux, to be discussed in this review, are extremely wide ranging and include, but are not limited to: 1) dyslipidemia and hepatic steatosis, 2) impaired glucose metabolism and insulin sensitivity in muscle and liver, 3) diminished insulin clearance, aggravating peripheral tissue hyperinsulinemia, and 4) impaired pancreatic beta-cell function. The precise biochemical mechanisms whereby fatty acids and cytosolic triglycerides exert their effects remain poorly understood. Recent studies, however, suggest that the sequence of events may be the following: in states of positive net energy balance, triglyceride accumulation in "fat-buffering" adipose tissue is limited by the development of adipose tissue insulin resistance. This results in diversion of energy substrates to nonadipose tissue, which in turn leads to a complex array of metabolic abnormalities characteristic of insulin-resistant states and type 2 diabetes. Recent evidence suggests that some of the biochemical mechanisms whereby glucose and fat exert adverse effects in insulin-sensitive and insulin-producing tissues are shared, thus implicating a diabetogenic role for energy excess as a whole. Although there is now evidence that weight loss through reduction of caloric intake and increase in physical activity can prevent the development of diabetes, it remains an open question as to whether specific modulation of fat metabolism will result in improvement in some or all of the above metabolic derangements or will prevent progression from insulin resistance syndrome to type 2 diabetes.
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PMID:Disordered fat storage and mobilization in the pathogenesis of insulin resistance and type 2 diabetes. 1194 43

Insulin resistance results in accumulation of triglyceride content and reduction of glycogen content in skeletal muscle. However, very few studies have measured lipid content and glycogen content in liver associated with insulin resistance. We studied the relationship between liver lipid content, liver glycogen, and insulin resistance in high-fat-fed rats, which are animal models of insulin resistance. High-fat-fed rats were hyperlipidemic, hyperglycemic, and hyperinsulinemic. Furthermore, the glucose infusion rates (GIR) were lower (normal rats, 10.35 +/- 1.66; high-fat-fed rats, 4.86 +/- 0.93 mg/kg/min; P <.01) and the triglyceride and cholesterol contents in liver were higher in the high-fat-fed rats than in normal rats. On the other hand, the glycogen content in liver was lower than in normal rats. There was an inverse relationship between liver triglyceride content and liver glycogen content. When the lipoprotein lipase (LPL) activator NO-1886 was administered to the high-fat-fed rats at a daily dose of 50 mg/kg body weight for 10 weeks, GIR (9.87 +/- 3.76 mg/kg/min, P <.05 v high-fat-fed control group) improved, causing an improvement of the hyperlipidemia, hyperglycemia, and hyperinsulinemia. Furthermore, NO-1886 decreased triglyceride and cholesterol concentrations and increased glycogen content in liver of the high-fat-fed rats. In this study, we found that insulin resistance caused fatty liver and reduced glycogen content in liver. Administration of the LPL activator NO-1886 improved the insulin resistance, resulting in an improvement in the relationship between triglyceride and glycogen content in liver of high-fat-fed rats.
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PMID:Correlation between lipid and glycogen contents in liver and insulin resistance in high-fat-fed rats treated with the lipoprotein lipase activator NO-1886. 1203 38

Conjugated linoleic acids (CLA) are a class of positional, geometric, conjugated dienoic isomers of linoleic acid (LA). Dietary CLA supplementation results in a dramatic decrease in body fat mass in mice, but also causes considerable liver steatosis. However, little is known of the molecular mechanisms leading to hepatomegaly. Although c9,t11- and t10,c12-CLA isomers are found in similar proportions in commercial preparations, the respective roles of these two molecules in liver enlargement has not been studied. We show here that mice fed a diet enriched in t10,c12-CLA (0.4% w/w) for 4 weeks developed lipoatrophy, hyperinsulinemia, and fatty liver, whereas diets enriched in c9,t11-CLA and LA had no significant effect. In the liver, dietary t10,c12-CLA triggered the ectopic production of peroxisome proliferator-activated receptor gamma (PPARgamma), adipocyte lipid-binding protein and fatty acid transporter mRNAs and induced expression of the sterol responsive element-binding protein-1a and fatty acid synthase genes. In vitro transactivation assays demonstrated that t10,c12- and c9,t11-CLA were equally efficient at activating PPARalpha, beta/delta, and gamma and inhibiting liver-X-receptor. Thus, the specific effect of t10,c12-CLA is unlikely to result from direct interaction with these nuclear receptors. Instead, t10,c12-CLA-induced hyperinsulinemia may trigger liver steatosis, by inducing both fatty acid uptake and lipogenesis.
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PMID:Dietary trans-10,cis-12 conjugated linoleic acid induces hyperinsulinemia and fatty liver in the mouse. 1223 71

We present clinical descriptions, metabolic features, and patterns of body fat loss of 16 patients with acquired generalized lipodystrophy (AGL) seen by us over the last 10 years. In addition, we review 63 cases of AGL reported in the literature. Based on these data, we propose new diagnostic criteria for AGL, the essential criterion being selective loss of body fat from large regions of the body occurring after birth. We also propose a subclassification of AGL into 3 varieties, type 1, the panniculitis variety; type 2, the autoimmune disease variety; and type 3, the idiopathic variety, which affect nearly 25%, 25%, and 50% of patients, respectively. Most of the patients presented in childhood and adolescence. Females were affected approximately 3 times more than males. Subcutaneous fat loss was severe and usually affected the face, trunk, abdomen, and extremities. In some patients, fat loss also involved the palms and soles and intraabdominal region; however, the bone marrow and retroorbital fat were preserved in all patients. Clinically, patients may have voracious appetite, fatigue, and acanthosis nigricans. Hepatomegaly was common, mostly due to hepatic steatosis. Most AGL patients had fasting and/or postprandial hyperinsulinemia, diabetes mellitus, hypertriglyceridemia, and low serum levels of high-density lipoprotein cholesterol, leptin, and adiponectin. Diabetes mellitus and hypertriglyceridemia were less prevalent in the panniculitis variety compared with the idiopathic and autoimmune varieties. The management of AGL includes cosmetic surgery for loss of fat. Severe hypertriglyceridemia should be treated with a very low-fat diet and omega-3 polyunsaturated fatty acid supplementation from fish oils. Management of diabetes is difficult and may necessitate insulin therapy in large doses. Insulin sensitizers such as metformin and thiazolidinediones have been used, although their long-term efficacy and safety remain unknown. Subcutaneous administration of recombinant leptin in AGL patients with hypoleptinemia effectively improves hyperglycemia, hypertriglyceridemia, and hepatic steatosis. Leptin therapy, however, remains investigational. Fibrates alone or in combination with statins may be used to treat hypertriglyceridemia.
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PMID:Clinical features and metabolic derangements in acquired generalized lipodystrophy: case reports and review of the literature. 1264 Jan 89

Nonalcoholic steatohepatitis (NASH) is one entity in a spectrum of chronic liver disease related to obesity, hyperinsulinemia, insulin resistance, and liver cell injury from free fatty acid toxicity or other oxidant stress. The more inclusive term "nonalcoholic fatty liver disease" (NAFLD) is increasingly being used to encompass the entire spectrum, which includes simple hepatic steatosis without inflammation (which may not lead to progressive liver injury), NASH itself, and the resulting cirrhosis (which may be devoid of steatosis). Children get NAFLD, and the incidence of this pediatric liver disease is rising as childhood obesity becomes increasingly prevalent. Although much remains to be learned about pediatric NAFLD, it is already evident that children with NASH risk progressive liver damage, including cirrhosis. Liver biopsy is required for definitive diagnosis, and other causes of fatty liver in childhood must be excluded. Gradual weight loss through increased regular exercise and a low-fat, low-refined carbohydrate diet appears to be effective. Drug treatments are being developed. Pediatric NASH is a serious complication of childhood obesity.
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PMID:Nonalcoholic steatohepatitis in children. 1273 49

We previously generated a strain of transgenic mice carrying the human renin gene, hRN8-12, in the background of C57BL/6j. In this study, we discovered that hRN8-12 male mice, but not females, developed obesity starting at 15 weeks of age. The body weight of 60-week-old male transgenic mice was 2 times higher than that of age-matched wild-type mice. Interestingly, male mice heterozygous for the human renin gene showed moderate weight gain compared with transgenic and wild-type mice. Obese hRN8-12 mice exhibited hyperglycemia, hyperinsulinemia, hyperleptinemia, and hyperlipidemia, and increase in weight in the adipose tissue, liver, heart, and kidneys. Histological analysis demonstrated that fatty hRN8-12 mice developed hypertrophy of pancreatic islets and fatty liver. These results suggested that hRN8-12 mice are associated with obesity dependent on the transgene dosage and should be a genetic model for late-onset obesity.
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PMID:Late-onset obesity in mice transgenic for the human renin gene. 1273 12

The study population in this report by Lin et al. was ob/ob mice that have an inherited genetic deficiency of the appetite-suppressing hormone leptin. These mice develop hyperinsulinemia, insulin resistance, and fatty livers. Compared with their lean littermates and wild-type C57BL-6 mice, ob/ob mice have hepatomegaly. In this study, the authors compared three different groups of adult mice (aged 8-10 wk), including male ob/ob C57BL-6 mice, their lean littermates, and wild-type C57BL-6 mice of the same age and sex. The primary purpose of this study was to test the efficacy of metformin for treatment of fatty liver disease in obese, ob/ob mice that develop hyperinsulinemia or insulin resistance and fatty livers. Metformin therapy was found to eliminate fatty liver disease in this model. The potential mechanisms of the action of metformin were the inhibition of hepatic tumor necrosis factor (TNF)alpha and several TNF-inducible responses, which are likely to promote hepatic steatosis and necrosis. In these experiments, ob/ob mice were divided into three treatment groups. Group 1 consisted of eight mice that were treated with metformin and permitted to consume a nutritiously replete liquid mouse diet ad libitum. Mice in group 2 (n = 8) did not receive metformin but were pair-fed the same volume of liquid diet that the mice in the metformin-treated group had consumed on the previous day. Obese ob/ob mice in group 3 (n = 4) and lean mice received no metformin, as with the mice in group 2, but were permitted to consume the liquid diet ad libitum. Liquid diet was given to facilitate accurate daily comparison of food intake among the various treatment groups. All mice were weighed at the beginning of the study and weekly thereafter until killed and then sera, fat, and liver tissues were collected. Tissues were either fixed in buffered formalin and processed from the deceased mice for histology or snap frozen in liquid nitrogen and stored until RNA and proteins were isolated. The feeding protocol was repeated with a second group of 18 ob/ob mice. After 4 wk, hepatocytes were obtained by in situ liver perfusion with collagenase and assayed for cellular adenosine triphosphate (ATP) content. In each experiment, hepatocytes isolated from 3 mice from each treatment group were suspended in a medium and pooled for subsequent analysis to evaluate cell viability, determine the number of obtained cells, and to assay cellular ATP content. These experiments were repeated using another 3 mice from each treatment group, so that analysis of hepatocytes took place from six ob/ob mice in each feeding group.Hepatic steatosis was decreased significantly only in the metformin-treated group. The authors found that metformin's beneficial effect on the fatty liver disease of mice was not due to its ability to constrain hyperphagia, nor due to decreased caloric ingestion, because the daily caloric intakes of the metformin-treated mice and the pair-fed control mice were virtually identical. These caloric intakes were consistently approximately 20% less than that of another obese control group that was permitted to consume diet ad libitum. The authors also observed no significant effect of metformin on serum glucose concentration from fed, ob/ob mice. Metformin is known to reduce hyperinsulinemia by about 40% in both of these obese hyperinsulinemic and insulin-resistant rodent strains. In conclusion, Lin et al. documented that metformin improves fatty liver disease and reverses hepatomegaly, steatosis, and aminotransferase abnormalities in mice. In addition, the authors suggest that metformin might inhibit dieting-induced redistribution of lipid from the liver to adipose tissue depots. In summary, this study identifies a potential treatment for fatty liver disease in humans.
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PMID:Current biochemical studies of nonalcoholic fatty liver disease and nonalcoholic steatohepatitis suggest a new therapeutic approach. 1449 93


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