UMLS:C0948265 - FACTA Search

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Query: UMLS:C0948265 (metabolic syndrome)
24,271 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Nonalcoholic fatty liver disease (NAFLD) is a frequent and potentially progressive chronic liver disease that occurs in subjects who do not abuse alcohol. NAFLD is often associated with obesity, metabolic syndrome and insulin resistance and its more aggressive form, nonalcoholic steatohepatitis (NASH) is a major cause of cryptogenic cirrhosis. NAFLD/NASH are commonly detected because of elevated serum aminotransferase levels, ultrasonographic fatty liver and, at liver histology, steatosis, inflammation, and occasionally fibrosis that may progress to cirrhosis. No established treatment exists for this potentially serious disorder. Current management of NAFLD/NASH is largely conservative and includes diet regimen, aerobic exercise, and interventions towards the associated metabolic abnormalities. The main concern is therefore to decrease liver steatosis and its progression toward steatohepatitis and fibrosis, and the risk of "cryptogenic" cirrhosis. Among the most promising medications, weight reducing drugs, insulin sensitizers and lipid-lowering agents, antioxidants, bile salts, co-factors increasing the mitochondrial transport of fatty acids are being considered. Among them, thiazolidinediones are the most promising drug family that act by activating PPARgamma nuclear receptors and by regulating both microsomal and peroxisomal lipid oxidative pathways. Pharmacological treatment of obesity and probiotics should be considered as potential therapeutic options. In this review, after summarizing the general background on fatty liver, the most current and attractive pharmacological approaches to the problem of NAFLD/NASH are discussed.
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PMID:Current pharmacological treatment of nonalcoholic fatty liver. 1707 35

Drugs that reverse insulin resistance are of importance as insulin resistance is frequently associated with type 2 diabetes. The three peroxisome proliferator-activated receptors (PPARs) PPARalpha, PPAR90 and PPARgamma are essential for the actions of the many insulin sensitizers. PPARalpha activation enhances free fatty acid oxidation and potentiates anti-inflammatory effects, while PPARgamma is essential for normal adipocyte differentiation and proliferation, as well as fatty acid uptake and storage. Thiazolidinediones (TZDs) are selective ligands of PPARgamma and act as insulin sensitizers. TZDs also suppress free fatty acids via the inhibition of lipolysis in adipose tissue. Insulin sensitizers currently under development include partial PPARgamma agonists and antagonists, and dual PPARalpha/PPARgamma agonists. Given that TZDs show anti-inflammatory, anti-oxidant and antiprocoagulant properties in addition to their insulin sensitizing and antilipotoxic properties, a case may be made for initiating TZD therapy early in the treatment of type 2 diabetes, particularly in those patients at risk of cardiovascular disease. TZDs may also be an important therapeutic option in the treatment of metabolic syndrome.
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PMID:Insulin resistance and PPAR insulin sensitizers. 1708 33

Peroxisome Proliferator-Activate Receptors (PPARs) are transcription factors belonging to the nuclear receptor superfamily. The three PPARs (alpha, beta/delta, and gamma) are distributed differently in the different organs. PPARalpha is most common in the liver, but also found in kidney, gut, skeletal muscle and adipose tissue, while PPARbeta/delta, is fairly ubiquitous; it may be found in body tissues and brain (for myelination process and lipid metabolism in the brain). PPARgamma has 3 isoforms, such as PPARgamma 1, PPARgamma 2, and PPARgamma 3. The syndrome-X was firstly coined by Reaven in 1988 and then to be provided in 1999 by the name : the metabolic syndrome-X. This metabolic syndrome represents a "Cluster" of metabolic disorders and cardiovascular risk factors which has been collected and summarized by the author and such a cluster includes: insulin resistance/hyperinsulinemia, central obesity, glucose intolerance/DM, atherogenic dyslipidemia (increase TG, decrease HDL-cholesterol, increase Apo-B, increase small dense LDL), hypertension, prothrombotic state (increase PAI-1, increase F-VII, increase fibrinogen, increase vWF, increase adhesion molecules), endothelial dysfunction, hyperuricemia, and increased hsC-RP and cytokines. The metabolic syndrome-X may lead to the development of T2DM and coronary heart disease (CHD); insulin resistance plays pivotal roles in the progression of such a syndrome and cardiovascular diseases. Improvement of Insulin Resistance, therefore, is most likely to reduce the high cardiovascular event rate in T2DM. It has been generally accepted that Insulin Resistance (detected by HOMA-R) and Acute Insulin Response = AIR (by HOMA-B) are both usually present in T2DM. The Thiazolidinedions (TZDs) are Insulin Sensitizers (e.g Rosiglitazone = ROS, Pioglitazone = PIO) introduced into clinical practice in 1997; clinical evidence data showed that TZDs improved both HOMA-R, and HOMA-B. PPARgamma can be activated by TZDs and it appears to be fundamental to the pathophysiology of diabetes mellitus i.e increase GLUT-4, increase glucokinase, decrease PEPCK, increase GLUT-4, and decreases production by fat cell of several mediators that may cause insulin resistance, such as TNFalpha and resistin. PPARgamma also mediates increased production of Adiponectin and the insulin signaling intermediate PI3K, and both actions lead to increase insulin sensitivity. A "dual PPARgamma-PPARalpha agonists" (e.g PIO, but ROS poorly activate PPARalpha) might lower glucose and modulate lipids. Thus, PIO, as a stronger "dual PPARgamma-PPARalpha agonists", shows an important therapeutic pathway in diabetes mellitus and cardiovascular diseases, even in metabolic syndrome. Current evidence suggests a close relationship between activation of PPARgamma and restoration of insulin sensitivity by reductions in TNFalpha and FFAs, and the enhancement of insulin stimulation of PI3-K Pathway and also increase adiponectin & decrease resistin.
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PMID:New approach in the treatment of T2DM and metabolic syndrome (focus on a novel insulin sensitizer). 1711 68

Insulin resistance is the major feature of the metabolic syndrome and depends on insulin secretion and insulin sensitivity. In chronic hepatitis C, insulin resistance and type 2 diabetes mellitus are more often seen than in healthy controls or chronic hepatitis B patients. Hepatitis C virus (HCV) infection promotes insulin resistance, mainly by increased TNF production together with enhancement of suppressor of cytokine (SOC-3); both events block PI3K and Akt phosphorylation. Two types of insulin resistance could be found in chronic hepatitis C patients: "viral" and "metabolic" insulin resistance. Insulin resistance in chronic hepatitis C is relevant because it promotes steatosis and fibrosis. The mechanisms by which insulin resistance promotes fibrosis progression include: (1) steatosis, (2) hyperleptinemia, (3) increased TNF production, (4) impaired expression of PPARgamma receptors. Lastly, insulin resistance has been found as a common denominator in patients difficult-to-treat like cirrhotics, overweight, HIV coinfected and Afro-American. Insulin resistance together with fibrosis and genotype has been found to be independently associated with impaired response rate to peginterferon plus ribavirin. Indeed, in genotype 1, the sustained response rate was twice (60%) in patients with HOMA < or = 2 than patients with HOMA > 2. In experiments carried out on Huh-7 cells transfected by full length HCVRNA, interferon alpha blocks HCV replication. However, when insulin (at doses of 128 microU/mL, similar that seen in the hyperinsulinemic state) was added to interferon, the ability to block HCV replication disappeared, and the PKR synthesis was abolished. In summary, hepatitis C promotes insulin resistance and insulin resistance induces interferon resistance, steatosis and fibrosis progression.
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PMID:Insulin resistance and hepatitis C. 1713 67

The three peroxisome-proliferator-activated receptor (PPAR) subtypes PPAR-alpha, PPAR-gamma, and PPAR-delta are ligand-activated transcription factors of the nuclear receptor family. PPARs form obligate heterodimers with the retinoid X receptor, which bind to peroxisome-proliferator-response elements (PPREs). PPAR-alpha is expressed mainly in liver, brown fat, kidney, heart, and skeletal muscle; PPAR-gamma in intestine and adipose tissue; PPAR-alpha and PPAR-gamma are both expressed in vascular endothelium, smooth muscle cells, macrophages, and foam cells; PPAR-delta in skeletal muscle, human embryonic kidney, intestine, heart, adipose tissue, developing brain, and keratinocytes. Intense interest in the development of drugs with new mechanisms of action for the metabolic syndrome has focused attention on nuclear receptors, such as PPARs that function as regulators of energy homeostasis. Agonists of PPAR-alpha and PPAR-gamma are currently used to treat diabetic dyslipidemia and type 2 diabetes. Dual PPAR-alpha/gamma agonists and PPAR-alpha/gamma/delta pan-agonists are under investigation for treatment of cardiovascular disease and the metabolic syndrome. Selective PPAR modulators (SPPARMs) are PPAR ligands that possess desirable efficacy and improved tolerance. Efforts are being made to identify novel partial agonists or antagonists for PPAR-gamma in order to combine their antidiabetic and antiobesity effects. Glucocorticoids are major mediators of the stress response and could be the link between stress and PPAR activator signaling and thus may affect the downstream metabolic pathways involved in fuel homeostasis.
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PMID:Targeting components of the stress system as potential therapies for the metabolic syndrome: the peroxisome-proliferator-activated receptors. 1714 46

In human organism, the administration of nicotinic acid (niacin) leads to two types of effects. Within the physiological range (approximately = 20 mg/day), niacin has a vitamin-like role as pellagra preventing factor. The pharmacological dosage (approximately 0,5-4,5 g/day) substantially influences the plasma lipid and lipoprotein concentrations: decreases VLDL and LDL concentrations, changes the profile of LDL subfractions towards the larger particles as well as particles with lower density; it also profoundly increases the concentration of HDL-C in consequence of elevated concentration of HDL2 subfraction. Niacin as the only hypolipidemic drug reduces the lipoprotein(a) concentration. The hypolipidemic mechanism of niacin is different from that of other hypolipidemic drugs. On the basis of clinically controlled trials (both interventional epidemiological and angiographical), which satisfy the criteria of evidence-based medicine, it is possible to conclude that niacin falls unambiguously into the class of hypolipidemic drugs with proven beneficial effect not only on cardiovascular mortality and morbidity, but also on total mortality. Therefore, niacin should have an indisputable role in the pharmacological control of dyslipidemias. With the respect of basic mechanism (inhibition of the lipolysis of adipose tissue) with subsequent decrease in the concentration of free fatty acids and their flux to liver, niacin fulfils the criteria for pathogenetic treatment of atherogenic dyslipidemia in metabolic syndrome. The prerequisite condition for the niacin treatment is the respect for serious adverse effects and possible health hazards of administration (skin flush, hepatotoxicity and deterioration of glucose homeostasis). Recently discovered extrahypolipidemic effects of niacin (antioxidative activity, facilitation of reverse cholesterol transport, activation of PPAR-gamma, antithrombotic effects) and the introduction of drug forms with sustained (extended resp.) release of active compound (that minimizes the adverse effects and administration hazards) form together the basis for firm statement that the derivatives of nicotinic acid should be introduced to the clinical practice in Czech Republic.
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PMID:[Nicotinic acid: an unjustly neglected remedy]. 1716 12

Intensive preclinical investigations have delineated a role for peroxisome proliferator-activated receptors (PPARs) in energy metabolism and inflammation. PPARs are activated by natural lipophilic ligands such as fatty acids and their derivatives. Normalization of lipid and glucose metabolism is achieved via pharmacological modulation of PPAR activity. PPARs may also alter atherosclerosis progression through direct effects on the vascular wall. PPARs regulate genes involved in the recruitment of leukocytes to endothelial cells, in vascular inflammation, in macrophage lipid homeostasis, and in thrombosis. PPARs therefore modulate metabolic and inflammatory perturbations that predispose to cardiovascular diseases and type 2 diabetes. The hypolipidemic fibrates and the antidiabetic thiazolidinediones are drugs that act via PPARalpha and PPARgamma, respectively, and are used in clinical practice. PPARbeta/delta ligands are currently in clinical evaluation. The pleiotropic actions of PPARs and the fact that chemically diverse PPAR agonists may induce distinct pharmacological responses have led to the emergence of new concepts for drug design. A more precise understanding of the molecular pathways implicated in the response to chemically distinct PPAR agonists should provide new opportunities for targeted therapeutic applications in the management of the metabolic syndrome, type 2 diabetes, and cardiovascular diseases.
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PMID:Drug Insight: mechanisms of action and therapeutic applications for agonists of peroxisome proliferator-activated receptors. 1723 41

The most common pathology associated with obesity is insulin resistance, which results in the onset of type 2 diabetes mellitus. Several studies have implicated the mammalian target of rapamycin (mTOR) signaling pathway in obesity. Eukaryotic translation initiation factor 4E-binding (eIF4E-binding) proteins (4E-BPs), which repress translation by binding to eIF4E, are downstream effectors of mTOR. We report that the combined disruption of 4E-BP1 and 4E-BP2 in mice increased their sensitivity to diet-induced obesity. Increased adiposity was explained at least in part by accelerated adipogenesis driven by increased expression of CCAAT/enhancer-binding protein delta (C/EBPdelta), C/EBPalpha, and PPARgamma coupled with reduced energy expenditure, reduced lipolysis, and greater fatty acid reesterification in the adipose tissue of 4E-BP1 and 4E-BP2 double KO mice. Increased insulin resistance in 4E-BP1 and 4E-BP2 double KO mice was associated with increased ribosomal protein S6 kinase (S6K) activity and impairment of Akt signaling in muscle, liver, and adipose tissue. These data clearly demonstrate the role of 4E-BPs as a metabolic brake in the development of obesity and reinforce the idea that deregulated mTOR signaling is associated with the development of the metabolic syndrome.
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PMID:Elevated sensitivity to diet-induced obesity and insulin resistance in mice lacking 4E-BP1 and 4E-BP2. 1727 54

The nutritional environment encountered during fetal life is strongly implicated as a determinant of lifelong metabolic capacity and risk of disease. Pregnant rats were fed a control or low-protein (LP) diet, targeted to early (LPE), mid-(LPM), or late (LPL) pregnancy, or throughout gestation (LPA). The offspring were studied at 1, 9, and 18 mo of age. All LP-exposed groups had similar plasma triglyceride, cholesterol, glucose, and insulin concentrations to those of controls at 1 and 9 mo of age, but by 18 mo there was evidence of LP-programmed hypertriglyceridemia and insulin resistance. All LP-exposed groups exhibited histological evidence of hepatic steatosis and were found to have two- to threefold more hepatic triglyceride than control animals. These phenotypic changes were accompanied by age-related changes in mRNA and protein expression of the transcription factors SREBP-1c, ChREBP, PPARgamma, and PPARalpha and their respective downstream target genes ACC1, FAS, L-PK, and MCAD. At 9 mo of age, the LP groups exhibited suppression of the SREBP-1c-related lipogenic pathway but between 9 and 18 mo underwent a switch to increased lipogenic capacity with a lower expression of PPARgamma and MCAD, consistent with reduced lipid oxidation. The findings indicate that prenatal protein restriction programs development of a metabolic syndrome-like phenotype that develops only with senescence. The data implicate altered expression of SREBP-1c and ChREBP as key mediators of the programmed phenotype, but the basis of the switch in metabolic status that occurred between 9 and 18 mo of age is, as yet, unidentified.
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PMID:Prenatal exposure to a low-protein diet programs disordered regulation of lipid metabolism in the aging rat. 1729 84

In animal experiments, the potent antioxidant and free radical scavenger alpha-lipoic acid has been shown to cause weight loss, ameliorate insulin resistance and atherogenic dyslipidemia, as well as to lower blood pressure, all of these being components of the metabolic syndrome. Recent investigations on its mechanisms of action indicate that alpha-lipoic acid can affect central and peripheral modulation of 5'-AMP-activated protein kinase, activate PPAR-alpha and PPAR-gamma, modulate PPAR-regulated genes and upregulate the expression of PPAR-gamma mRNA and protein in cardiac tissue and aorta smooth muscle. To a large extent, these findings can explain the observed beneficial metabolic effects of alpha-lipoic acid, supporting its potential application as a therapeutic agent for the treatment of the metabolic syndrome.
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PMID:Alpha-lipoic acid: physiologic mechanisms and indications for the treatment of metabolic syndrome. 1730 24

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