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Query: UMLS:C0011860 (type 2 diabetes)
 57,723 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Many models of diabetes dyslipidemia are available. Animals with chemically-induced diabetes have been used to study insulin-dependent diabetes. Hypercholesterolemia in streptozotocin-induced diabetes in rats results from increased intestinal absorption and synthesis of cholesterol. Lipoproteins from diabetic rats are oxidized and demonstrate cytotoxicity, a feature which can be prevented by insulin or antioxidant treatment. Diabetic rabbits fed a cholesterol-rich diet do not develop atherosclerotic lesions because accumulated VLDL are apo E-depleted, too large and do not enter into the arterial wall. Models for non-insulin-dependent diabetes (NIDDM) are obtained through selective breeding or dietary conditions. The obese Zucker rat (fa/fa) is characterized by hyperphagy, hyperglycaemia, hyperinsulinemia, insulin-resistance, hypertriglyceridemia and hypercholesteolemia. It responds to dietary, hormonal and drug treatments, but does not develop atherosclerosis spontaneously. It is used as a model for obesity, NIDDM and type IV hyperlipidemia. The JCR:LA cp rat bears the corpulent gene and develops similar characteristics to those of the Zucker rat. However, insulin-resistance is more severe in homozygous males (cp/cp), and cardiovascular lesions are observed. Their appearance is reduced by treatments which decrease hyperinsulinemia and insulin resistance but not by lowering lipid levels alone. The sand rats (Psammomys obesus) develop obesity and NIDDM when fed a laboratory diet. When cholesterol and anti-thyroid drug are added to the diet, they develop cardiovascular lesions. This species constitutes a new model for studying atherosclerosis-related diabetes.
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PMID:Dyslipidemia and diabetes: animal models. 762 69

The relationship between overweight and cardiovascular disease was a matter of debate for many years. Recent studies have demonstrated that obesity defined as body mass index of 30 kg/m2 or higher is associated with an exponential increase of cardiovascular complications. This effect is largely mediated by the induction of established risk factors such as dyslipidemia, hypertension and type 2 diabetes mellitus. Recently, there is growing evidence that the occurrence of most complications of obesity depends not only on the degree of overweight but also on the pattern of body fat distribution. Many data suggest that the anatomical localization of body fat is more important for the risk of developing complications than the adipose tissue mass per se. An abdominal, upper-body type of fat distribution, which can be easily determined by the measurement of waist and hip circumferences (waist/hip ratio = WHR), is also a confirmed risk factor for metabolic disturbances, hypertension and atherosclerosis, independent of body weight. However, the clinical appearance of these disturbances is frequently associated with the development of obesity. This network of metabolic disorders and their vascular complications is termed "metabolic syndrome" or "syndrome X" (Table 2). Abdominal obesity is now known to be closely associated with the metabolic syndrome and is regarded to represent its readily recognizable phenotypic feature. The components of the metabolic syndrome are characterized by varying forms and degrees of insulin resistance. It is assumed that insulin resistance, defined as diminished biological response to the action of insulin, represents the primary defect or at least the common pathogenetic link between these disturbances.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Abdominal obesity and coronary heart disease. Pathophysiology and clinical significance]. 771 76

Epidemiological studies have elucidated that diabetes mellitus (DM) is one of the risk factors of coronary heart disease and that DM often accompanies dyslipidemia. Dyslipidemia in DM can be classified as either quantitative or qualitative. Although dyslipdemia in DM is affected by the type of DM and glycemic conditions, the characteristics of dyslipidemia in DM, especially in NIDDM are the increase in triglycerides accompanied by the decrease in HDL-cholesterol level. Recently, new commercial kits for measurement of atherogenic lipoproteins which increase in DM are clinically available. The usefulness of these kits in DM was reviewed. Polyacrylamide electrophoresis can detect IDL and Lp(a) qualitatively. It has also become possible to estimate Lp(a) quantitatively by ELISA, TIA and LIA methods. Remnant lipoprotein can be measured in the fraction unbound to anti-apo A1 and anti-apo B100 antibodies by immunoaffinity gel analysis. Apoproteins, apoprotein E phenotype, post-heparin lipoprotein lipase, and Lp AI (HDL with apo AI and without apo AII) can be measured by the commercially available kits. Modified LDLs (glycated, oxidative) increase in DM, but their measurements remain complicated at the moment. Analysis of plasma fatty acids by gaschromatography is useful for dietary assessment. The measurement of these new markers seems to be useful to assess the extent of atherogenic risk in DM.
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PMID:[Plasma fatty acids, lipids, lipoprotein and macroangiopathy]. 778 61

The general practitioner man be confronted with the X syndrome, which includes central obesity, impaired glucose tolerance or type II diabetes mellitus, dyslipidemia and eventually hypertension. Insulinoresistance and hyperinsulinaemia contribute to the pathogenesis of these disorders. The syndrome X, which leads to important cardiovascular morbidity, needs appropriate treatment, which has to take into account the actions of drugs on glucose and lipid profiles. Syndrome X is rarely treated as a whole, but to treat separately each of its manifestations would be a mistake. The necessity of a global approach, a complete understanding of the familial environment and also the duration of the development of syndrome X justify the prominent part of the family doctor in the follow-up.
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PMID:[Syndrome X and general medicine]. 778 42

Despite recent progress in therapy and management of diabetes mellitus, diabetes remains a serious disease with life-threatening complications. It is by far the most common metabolic disease and affects 5% of the population in industrialized countries. Noninsulin-dependent diabetes mellitus (NIDDM) is a complex disorder characterized by insulin resistance and impaired insulin secretion and is associated with an increased risk of coronary heart disease, peripheral vascular disease, arterial hypertension and dyslipidemia. Predisposing factors for NIDDM are obesity and a family history of diabetes. Greater physical activity has been associated inversely with the prevalence of NIDDM in several cross-sectional studies. Physical activity increases the sensitivity to insulin, and regular endurance exercise can induce and maintain weight loss, improve glucose tolerance and ameliorate most of the abnormalities in the metabolic syndrome. Type I diabetes mellitus arises as a consequence of immunologically mediated pancreatic islet beta-cell destruction in genetically susceptible individuals. It is an insidious process that may occur over years. During the stage of disease evolution (prediabetes), individuals may be identified by the presence of immunological markers and a decline of beta-cell function. The autoimmune nature of the disease process has led to attempts to stop this process by immune intervention strategies. A variety of immune interventions has been used, some immunosuppressive and some immunomodulatory. Several screening programs are used in order to identify high-risk subjects (i.e. first-degree relatives of individuals with type I diabetes) who may benefit from an early intervention. The ultimate goal of all these efforts is to prevent the development of overt type I diabetes mellitus in those at risk for the disease, using strategies that are both safe and specific. This review summarizes the results of the various studies conducted to date and outlines the approaches currently being tested.
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PMID:[Is prevention of diabetes mellitus possible?]. 783 27

The individual components of the metabolic syndrome such as central obesity, dyslipidemia with increased triglycerides and decreased HDL-cholesterol, hyperuricemia, hypertension and progressive glucose intolerance are markers for an increased risk of atheroma and type 2 (non-insulin-dependent) diabetes. All components, with the exception of hyperuricemia, are associated with skeletal muscle insulin resistance, leading to compensatory chronic hyperinsulinemia. Insulin resistance/hyperinsulinemia, in turn, is associated with a series of hypertensiogenic and atherogenic side effects, aggravating the individual components of the metabolic syndrome. From a more pathophysiologically orientated point of view, early identification of individuals obviously at risk for atheroma and type 2 diabetes, as well as early intervention aimed at the improvement of reduced insulin action may play a central role in an integrated life-style approach of primary prevention of atherosclerosis and type 2 diabetes.
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PMID:[The metabolic syndrome. Pathophysiologic causes, diagnosis, therapy]. 784 93

The microvascular complications of retinopathy, nephropathy, and neuropathy are less prevalent, and not as severe, in NIDDM as compared with IDDM for unknown reasons. Macrovascular disease is the greatest challenge in the management of NIDDM because it is the cause of death in 50% to 60% of this patient population. Control of the hyperglycemia is the most important because the prevention of complications is more effective than the treatment of them. Blood glucose control through diet, exercise, and medication is the key to reducing the previously identified complications. Lifestyle modifications of diet and exercise are the most effective treatment to reduce hyperglycemia. It is important to emphasize during the asymptomatic period the serious consequences of the complications and to set goals using the glycosylated hemoglobin. If these goals are not met, treatment should be intensified by more frequent visits or referral for the team approach. The time for intervention is before the complications are present, not after they occur. It is certainly reasonable to reduce as many risk factors as possible that adversely affect the complications of NIDDM. Hypertension can affect the course of coronary artery disease, retinopathy, nephropathy, and neuropathy and should be treated. The avoidance of tobacco is a must for the prevention of vascular disease and is associated with painful neuropathy. Dyslipidemia is seen frequently in NIDDM and should be assessed by fasting lipid panel and treated to lower the LDL cholesterol below 130 mg/dL. Reduction of individual risk factors is the most effective approach to this complex clinical syndrome until such time as a better understanding of the pathophysiology provides a more specific and effective intervention.
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PMID:Noninsulin-dependent diabetes mellitus. The prevention of complications. 787 91

Several large family studies are reviewed to identify results suggesting single gene traits contributing to the occurrence of hypertension in humans. Segregation analysis in families has suggested major gene effects for several highly heritable traits associated with hypertension. These include recessively segregating high sodium-lithium countertransport (major gene H2 = 34%), additively segregating low urinary kallikrein excretion (major gene H2 = 51%), and recessively segregating hyperinsulinemia (major gene H2 = 33%). In some families, hypertension and metabolic abnormalities (dyslipidemia, hyperinsulinemia, and obesity) seem to be related to several candidate genes studied but not conclusively proven (LPL deficiency mutations, dense LDL subfractions, or NIDDM with hyperinsulinemia). More recently, DNA markers have identified genes promoting hypertension. Glucocorticoid-remediable aldosteronism (GRA) promotes a rare but unusual form of hypertension that is unresponsive to ordinary medications but very responsive to glucocorticoid medications. GRA has been found in hypertensive persons with a specific mutation of the 11 beta-hydroxylase gene on chromosome 8q21. Many persons with essential hypertension carry a common "susceptibility gene" at the angiotensinogen locus (chromosome 1q4) identified using linkage studies in siblings, association studies, and in studies of preeclampsia and hypertension in pregnant women. These first two well-established genetic loci promoting human hypertension represent two ends of a broad spectrum. The rare "determinant" gene for GRA by itself seems to produce severe hypertension and early strokes. The angiotensinogen (AGT) "susceptibility" gene is very common (30% of Utah Caucasians) and seems to predispose to hypertension but probably requires other genetic and environmental influences to be fully expressed.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Evidence for single gene contributions to hypertension and lipid disturbances: definition, genetics, and clinical significance. 798 84

Association between insulin resistance and hypertension: Insulin resistance and reactive hyperinsulinemia occur not only with obesity, impaired glucose tolerance or non-insulin-dependent (type 2) diabetes mellitus, but also in many non-obese, non-diabetic patients with essential hypertension and their currently normotensive, lean young offspring and in some other conditions known to promote hypertension. Insulin resistance impairs glucose tolerance, while insulin resistance and/or hyperinsulinemia promote dyslipidemia, body fat deposition and probably atherogenesis. Therefore, the common coexistence of a genetic predisposition for hypertension with insulin resistance helps to explain the frequent, although temporally often dissociated, occurrence of hypertension as well as dyslipidemia, obesity and type 2 diabetes in a given subject. Pathogenetic mechanisms: In the pathogenesis of hypertension, inappropriate vasoconstriction (due to dysbalance of vasoactive substances and/or raised cytosolic Ca2+) and/or a structural vasculopathy is a very important ultimate causative event. In the presumed mosaic of participating pressor mechanisms, distinct Na+ retention is almost obligatory with diabetes mellitus, while essential and particularly obesity-associated hypertension probably involves a tendency for sympathetic activation. Development of insulin resistance: Insulin resistance may develop as a consequence of an intracellular excess of Ca2+ or decrease in Mg2+, an impaired insulin-mediated rise in skeletal muscle blood flow, increased sympathetic activity or being overweight. Acute hyperinsulinemia on the one hand causes arterial vasodilation and on the other hand enhances renal sodium reabsorption and sympathetic activity. Chronically, hyperinsulinemia may promote cardiovascular muscle cell proliferation and atherogenesis, and it has been proposed that insulin resistance in certain transmembranous cation exchange systems may elevate cytosolic Ca2+. Nevertheless, whether insulin resistance and/or hyperinsulinemia itself contribute to the pathogenesis of hypertension is still unclear.
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PMID:Insulin resistance, hyperinsulinemia and hypertension. 815 79

Insulin resistance has been recently distinguished as a syndrome associated with a clustering of metabolic disorders, including non-insulin dependent diabetes mellitus (NIDDM), obesity, hypertension, dyslipidemia and atherosclerosis. To date, it is thought that all of these disorders are the resulting consequences of primary insulin resistance. We propose that insulin resistance and the metabolic diseases mentioned can be caused by primary overactivity of the Na+/H+ exchange. This hypothesis has practical connotations for understanding the pathogenesis of the insulin resistance syndrome.
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PMID:Primary Na+/H+ exchanger dysfunction: a possible explanation for insulin resistance syndrome. 823 99


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