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Query: UMLS:C0242339 (dyslipidemia)
 13,927 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Hypertension, dyslipidemia, and glucose intolerance cocluster in the population and act synergistically in increasing coronary artery disease risk. The mechanisms by which these risk factors interact in atherosclerosis are complex. First, hypertension, dyslipidemia, and altered insulin sensitivity may have a common pathophysiological basis. Activation of neurohormonal mechanisms may be implicated in many or all of these processes. In addition, underlying these processes may be common genetic and environmental influences. Second, these risk factors ultimately act on the blood vessel, thereby leading to atherosclerosis. Elevated serum lipids lead to vessel wall responses, including endothelial dysfunction, smooth muscle cell proliferation, lipid accumulation, foam cell formation, and, eventually, necrosis and plaque development. Hypertension may induce shear-related injury to the vessel. Endothelial injury (caused by hypertension) and vascular cell proliferation (induced by increased pressure and/or vasoactive substances) are effects that amplify the atherosclerotic process. In addition, diabetes and hyperinsulinemia can increase vascular tone, impair endothelial function, and stimulate vascular smooth muscle cell proliferation. Control of these risk factors should prevent or attenuate the vessel wall responses. Emphasis is now being placed on pharmacological therapeutic modalities that decrease blood pressure and improve insulin sensitivity and lipid metabolism. Identification of common links between risk factors, such as neurohormonal mechanisms (e.g., angiotensin), should lead to better therapeutic strategies.
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PMID:Atherosclerosis and hypertension: mechanisms and interrelationships. 169 33

Non-insulin-dependent (type II) diabetes mellitus is an inherited metabolic disorder characterized by hyperglycemia with resistance to ketosis. The onset is usually after age 40 years. Patients are variably symptomatic and frequently obese, hyperlipidemic and hypertensive. Clinical, pathological and biochemical evidence suggests that the disease is caused by a combined defect of insulin secretion and insulin resistance. Goals in the treatment of hyperglycemia, dyslipidemia and hypertension should be appropriate to the patient's age, the status of diabetic complications and the safety of the regimen. Nonpharmacologic management includes meal planning to achieve a suitable weight, such that carbohydrates supply 50% to 60% of the daily energy intake, with limitation of saturated fats, cholesterol and salt when indicated, and physical activity appropriate to the patient's age and cardiovascular status. Follow-up should include regular visits with the physician, access to diabetes education, self-monitoring of the blood or urine glucose level and laboratory-based measurement of the plasma levels of glucose and glycated hemoglobin. If unacceptably high plasma glucose levels (e.g., 8 mmol/L or more before meals) persist the use of orally given hypoglycemic agents (a sulfonylurea agent or metformin or both) is indicated. Temporary insulin therapy may be needed during intercurrent illness, surgery or pregnancy. Long-term insulin therapy is recommended in patients with continuing symptoms or hyperglycemia despite treatment with diet modification and orally given hypoglycemic agents. The risk of pancreatitis may be reduced by treating severe hypertriglyceridemia (fasting serum level greater than 10 mmol/L) and atherosclerotic disease through dietary and, if necessary, pharmacologic management of dyslipidemia. Antihypertensive agents are available that have fewer adverse metabolic effects than thiazides and beta-adrenergic receptor blockers. New drugs are being developed that will enhance effective insulin secretion and action and inhibit the progress of complications.
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PMID:Non-insulin-dependent (type II) diabetes mellitus. 174 94

Cardiovascular disease, and in particular ischemic heart disease, is the principal cause of morbidity, functional disability, and mortality in patients with non-insulin-dependent (type II) diabetes. The main risk factors for the macrovascular complications of diabetes are dyslipidemia, hypertension, and cigarette smoking. Although degree of hyperglycemia is a risk factor for microvascular complications, it is not a prominent risk factor for macrovascular complications. Nevertheless, there are theoretical reasons for believing that glycemic control could lower cardiovascular risk. For example, glycemic control may both improve clearance and suppress hepatic overproduction of very-low-density lipoprotein. Moreover, there is direct empirical evidence that improved glycemic control can favorably alter lipid profiles in type II diabetic patients. Despite this, the only clinical trial that has assessed cardiovascular mortality as an end point in diabetic subjects (i.e., the University Group Diabetes Program) failed to demonstrate a benefit of glycemic control. In this study, the insulin-variable group, which achieved sustained glycemic control relative to the placebo group, had essentially the same cardiovascular mortality as the latter group. All of the conventional lipid-lowering agents have been shown to produce favorable changes in lipid profiles in diabetic subjects. However, the optimum regimen remains to be defined. Metabolic differences between diabetic and nondiabetic subjects mean that the optimum lipid-lowering regimens for the two categories of patients may differ. For example, nicotinic acid, which is a powerful lipid-altering drug, may worsen glucose intolerance. The characteristic lipid abnormalities in type II diabetic subjects are hypertriglyceridemia and low high-density lipoprotein cholesterol, not hypercholesterolemia. Although the role of hypertriglyceridemia as a cardiovascular risk factor in the general population has been questioned, there is evidence that this lipid abnormality may play a stronger role in diabetic subjects. For all of the above reasons, there is an urgent need for large-scale clinical trials assessing cardiovascular end points and testing various strategies of improving lipid profiles in diabetic subjects, particularly given the fact that all of the current generation of lipid-lowering trials have systematically excluded diabetic patients.
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PMID:Dyslipidemia in type II diabetes. Implications for therapeutic intervention. 177 1

Hyperandrogenism and lipid metabolism were shown to be related intimately. Any discussion of the nature of their relationship must include other clinical and metabolic variables such as hyperinsulinemia and UBO. Despite the many correlations among each of these factors, the appropriate sequence in the pathogenesis of these conditions has not been defined. Do conditions that result in insulin resistance (e.g., genetic defects, insulin receptor antibodies, and obesity) also lead to the development of hyperandrogenemia by direct or indirect ovarian stimulation by insulin? Does hyperandrogenism of ovarian or adrenal origin cause abnormal upper body fat distribution, in turn leading to lipid abnormalities and insulin resistance? Regardless of the issue of mechanism of causality, women with hyperandrogenism are thought to be at greater risk for cardiovascular morbidity and mortality than their normoandrogenic counterparts. These women often are obese, hypertensive, and sedentary; ingest diets high in saturated fats; and have glucose intolerance and/or insulin resistance. All these abnormalities are well known independent risk factors for the development of lipid abnormalities and cardiovascular disease. Whether hyperandrogenism is a secondary consequence of any of these or whether it is an independent contributor to lipid aberrations requires future study. Treatment strategies for hyperandrogenic women, however, should not only be directed toward alleviation of the cosmetic problem of hirsutism but also toward the prevention and treatment of cardiovascular morbidity using modalities aimed at eradicating hyperinsulinemia, hypertension, and dyslipidemia. These modalities should include modifications in diet, exercise, and weight in addition to pharmacologic and/or surgical manipulation. Weight reduction will reduce many cardiovascular risk factors. Obesity is easier to target because of the many risk factors that result in it.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Lipid metabolism and hyperandrogenism. 177 28

The incidence of cardiovascular disease in non-insulin-dependent diabetes mellitus (NIDDM) has not been reduced by the control of hyperglycemia alone. Hypertension and dyslipidemia may be the major determinants of macrovascular disease in these patients. With the high prevalence of hypertension in NIDDM, antihypertensive drugs are likely to be important determinants of an atherogenic lipid profile. To date, there is no completed major randomized controlled trial of antihypertensive treatment outcome in a diabetic population, and as such, drug choice for the treatment of diabetic hypertension is often based on evidence extrapolated from studies in nondiabetic groups. However, two short-term studies have assessed the effects of doxazosin antihypertensive therapy in subjects with NIDDM. Both studies showed that the significant reduction in blood pressure with doxazosin treatment was associated with favorable effects on the serum lipid profile. In one study, contrasting adverse effects of atenolol treatment on glycemic control, lipids, and lipoproteins were observed. Doxazosin therapy was associated with a trend toward correcting the disturbances of lipoprotein metabolism characteristic of NIDDM. These metabolic effects, combined with effective lowering of blood pressure by doxazosin, may be important determinants of cardiovascular disease in the long term.
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PMID:Doxazosin therapy in the treatment of diabetic hypertension. 182 86

Dyslipidemia of chronic renal failure is of multifactorial origin. Decreased activity of lipoprotein lipase and hepatic triglyceride lipase, peripheral insulin resistance, hyperparathyroidism and L-carnitine deficiency are the contributing factors. This results in a disturbed catabolism of chylomicron, accumulation of very-low-density (VLDL) and intermediate-density (IDL) lipoproteins as well as incompletely cleared remnant particles, whereas low-density lipoprotein (LDL) levels are diminished. There is current debate as to whether cardiovascular disease is accelerated and whether hyperlipidemia should specifically be treated. In addition, there have been few means of influencing these metabolic alterations. Drug incompatibility and consequently side effects render treatment difficult. The drugs that have been most tested for lipid lowering in chronic renal failure are the fibric acids. By their mode of action, they are the logical choice. Dose reduction overcomes major side effects such as myopathy and rhabdomyolysis. The second generation of fibric acid derivatives (gemfibrozil and beclobrate) show several advantages over formerly used derivatives. Treatment with lovastatin and simvastatin appears to be safe and is recommended in a minority of patients with predominantly elevations of LDL. HMG-CoA reductase inhibitors also lower remnant particles effectively in hemodialysis (HD) patients. L-Carnitine and low-molecular-weight heparin have been shown to influence VLDL rich in triglycerides in a subset of patients on HD. In posttransplant hyperlipidemia, diet remains the first course of action in all patients. When this approach fails, the new lipid-lowering agents, especially fibric acids, appear to be safe in short-term studies in azathioprine- and ciclosporin-treated patients. Lovastatin has been shown to be safe in stable renal transplant patients. Its toxicity seems to depend mainly on high ciclosporin whole blood through or plasma levels.
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PMID:Hyperlipoproteinemia in chronic renal failure: pathophysiological and therapeutic aspects. 186 98

Hyperinsulinaemia links non-insulin dependent diabetes (NIDDM), obesity, and hypertension, each an insulin-resistant state in its own right. Insulin resistance predicts the occurrence of NIDDM, and plays a major role in its pathogenesis. We tested the hypothesis that hyperinsulinaemia may also predict hypertension in a sample (n = 2905) of the mixed population of San Antonio, in which hyperinsulinaemia and NIDDM are more prevalent among Mexican-Americans than non-Hispanic whites. Whilst in the whole sample the hypertensives had significantly (P less than 0.001) higher plasma insulin concentrations than the normotensives, high blood pressure was significantly (P less than 0.01) more frequent among non-Hispanic whites than Mexican-Americans regardless of diabetes status. After adjusting for factors (age, sex, body mass, and body fat distribution) known to affect insulin levels, a direct relationship between post-glucose plasma insulin concentrations and prevalence of hypertension was still present in both ethnic groups. In Mexican-Americans, however, the standardized prevalence of hypertension was significantly (P less than 0.001) lower at any given insulin concentration. Post-glucose plasma glucose levels also were directly related to hypertension prevalence in both groups; again, the regression line was shifted downward and, furthermore, less steep (P less than 0.02) in Mexican-Americans, suggesting relative protection against the negative effect of hyperglycaemia on blood pressure. Dyslipidaemia (higher total cholesterol and triglyceride, and lower HDL-cholesterol concentrations) was strongly associated with hyperinsulinaemia and blood pressure in both ethnic groups. After adjusting for plasma insulin, only hypertriglyceridaemia was associated with high blood pressure, with no inter-ethnic difference.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:High blood pressure and insulin resistance: influence of ethnic background. 190 31

Hypertension may be either accentuated or caused by hyperinsulinemia secondary to insulin resistance. The role of hyperinsulinemia has been most clearly defined in those people with upper body obesity who frequently have hypertension, abnormal glucose tolerance, and dyslipidemia. Less well understood but repeatedly demonstrated, insulin resistance and hyperinsulinemia are also seen in normal-weight hypertensive patients. The implications of these findings are important to recognize, both in an attempt to understand the pathogenesis of hypertension and in hopes of treating it most appropriately.
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PMID:Hypertension and hyperinsulinemia. 194 84

Abnormalities of plasma lipid and lipoprotein concentrations are common in both insulin-dependent (IDDM) and non-insulin-dependent (NIDDM) diabetes mellitus. In general, individuals with IDDM who are untreated or inadequately treated have elevations in both postprandial and fasting triglyceride levels in association with reduced activity of lipoprotein lipase. Low-density lipoprotein (LDL) cholesterol levels can rise when insulin deficiency impacts on LDL-receptor function. When patients with IDDM are treated and plasma glucose levels well controlled, plasma very-low-density lipoprotein (VLDL) triglyceride and LDL cholesterol levels are usually normal. In addition, plasma high-density lipoprotein (HDL) cholesterol levels are normal or elevated in well-controlled IDDM subjects. In NIDDM, increased VLDL triglyceride and reduced HDL cholesterol concentrations are common and are only partially related to glycemic control. Overproduction of VLDL leads to hypertriglyceridemia, which can be exacerbated if lipoprotein lipase activity is also reduced. The regulation of LDL levels is complex; catabolism can be reduced if significant insulin deficiency exists or increased if significant hypertriglyceridemia is present. The reduced levels of HDL cholesterol in NIDDM appear to be related to increased exchange of HDL cholesteryl esters for VLDL triglycerides, although other mechanisms may exist. The roles of insulin resistance, obesity, and independently inherited abnormalities of lipoprotein metabolism in the etiology of dyslipidemia of NIDDM are complex and require further investigation. Finally, the effects of diabetes on glycosylation of apoproteins; on other lipid enzymes, particularly hepatic triglyceride lipase; on lipoprotein surface lipids; and on hepatic uptake of remnants have only just begun to be defined. In view of the marked increase in atherosclerotic cardiovascular disease in individuals with diabetes mellitus, prompt attention to and aggressive therapy for dyslipidemia should be a central component of care for these patients.
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PMID:Lipoprotein physiology in nondiabetic and diabetic states. Relationship to atherogenesis. 195 76

Epidemiologic research indicates that glucose intolerance and hypertension are interrelated phenomena, each powerfully predisposing to atherosclerotic cardiovascular disease. Both diabetic and hypertensive patients have greater amounts of atherogenic risk factors, including dyslipidemia, hyperuricemia, elevated fibrinogen, and left ventricular hypertrophy. Diabetic persons have an increased prevalence of hypertension (50%), and glucose intolerance is more common in hypertension (15% to 18%). Both share a strong relationship to excess weight, but the excess of hypertension in diabetic persons occurs in both lean and obese subjects. Diabetes doubles the risk of hypertension associated with overweight. The risk of coronary disease, stroke, and peripheral arterial disease increases with increasing blood pressure to the same degree in diabetic persons as in nondiabetic persons, but at any level of blood pressure, diabetic persons have a doubled risk of these outcomes. Both diabetic and hypertensive patients are particularly prone to silent or unrecognized myocardial infarctions. Greater efforts at primary prevention of both hypertension and diabetes are clearly needed, including efforts at weight control, exercise, limitation of salt intake, and control of blood lipid levels. In either diabetic or hypertensive candidates for cardiovascular disease, optimization of the chances of avoiding sequelae requires a comprehensive multifactorial approach. Prevention requires more than normalization of either the blood sugar or blood pressure. Rational preventive measures must also include weight reduction, a fat-modified diet, cessation of smoking cigarettes, raising high-density lipoprotein, lowering low-density lipoprotein, and reduction of fibrinogen. Hypertension, obesity, insulin resistance, hyperinsulinemia, hypertriglyceridemia, and low high-density lipoprotein cholesterol tend to coexist.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The epidemiology of impaired glucose tolerance and hypertension. 200 55


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