UMLS:C0242339 - FACTA Search

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

To further elucidate the incidence and potential mechanism of asparaginase-associated lipid abnormalities in children with acute lymphoblastic leukemia (ALL), we serially obtained fasting lipid and lipoprotein studies on 38 of the 43 consecutively diagnosed children with ALL before, during, and after asparaginase therapy. We also evaluated a second population of 30 long-term survivors of childhood ALL; a fasting lipid and lipoprotein profile was obtained once at study entry. The mean peak triglyceride level during asparaginase of 465 mg/dL (standard deviation [SD] 492) was significantly higher (P = .003) than the level of 108 mg/dL (SD 46) before the initiation of asparaginase therapy. Sixty-seven percent of the newly diagnosed patients had fasting triglyceride levels greater than 200 mg/dL during asparaginase therapy; 15 patients (42%) had levels greater than 400 mg/ dL, 7 with levels greater than 1,000 mg/dL. The incidence of hypertriglyceridemia did not vary by type of asparaginase or risk status of ALL (defined by white blood cell count and age). None of the 7 patients with triglyceride levels greater than 1,000 mg/dL developed pancreatitis. In contrast, 4 of the 13 patients without triglyceride elevation developed pancreatitis; 3 of the 4 patients had fasting studies at the height of their abdominal pain. Nuclear magnetic resonance analysis of lipid subclasses showed a significant increase in the smaller, denser forms of very low density lipoprotein (VLDL) and negligible chylomicron fraction in a subset of patients with marked triglyceride elevation. Lipoprotein lipase activity was consistently above normative values for all levels of triglyceride and could not be explained by obesity or hyperglycemia. Apolipoprotein B(100) levels increased during asparaginase therapy, although the mechanism of this remains unclear. LDL reciprocally decreased with increased VLDL during asparaginase therapy. After asparaginase therapy, triglyceride levels (mean, 73 mg/dL [SD 33]) were significantly lower than levels obtained during asparaginase therapy. Triglyceride levels for survivors did not differ from the normal range or postasparaginase levels in the newly diagnosed patients. These data show a striking temporal association between asparaginase therapy and hypertriglyceridemia. Changes in cholesterol, in contrast, were not temporally related to asparaginase treatment. Cholesterol levels were elevated (>200 mg/dL) in 20% of the patients after asparaginase, which may be due to continued treatment with corticosteroids. The mean cholesterol level of long-term survivors of 177 mg/dL was significantly higher than the norm (P = .045). High-density lipoprotein (HDL) levels were significantly lower than normal at all time periods and for both populations; 25% of survivors had HDL levels less than 35 mg/dL. We conclude that modifications in asparaginase therapy are not necessary. In cases of triglyceride elevation greater than 2,000 mg/dL when the risk of pancreatitis is increased, close clinical monitoring is imperative. Larger studies are needed to determine the incidence of dyslipidemia in long-term survivors of ALL as well as the relationship between lipid abnormalities and other late effects of treatment, notably obesity and cardiomyopathies.
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PMID:Asparaginase-associated lipid abnormalities in children with acute lymphoblastic leukemia. 905 8

Patients with NIDDM are at increased risk for coronary heart disease (CHD). However, information on the predictive value of cardiovascular risk factors and the degree of hyperglycemia with respect to the risk for CHD in diabetic patients is still limited. Therefore, we carried out a prospective study on risk factors for CHD, including a large number of NIDDM patients. At baseline, risk factor levels of CHD were determined in 1,059 NIDDM patients (581 men and 478 women), aged from 45 to 64 years. These patients were followed up to 7 years with respect to CHD events. Altogether, 158 NIDDM patients (97 men [16.7%] and 61 women [12.8%]) died of CHD and 256 NIDDM patients (156 men [26.8%] and 100 women [20.9%]) had a serious CHD event (death from CHD or nonfatal myocardial infarction). A previous history of myocardial infarction, low HDL cholesterol level (<1.0 mmol/l), high non-HDL cholesterol (> or =5.2 mmol/l), high total triglyceride level (>2.3 mmol/l), and high fasting plasma glucose (>13.4 mmol/l) were associated with a twofold increase in the risk of CHD mortality or morbidity, independently of other cardiovascular risk factors. High calculated LDL cholesterol level (> or =4.1 mmol/l) was significantly associated with all CHD events. The simultaneous presence of high fasting glucose (>13.4 mmol/l) with low HDL cholesterol, low HDL-to-total cholesterol ratio, or high total triglycerides further increased the risk for CHD events up to threefold. Our 7-year follow-up study provides evidence that dyslipidemia and poor glycemic control predict CHD mortality and morbidity in patients with NIDDM.
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PMID:Dyslipidemia and hyperglycemia predict coronary heart disease events in middle-aged patients with NIDDM. 923 62

Investigations into the mechanisms by which diabetes accelerates atherosclerosis have been hampered by the lack of suitable animal models. We hypothesized that streptozotocin-treated LDL receptor-deficient mice would be a good model of diabetic atherosclerosis because streptozotocin causes diabetes in the parent C57BL/6 strain and because in these mice diet-induced hypercholesterolemia leads to the formation of advanced atherosclerotic lesions throughout the aorta. Diabetes was induced in 18 mice by intraperitoneal injection of streptozotocin. Low-dose insulin was given subcutaneously to prevent excessive mortality and extreme elevations in triglyceride levels. The control group was subjected to sham injections. Both groups were fed a diet containing .075% cholesterol for six months. Average blood glucose was higher in the diabetic group than in the control group (257 +/- 67 mg/dL versus 111 +/- 7 mg/dL, P < 0.05). Although plasma cholesterol was similar (966 +/- 399 versus 1002 +/- 180 mg/dL) in both groups, VLDL cholesterol was higher whereas LDL cholesterol was lower in the diabetic group. Immunocytochemical analysis demonstrated significantly more advanced glycation end-product (AGE) epitopes in the artery wall of the diabetic group, whereas staining for oxidation-specific epitopes was similar in both groups. Sera of diabetic mice also contained significantly more IgG autoantibodies that bound to several AGE epitopes than did sera from control mice. Despite the presence of hyperglycemia, diabetic dyslipidemia, and enhanced AGE formation in the diabetic mice, both groups had a similar extent of atherosclerosis (diabetic, 17.3 +/- 5.2; control, 16.5 +/- 6.6% of the aortic surface). These data suggest that, at least under conditions of marked hypercholesterolemia; hyperglycemia and enhanced AGE formation do not contribute significantly to atherogenesis in LDL-/- mice.
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PMID:Effect of streptozotocin-induced hyperglycemia on lipid profiles, formation of advanced glycation endproducts in lesions, and extent of atherosclerosis in LDL receptor-deficient mice. 935 97

People with type II diabetes have a twofold to fourfold increased risk of dying from the complications of cardiovascular disease. Atherosclerosis and vascular thrombosis are major contributors. The increased risk is present before fasting hyperglycemia is seen. These individuals often have a sedentary life-style, poor physical conditioning, insulin resistance, centripetal obesity, hypertension, dyslipidemia, and a prothrombotic state. Chronic hyperglycemia is then added to these risk markers. Microalbuminuria may precede hyperglycemia in type II diabetes, occurs in 30% to 40% of these individuals after diabetes is established, and is a predictor of cardiovascular events. Early intervention in high-risk individuals may delay or prevent fasting hyperglycemia. An all-inclusive approach that focuses on early risk factor (or marker) identification and management to prevent or delay accelerated atherosclerosis and thrombosis in type II diabetes is an attractive strategy. However, the database to support this strategy is limited. In particular, large-scale prospective trial data are not available to support the concept of intensive glycemic regulation to prevent progression of macrovascular disease in type II diabetes. This is in contrast to the situation regarding microvascular disease of the eyes and kidneys. Recently, indirect data of a correlative nature have emerged, and short- and long-term prospective trials at early and late stages of type II diabetes are now being reported. These studies are analyzed and interpreted in this report. In contrast, the database to support an intensive antiplatelet regimen to prevent vascular thrombotic events in people with type II diabetes is large, and these studies are reviewed. They are of a type and magnitude to allow definite recommendations for aspirin therapy in type II diabetes. Aggressive therapy directed at hypertension, hyperlipidemia, and elevated urinary albumin in people with type II diabetes appears to be indicated. Increased attention to the multifactorial aspects of treatment of the type II diabetic patient is needed. Our present challenge is to translate these findings for patients and primary health care providers so that effective actions may be implemented.
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PMID:Multifactorial aspects of the treatment of the type II diabetic patient. 943 50

Five thousand five hundred seventy-two newly diagnosed non-insulin-dependent diabetes mellitus (NIDDM) patients (3,225 men and 2,347 women; mean age, 58.5 years) were recruited through the General Practitioners (GPs) network in France. All had persistent hyperglycemia after a preliminary 3-month period with dietary and life-style modification. Gliclazide (80 to 320 mg/d) was then prescribed as diabetic pharmacotherapy for 2 years. Additional therapy for hypertension and dyslipidemia was started if necessary. The aim of the study was mainly to determine the feasibility of a GP-directed protocol for the monitoring and treatment of newly diagnosed NIDDM patients, and to assess the effectiveness of diabetic therapy in this cohort. Diabetes was diagnosed in 78% of the cohort during routine screening. Among the women, 6.5% had a history of gestational diabetes. Eighteen percent of the patients had a parental history of diabetes, and the dominant maternal role in the genesis of NIDDM was confirmed. High blood pressure (Joint National Committee V criteria) was found at inclusion in 38.8% of the whole cohort. Hyperlipidemia was known in 44.6%. A history of stroke was present in 1.6% of the patients, and coronary heart disease (CHD) in 6.3%. These data support the relationship between the atherogenic state and development of NIDDM. Microalbuminuria defined as urinary albumin excretion (UAE) of at least 20 mg/L was found in 29.6% of the patients, and retinopathy in 9.8%. Among the included patients, 23% did not complete the study and were excluded from the efficacy analysis. Of these, 14% (808 patients) had only baseline evaluation data and 9% (499 patients) withdrew later. Comparison of mean baseline and final results in study completers uncovered a significant improvement in fasting blood glucose ([FBG] 182 +/- 48 v 137 +/- 40 mg/dL), post prandial blood glucose ([PPBG] 209 +/- 68 v 162 +/- 52 mg/dL), and hemoglobin A1c ([HbA1c] 8.7% +/- 2.5% v 7.3% +/- 2.0%). A slight improvement in total cholesterol (228 +/- 44 v 222 +/- 41 mg/dL), body mass index ([BMI] 28.5 +/- 4.7 v 27.9 +/- 4.5 kg/m2), and waist to hip ratio (0.99 +/- 0.1 v 0.98 +/- 0.1) was observed. There was a decrease in the percentage of patients with high blood pressure (38.5% v 30.7%). A mild increase in the prevalence of retinopathy (10.2% v 11.8%) was noted during the study, while the incidence of microalbuminuria remained unchanged (30.2% v 29.5%). In conclusion, the data indicate that the GPs involved in this study were able to successfully monitor and manage NIDDM patients in accordance with a standardized protocol. Gliclazide appeared to be an effective and well-tolerated treatment. The high prevalence of chronic diabetic complications at diagnosis emphasizes the delay encountered in reaching the diagnosis of NIDDM and the problems associated with this delay. In addition to the classic risk factors for NIDDM exhibited in this patient cohort, we have identified CHD and a maternal genetic component as further potential predicting factors.
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PMID:Management of newly diagnosed non-insulin-dependent diabetes mellitus in the primary care setting: effects of 2 years of gliclazide treatment--the Diadem Study. 943 56

Insulin resistance is characterized principally by impaired insulin-mediated glucose uptake which provokes a compensatory increase in pancreatic beta-cell secretory activity. For a time this may produce well-controlled plasma glucose levels but as the insulin resistance worsens the augmented insulin production becomes inadequate to keep plasma glucose at euglycemia leading to the development of non-insulin dependent diabetes mellitus (NIDDM), accompanied by hyperinsulinemia and hyperglycemia. A number of metabolic defects are associated with NIDDM including obesity, hypercoagulability, cardiovascular disease risk factors such as hypertension and dyslipidemia and these constitute the insulin resistance syndrome. The identity of the biochemical factor that might link all these defects is not yet known. We have hypothesized that platelet-activating factor (1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine, PAF) may be such a link. In this study, we measured plasma acetylhydrolase (EC.1.1.48), which degrades PAF to the inactive metabolise lyso-PAF, as a surrogate for PAF activity in three groups of hypercholesterolemic subjects: lean controls (n = 9), non-diabetic obese (n = 6) and NIDDM subjects (n = 6). The ages and body mass indices of the subjects were 46 +/- 3.1 and 24.2 +/- 2.2 for the lean controls, 52 +/- 2.5 and 28.7 +/- 0.9 for the NIDDM subjects and 60 +/- 2 and 27.6 +/- 2.1 for the obese, non-diabetic subjects (mean +/- S.E.M.). The measurements were made before and after therapy with the cholesterol-lowering drug lovastatin, a 3-hydroxy 3 methylglutaryl (HMG) coenzyme. A reductase inhibitor (40 mg/day) for 3 months. Fasting plasma glucose (FPG) levels were 91 +/- 11, 96 +/- 3 and 146 +/- 11 mg/dl, for the lean, obese and NIDDM subjects, respectively, before therapy began. Lovastatin did not affect FPG in any of the three subject groups. Before treatment, the fasting plasma insulin (FPI) levels were 6.1 +/- 0.92, 10.83 +/- 2.03 and 14.68 +/- 3.64 mU/l for the lean, non-diabetic obese and NIDDM subjects, respectively. After lovastatin therapy only the obese group exhibited a significant change in FPI (15.35 +/- 2.47 mU/l) (P < 0.05). Total cholesterol levels were similar in all three groups both before and after lovastatin therapy but within each group lovastatin therapy significantly reduced the total cholesterol by 32, 29 and 34% in the lean, obese and NIDDM subject groups respectively (P < 0.0001). Lovastatin therapy reduced LDL-cholesterol levels by 40, 32 and 46% in the lean, obese and NIDDM subjects, respectively, but produced no significant effect on HDL or triglyceride levels. Before therapy, the plasma acetylyhydrolase activities were 104 +/- 7, 164 +/- 7 and 179 +/- 7 nmol/ml per min in the lean, obese and NIDDM subjects, respectively. Lovastatin therapy reduced plasma acetylhydrolase levels to 70 +/- 7, 87 +/- 6 and 86 +/- 7 nmol/ml per min in the lean, obese and NIDDM subjects, respectively. Plasma acetylhydrolase activity was predominantly (> 80%) associated with LDL cholesterol both before and after lovastatin treatment. Also, plasma acetylhydrolase activity significantly correlated with fasting plasma insulin levels before lovastatin therapy but not after. Taken together, this study clearly implicates PAF metabolism in three defects associated with the insulin resistance syndrome: hypercholesterolemia, obesity and NIDDM. Additionally, we conclude that chronic hyperinsulinemia may play a significant role in the production of plasma acetylhydrolase.
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PMID:Plasma PAF acetylhydrolase in non-insulin dependent diabetes mellitus and obesity: effect of hyperinsulinemia and lovastatin treatment. 945 36

It is widely held that although obesity and type 2 diabetes are polygenic in origin, the primary defect causing both conditions is insulin resistance, which in turn gives rise to a constellation of other abnormalities, including hyperinsulinemia, dyslipidemia, glucose intolerance, and (in the genetically predisposed) frank hyperglycemia. Explored here is an alternative, albeit speculative, scenario in which hyperinsulinemia and insulin resistance arise either simultaneously or sequentially from some preexisting defect within the leptin signaling pathway. In either case, a central component of the model is that the breakdown of glucose homeostasis that is characteristic of the condition of obesity with type 2 diabetes is secondary to disturbances in lipid dynamics. The possibility is raised that abnormally high concentrations of malonyl-CoA in liver and skeletal muscle suppress the activity of mitochondrial carnitine palmitoyltransferase I and thus fatty acid oxidation in both sites. It is suggested that the buildup of fat within the muscle cell (caused in part by excessive delivery of VLDLs from the liver) interferes with glucose transport or metabolism or both, producing insulin resistance. Elevated circulating concentrations of fatty acids are also implicated in the etiology of type 2 diabetes by virtue of 1) their powerful acute insulinotropic effect, 2) their ability to exacerbate insulin resistance in muscle, and 3) their long-term detrimental action on pancreatic beta-cell function.
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PMID:Glucose-fatty acid interactions in health and disease. 949 60

The most recent position statement on nutrition from the American Diabetes Association recommends an individualized approach to nutrition that is based on the nutritional assessment and desired outcomes of each patient and that takes into consideration patient preferences and control of hyperglycemia and dyslipidemia. To achieve these nutritional goals, either low-saturated-fat, high-carbohydrate diets or high-monounsaturated-fat diets can be advised. A meta-analysis of various studies comparing these two approaches to diet therapy in patients with type 2 diabetes revealed that high-monounsaturated-fat diets improve lipoprotein profiles as well as glycemic control. High-monounsaturated-fat diets reduce fasting plasma triacylglycerol and VLDL-cholesterol concentrations by 19% and 22%, respectively, and cause a modest increase in HDL-cholesterol concentrations without adversely affecting LDL-cholesterol concentrations. Furthermore, there is no evidence that high-monounsaturated-fat diets induce weight gain in patients with diabetes mellitus provided that energy intake is controlled. Therefore, a diet rich in cis-monounsaturated fat can be advantageous for both patients with type 1 or type 2 diabetes who are trying to maintain or lose weight.
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PMID:High-monounsaturated-fat diets for patients with diabetes mellitus: a meta-analysis. 949 73

The high prevalence rate of mortality in diabetic patients is explained by atherothrombotic cardiovascular disease. Hyperinsulinemia and insulin resistance, dyslipidemia, chronic hyperglycemia, decrease of endothelial cells and of monocytes-macrophage cell functions, and hypercoagulability are the main side-effects which are involved in the pathogenesis of diabetic atherothrombotic disease. Its clinical manifestations are coronary heart disease, peripheral vascular insufficiency, cerebral vascular insufficiency and reno-vascular hypertension. The common characteristics are a clinical latent period, the frequency of acute complications and the widespread bilateral distal localisation of vascular insufficiency. The therapeutic strategy in diabetic atherothrombotic disease is becoming better codified, leading to screening and prevention. The evaluation of diabetic vascular risk could reduce the prevalence of thrombotic events.
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PMID:[Management of diabetic vasculopathy]. 950 77

Type II diabetes is a common disorder whose prevalence is increasing in the United States and throughout the world. Type II diabetes is also associated with several other metabolic abnormalities such as central obesity, hypertension, and dyslipidemia, which contributes to the very high rate of cardiovascular morbidity and mortality. The main pathologic defects in diabetes consist of excessive hepatic glucose production, peripheral insulin resistance, and defective beta-cell secretory function. The duration and severity of the hyperglycemia dictate the microvascular complications, no matter what the etiology of the glucose intolerance, and the goals of therapy should be similar to those of insulin-dependent type I diabetic patients. Initiation of nonpharmacologic therapy should be started as soon as the diagnosis is made. Pharmacologic agents should be initiated if the glycemic goals are not met with a 3-month trial of diet and exercise. The cornerstone of therapy consists of a regular exercise routine along with a diet consisting of 40% to 50% complex carbohydrates, 10% to 20% protein, and monounsaturated fats such as canola oil and olive oil. If nonpharmacologic therapy does not achieve adequate glycemic control, initiation of an oral antidiabetic agent is warranted. In addition to the sulfonylureas, which work by stimulating insulin secretion, we now have metformin, which inhibits excessive hepatic glucose production; acarbose, which delays the absorption of carbohydrates in the gut; and troglitazone, which reduces insulin, resistance primarily in skeletal muscle. The selection of an initial oral antidiabetic agent depends on patient characteristics such as the presence of obesity and dyslipidemia, the duration of diabetes, and other concomitant conditions. Combination therapy with two or three of the different classes of oral antidiabetic agents is effective and has been used throughout the world. When maximum doses of oral antidiabetic agents do not adequately control glycemia, insulin therapy is necessary. In selected patients, combination therapy consisting of bedtime intermediate-acting insulin in addition to daytime oral antidiabetic agent(s) can be an effective method to normalize glucose control without the need for rigorous insulin regimens. When combination therapy fails, a split-mixed regimen using premixed 70/30 insulin prebreakfast and predinner can be very effective in obese subjects. In thin insulin-requiring subjects with type II diabetes, more intensive regimens may be required. In general, the risk of severe hypoglycemia is quite low in patients with type II diabetes, and the main adverse effect of insulin therapy is weight gain. Prevention and aggressive treatment of glucose intolerance and the other adverse metabolic conditions associated with type II diabetes will not only have a positive effect on the quality of life but also provide long-term cost savings.
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PMID:Type II diabetes mellitus. 950 90

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