Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0020473 (hyperlipidemia)
15,891 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Primary hypothyroidism was found to be the cause of hyperlipidemia in 22 patients. The mean age was 46 years, 59% were males, 27% had vascular disease, 14% had xanthomas and 86% had thyroid antibodies. Familial involvement was shown in 3 propositi. All patients were treated with L-thyroxine, 0.05--0.2 mg/day for a mean of 16 months. Combined hyperlipidemia was common (77%), and lipoprotein phenotyping revealed types IIB hyperlipopro-teinemia in 11, IIA in 5, III in 3 and IV in 3 patients. With treatment, normal plasma cholesterol (less than 265 mg/dl) and triglycerides (less than 200 mg/dl) were obtained in 91% and 86%, respectively. The mean maintenance L-thyroxine dose was 0.15 mg/day, but smaller doses often showed marked hypolipidemic effect. The mean +/- S. D. pretreatment fasting plasma cholesterol and triglycerides were 387 +/- 120 and 328 +/-247 mg/dl and on thyroid treatment the mean minimum levels were 205 +/- 46 and 133 +/- 65 mg/dl, respectively (both p values less than 0.005). Hypothyroidism has proved to be a common reversible form of hyperlipidemia. One cardiac patient died and three others had to have their L-thyroxine titrated to prevent angina. Family screening has been of use in case finding for auto-immune disease in 3 families.
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PMID:Hypothyroidism, an important cause of reversible hyperlipidemia. 83 19

One hundred and ten patients with radiologically established peripheral atherosclerotic arterial disease were studied. None of them suffered from diabetes, endocrine disorders or renal disease. Their serum cholesterol and triglyceride values were compared with those of a reference group consisting of 548 individuals. When the 95th percentile of the reference values was used for cut-off, the frequency of hyperlipidemias in the patients with peripheral arterial atherosclerosis was about 52%. Combined hyperlipidemia was slightly more common (21%) than isolated increase of either cholesterol (17.9%) or triglycerides (12.6%). Using other cut-off limits for the definition of hyperlipidemia, a striking change in the distribution between these three types of hyperlipidemia occurred. In our patients, the frequencies of different blood groups were not significantly different from those of a comparable population. The serum lipids were at the same level in the different blood groups.
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PMID:Hyperlipidemia in peripheral atherosclerotic arterial disease. 117 25

Combined hyperlipidemia may result from the interaction of several metabolic and environmental factors. We explored to what extent fasting insulin concentration, apolipoprotein (apo) E2 frequency, and cigarette smoking explained the serum levels of triglyceride and high-density lipoprotein cholesterol (HDL-C) in patients with combined hyperlipidemia. Forty-nine untreated patients with combined hyperlipidemia were compared with 49 hypercholesterolemic patients who were matched for gender, age, and body mass index. All laboratory values were obtained after 9 weeks of standardized dietary intake and after an overnight fast. The patients with combined hyperlipidemia had a significantly higher (33 pmol/L, 50%) mean insulin concentration than matched hypercholesterolemic control subjects, indicating that the combined hyperlipidemic patients were more insulin resistant. However, the differences in the fasting insulin and triglyceride concentrations within the pairs were only slightly correlated (adjusted r = .29). The combined hyperlipidemic patients were also characterized by a higher frequency of apoE2 alleles (25% versus 6%) and smokers (41% versus 16%). In a matched multiple linear regression model, the differences in insulin concentration, apoE2 allele frequency, and smoking explained 12%, 8%, and 9%, respectively, of the mean paired difference in triglyceride concentration. The differences in insulin concentration or apoE2 allele frequency did not significantly explain the mean paired difference in HDL-C concentration, whereas smoking explained 17% of the difference. In conclusion, fasting insulin concentration, the presence of the apoE2 allele, and smoking may explain 30% of the hypertriglyceridemia and the low levels of HDL-C in nonobese patients with combined hyperlipidemia.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effect of insulin resistance, apoE2 allele, and smoking on combined hyperlipidemia. 791 7

The relevance of hyperlipidemia in allograft arteriosclerosis (chronic rejection) is controversial. Isolated hypercholesterolemia induced with cholesterol-cholic acid-diet (CC-diet) or hypertriglyceridemia induced with glycerol-diet (G-diet) had no or only a protective effect on aortic allograft arteriosclerosis in the rat. Combined hyperlipidemia with both diets (CC+G-diet) enhanced allograft arteriosclerosis by doubling intimal thickness and cellularity (P < .05) but had no effect on host arteries. Compared with normolipidemic controls, the CC+G-diet increased the total serum cholesterol concentration 4.8-fold (P < .05). Levels of VLDL2 and IDL increased 4.8- and 18.1-fold (P < .05), and their composition changed from triglyceride-rich to cholesterol-rich lipoproteins in an atherogenic direction. The CC+G-diet had no effect on the structure of inflammation in the vascular wall. Instead, significant lipid deposits were observed, and the expression of epidermal growth factor and insulin-like growth factor-1 was significantly elevated in the vascular wall. Thus, elevations in VLDL and IDL lipoprotein levels and their cholesterol content associate with the generation of allograft arteriosclerosis in rats. Deposition of lipids in the vascular wall seems to induce local synthesis of certain growth factors, which ultimately leads to the induction of smooth muscle cell replication.
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PMID:Hyperlipidemia accelerates allograft arteriosclerosis (chronic rejection) in the rat. 798 Nov 93

The effect of fenofibrate on plasma cholesteryl ester transfer protein (CETP) activity in relation to the quantitative and qualitative features of apoB- and apoA-I-containing lipoprotein subspecies was investigated in nine patients presenting with combined hyperlipidemia. Fenofibrate (200 mg/d for 8 weeks) induced significant reductions in plasma cholesterol (-16%; P < .01), triglyceride (-44%; P < .007), VLDL cholesterol (-52%; P = .01), LDL cholesterol (-14%; P < .001), and apoB (-15%; P < .009) levels and increased HDL cholesterol (19%; P = .0001) and apoA-I (12%; P = .003) levels. An exogenous cholesteryl ester transfer (CET) assay revealed a marked decrease (-26%; P < .002) in total plasma CETP-dependent CET activity after fenofibrate treatment. Concomitant with the pronounced reduction in VLDL levels (37%; P < .005), the rate of CET from HDL to VLDL was significantly reduced by 38% (P = .0001), whereas no modification in the rate of cholesteryl ester exchange between HDL and LDL occurred after fenofibrate therapy. Combined hyperlipidemia is characterized by an asymmetrical LDL profile in which small, dense LDL subspecies (LDL-4 and LDL-5, d = 1.039 to 1.063 g/mL) predominate. Fenofibrate quantitatively normalized the atherogenic LDL profile by reducing levels of dense LDL subspecies (-21%) and by inducing an elevation (26%; P < .05) in LDL subspecies of intermediate density (LDL-3, d = 1.029 to 1.039 g/mL), which possess optimal binding affinity for the cellular LDL receptor. However, no marked qualitative modifications in the chemical composition or size of LDL particles were observed after drug treatment. Interestingly, the HDL cholesterol concentration was increased by fenofibrate therapy, whereas no significant change was detected in total plasma HDL mass. In contrast, the HDL subspecies pattern was modified as the result of an increase in the total mass (11.7%) of HDL2a, HDL3a, and HDL3b (d = 1.091 to 1.156 g/mL) at the expense of reductions in the total mass (-23%) of HDL2b (d = 1.063 to 1.091 g/mL) and HDL3c (d = 1.156 to 1.179 g/mL). Such changes are consistent with a drug-induced reduction in CETP activity. In conclusion, the overall mechanism involved in the fenofibrate-induced modulation of the atherogenic dense LDL profile in combined hyperlipidemia primarily involves reduction in CET from HDL to VLDL together with normalization of the intravascular transformation of VLDL precursors to receptor-active LDLs of intermediate density.
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PMID:Fenofibrate reduces plasma cholesteryl ester transfer from HDL to VLDL and normalizes the atherogenic, dense LDL profile in combined hyperlipidemia. 864 Apr 4

The long-term efficacy and safety of fluvastatin monotherapy was compared with that of the combination of fluvastatin and fenofibrate in 104 patients with coronary heart disease and combined hyperlipidemia in an open, randomised, parallel group, clinical study of 78 weeks duration. Combined hyperlipidemia was defined as LDL-cholesterol 4.1 mmol/l and higher and triglycerides between 2.5 and 4.5 mmol/l after 8 weeks of dietary intervention. The patients were treated with either fluvastatin 40 mg daily or with the combination of fluvastatin (20 mg daily) and micronized fenofibrate 200 mg daily. Mean values of total and LDL-cholesterol decreased by 19.3% and 29.7% respectively after fluvastatin treatment and by 21.5% and 29.1% respectively after the combination of fluvastatin and fenofibrate treatment. The differences between the treated groups were not significant. Mean values of HDL-cholesterol increased significantly more after the combination of fluvastatin and fenofibrate than after fluvastatin monotherapy (26% vs. 9.9%). The mean values of triglycerides decreased significantly more after the combination treatment than after fluvastatin monotherapy (-40.2% vs. -19.7%). The treatment in both groups was well tolerated and no signs of myopathy were observed in any patient. The study was discontinued in 1 patient due to the increase of liver enzymes. The most frequently observed side effects were minor gastrointestinal symptoms, which were more frequent in patients treated by the combination of fluvastatin and fenofibrate. Thus our results demonstrate that the combination of fluvastatin and fenofibrate is an effective and safe treatment option for patients with coronary heart disease and mild to moderate combined hyperlipidemia if a more radical lowering of triglycerides and increase of HDL-cholesterol is desired.
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PMID:[Long-term treatment of combined hyperlipidemia with a combination of fluvastatin and fenofibrate]. 1104 81

Combined hyperlipidemia (coincident present hypercholesterolemia and hypertriglyceridemia) may contribute to the development of atherosclerosis and coronary artery disease by increasing of cell adhesion molecules (CAMs). Although the cellular expression of CAMs is difficult to assess clinically, soluble forms of CAMs (sCAMs) are present in the circulation and may serve as marker of CAMs. The aim of this study was to determine whether combined hyperlipidemia in overweight adults without clinical evidence of cardiovascular disease, diabetes mellitus or hypertension is associated with increased expression of CAMs. We examined the levels of soluble cell adhesion molecules (sICAM-1, sE-Selectin and sP-Selectin) in blood plasma of overweight adults (n = 36), mean of BMI 27.08 +/- 4.12 kg/m2 with combined hyperlipidemia, with total cholesterol (TC) 7.27 +/- 1.50 mmol/l, LDL cholesterol 4.89 +/- 1.35 mmol/l, HDL cholesterol 1.27 +/- 0.51 mmol/l and triglycerides (TG) 4.08 +/- 2.22 mmol/l before lipid-lowering therapies, and in equal numbers of age, sex and BMI matched controls. Patients with combined hyperlipidemia had significantly higher plasma levels of soluble intercellular adhesion molecule-1 (sICAM-1) (298.13 +/- 41.24 ng/ml versus 241.35 +/- 37.48 ng/ml; P < 0.001), sE-Selectin (63.31 +/- 9.48 ng/ml versus 42.16 +/- 14.18 ng/ml; P < 0.001) and sP-Selectin (161.18 +/- 20.85 ng/ml versus 111.54 +/- 26.12 ng/ml; P < 0.001) compared with overweight, non-hyperlipidemic control subjects. Combined hyperlipidemia in adults with overweight is associated with elevated soluble plasma levels of CAMs. We suppose that levels of CAMs in these patients may be determined as a marker for appreciation of their potential atherosclerotic burden.
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PMID:Increasing plasma levels of soluble cell adhesion molecules (sE-Selectin, sP-Selectin and sICAM-1) in overweight adults with combined hyperlipidemia. 1244 98

Combined hyperlipidemia predisposes subjects to coronary heart disease. Two lipid abnormalities--increased cholesterol and atherogenic dyslipidemia--are potential targets of lipid-lowering therapy. Successful management of both may require combined drug therapy. Statins are effective low-density lipoprotein (LDL) cholesterol-lowering drugs. For atherogenic dyslipidemia (high triglycerides, small LDL, and low high-density lipoprotein [HDL]), fibrates are potentially beneficial. The present study was designed to examine the safety and efficacy of a combination of low-dose simvastatin and fenofibrate in the treatment of combined hyperlipidemia. It was a randomized, placebo-controlled trial with a crossover design. Three randomized phases were employed (double placebo, simvastatin 10 mg/day and placebo, and simvastatin 10 mg/day plus fenofibrate 200 mg/day). Each phase lasted 3 months, and in the last week of each phase, measurements were made of plasma lipids, lipoprotein cholesterol, plasma apolipoproteins B, C-II, and C-III and LDL speciation on 3 consecutive days. Simvastatin therapy decreased total cholesterol by 27%, non-HDL cholesterol by 30%, total apolipoprotein B by 31%, very low-density lipoprotein (VLDL) + intermediate-density lipoprotein (IDL) cholesterol by 37%, VLDL + IDL apolipoprotein B by 14%, LDL cholesterol by 28%, and LDL apolipoprotein B by 21%. The addition of fenofibrate caused an additional decrease in VLDL + IDL cholesterol and VLDL + IDL apolipoprotein B by 36% and 32%, respectively. Simvastatin alone caused a small increase in the ratio of large-to-small LDL, whereas the addition of fenofibrate to simvastatin therapy caused a marked increase in the ratio of large-to-small LDL species. Simvastatin alone produced a small (6%) and insignificant increase in HDL cholesterol concentrations. When fenofibrate was added to simvastatin therapy, HDL cholesterol increased significantly by 23%. No significant side effects were observed with either simvastatin alone or with combined drug therapy. Therefore, a combination of simvastatin 10 mg/day and fenofibrate 200 mg/day appears to be effective and safe for the treatment of atherogenic dyslipidemia in combined hyperlipidemia.
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PMID:Effects of adding fenofibrate (200 mg/day) to simvastatin (10 mg/day) in patients with combined hyperlipidemia and metabolic syndrome. 1268 35

Combined hyperlipidemia is increasing in frequency and is the most common lipid disorder associated with obesity, insulin resistance and diabetes mellitus. It is associated with other features of the metabolic syndrome including hypertension, hyperuricemia, hyperinsulinemia and highly atherogenic subfractions of lipoprotein remnant particles including small dense low density lipoprotein-cholesterol. This review examines the mechanisms by which combined hyperlipidemia arises and the various drugs including fibric acid derivatives, hydroxymethylglutaryl coenzyme A (HMG-CoA) reductase inhibitors, and nicotinic acid which can be used either as monotherapy or in combination to manage it and to improve prognosis from atherosclerotic disease in diabetes mellitus, insulin resistant states and primary combined hyperlipidemia. The therapeutic approach to combined hyperlipidemia involves determination of whether the cause is hepatocyte damage or metabolic derangements. Combined hyperlipidemia due to hepatocyte damage should be treated by attention to the primary cause. In the case of metabolic dysfunction because of imbalance in glucose and fat metabolism, therapy of diabetes mellitus and obesity should be optimised prior to commencement of lipid lowering drugs. Both fibric acid derivatives and HMG-CoA reductase inhibitors can be used in the treatment of combined hyperlipidemia with fibric acid derivatives having greater effects on triglycerides and HMG-CoA reductase inhibitors on LDL-C though both have effects on the other cardiovascular risk factors. There is some evidence of benefit with both interventions in mild combined hyperlipidemias and large scale trials are underway. Fibric acid derivatives and HMG-CoA reductase inhibitor therapy can be combined with care, provided that gemfibrozil is avoided, fibric acid derivatives are given in the mornings and shorter half -life HMG-CoA reductase inhibitors are used at night. Combined hyperlipidemia emergencies occur with predominant hypertriglyceridemia in pregnancy or as a cause of pancreatitis. Therapy in the former should aim to reduce chylomicron production by a low fat diet and intervention to suppress VLDL-C secretion using omega-3 fatty acids. In the latter case, fluid therapy alone and medium chain plasma triglyceride infusions usually reduce levels satisfactorily though apheresis may be required. Blood glucose levels also need aggressive management in these conditions. Combined hyperlipidemia is likely to become an increasing problem with the increase in the prevalence of obesity and diabetes mellitus and needs aggressive management to reduce cardiovascular risk.
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PMID:Drug treatment of combined hyperlipidemia. 1472 15

Combined hyperlipidemia is associated with endothelial dysfunction. Atorvastatin has lipid-lowering and pleiotropic properties, including a protective effect on endothelial function. This study investigated the short- and medium-term effects of therapy with atorvastatin and of its discontinuation on lipid lowering and endothelial function. In 33 patients with combined hyperlipidemia who had been randomized and treated for 6 weeks with 40 mg of atorvastatin twice daily (n = 23) or placebo (n = 10), fasting lipid levels and flow-mediated dilation (FMD) of the brachial artery were measured at baseline, after 12 hours, 1 week, and 6 weeks during therapy, and 36 hours after discontinuation of therapy. Thereafter, all patients received 20 mg/day of atorvastatin for another 6 weeks. In the atorvastatin group, low-density lipoprotein cholesterol was decreased by 30% and 46% after 1 and 6 weeks, respectively (p <0.0001 for the 2 comparisons). In patients who already showed an impaired FMD at the beginning of the study (n = 15), atorvastatin caused a significant improvement in FMD, from 2.6% at baseline to 4.0% and 6.3% after 1 and 6 weeks, respectively (p <0.05 and <0.001). Thirty-six hours after withdrawal of atorvastatin, the FMD in this group decreased again to 2.8% (p <0.05), whereas low-density lipoprotein cholesterol level remained unchanged. The 6 patients with normal FMD at baseline showed no improvement in FMD during therapy or any decrease after withdrawal of the drug. In conclusion, only patients with endothelial dysfunction profit from high-dose atorvastatin treatment. When the treatment is abruptly discontinued, the effect on FMD disappears in 36 hours.
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PMID:Early effects on endothelial function of atorvastatin 40 mg twice daily and its withdrawal. 1656 5


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