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Target Concepts:
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Query: UMLS:C0242339 (
dyslipidemia
)
13,927
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The maximum tolerated dose and pharmacokinetics of a drug is usually determined in healthy human volunteers and animals. This data is then used to define the dosing recommendation for the diseased patient population. However, in the case of some hydrophobic drugs, the dose which is deemed nontoxic becomes ineffective and/or toxic when administered to the diseased patient. This observation might be explained by several lines of evidence which indicate that binding of drugs such as amphotericin B (AmpB) and cyclosporine (CSA) to plasma low-density lipoprotein- (LDL) cholesterol is involved in the development of kidney toxicity. Our preliminary studies have suggested that this phenomena might be due to increase
lipid transfer protein
(LTP 1) activity which promotes the transfer of AmpB from high-density lipoproteins to LDL. In addition, since LTP 1 function is regulated by the lipid content of plasma lipoproteins, we suggest that changes in lipoprotein composition that occur in
dyslipidemia
regulate the distribution of these and other hydrophobic drugs (i.e., annamycin and nystatin). The impact of these studies on hydrophobic drug therapy could have broad implications on how we evaluate and determine dosing of hydrophobic drugs in dyslipidemic patients. By understanding the mechanism(s) responsible for the distribution of hydrophobic compounds in the bloodstream, we are trying to define the effect of dyslipidemias on the plasma clearance and therapeutic index of hydrophobic compounds.
...
PMID:Modifications in plasma lipoprotein concentration and lipid composition regulate the biological activity of hydrophobic drugs. 887 13
Women with polycystic ovary syndrome (PCOS) appear at increased cardiovascular risk due in part to a
dyslipidemia
characterized by increased plasma triglyceride and reduced high density lipoprotein (HDL) cholesterol levels. This is a detailed exploratory study of HDL composition in 35 obese [body mass index (BMI), > 27] and 22 nonobese subjects with PCOS and in 14 healthy obese and 18 nonobese women. Although we found reduced levels of total and HDL2 cholesterol in obese women with PCOS, HDL composition was modified by depletion of lipid relative to protein, with reduced ratios of HDL total cholesterol and HDL phospholipids to apolipoprotein A-I (apoA-I) compared to those in obese controls (P = 0.008 and P = 0.012, respectively). This was explained by reduced cholesterol (P = 0.004) and phospholipid (although not significant, P = 0.07) in HDL with no change in the content of apoA-I, its major protein. Obesity, insulin resistance, and hyperandrogenemia are features of PCOS and potentially affect lipid metabolism. Insulin sensitivity was assessed by the reduction in endogenous glucose concentration after exogenous insulin; the insulin, glucose, and fatty acid responses to oral glucose; and the fasting insulin concentration. When age, BMI, free androgen index, insulin sensitivity determined by all methods, and the presence of PCOS were subjected to stepwise multivariate regression analysis, the presence of PCOS was the most consistent predictor of lipid-depleted HDL (HDL total cholesterol/apoA-I and HDL phospholipids/apoA-I). We speculate that altered activity of hepatic lipase or
lipid transfer protein
could explain this aspect of the
dyslipidemia
. Obesity has an important influence on the lipid profile. Obese PCOS and control subjects had higher levels of cholesterol, triglyceride, apoB, and fatty acids than their lean counterparts, and BMI proved the best predictor of blood levels on multiple regression analysis. In contrast, lean PCOS patients had normal sensitivity to insulin and lipid profiles similar to those of the lean controls and did not manifest the HDL abnormalities. Although in PCOS, correlations were obtained between the free androgen index and cholesterol, triglyceride, and apoB levels and between the integrated glucose and insulin responses after oral glucose and fasting fatty acid and triglyceride levels, when age and adiposity were included as covariates only fatty acids and the integrated glucose response remained significantly correlated. Among the controls, total, low density lipoprotein cholesterol, triglycerides, and apoB were related to aspects of insulin sensitivity independent of age and BMI. Lipid metabolism in PCOS is dependent on several related factors, but subjects with PCOS who are obese show a specific reduction in HDL lipid, suggesting a reduced capacity for cholesterol removal from tissues with diminished antiatherogenic potential. Efforts should be directed toward reducing obesity in PCOS to improve the metabolic disturbance in addition to ameliorating the presenting symptoms.
...
PMID:Altered composition of high density lipoproteins in women with the polycystic ovary syndrome. 932 74
The purpose of these studies was to determine the distribution of a lipophilic antimalarial agent, halofantrine hydrochloride (Hf), in fasted plasma from hypo-, normo-, and hyperlipidemic patients that displayed differences in lipoprotein concentration and
lipid transfer protein
I (LTP I) activity. To assess the influence of modified lipoprotein concentrations and LTP I activity on the plasma distribution of Hf, Hf at a concentration of 1000 ng/mL was incubated in either hypo-, normo-, or hyperlipidemic human plasma for 1 h at 37 degreesC. Following incubation, the plasma samples were separated into their lipoprotein and lipoprotein-deficient plasma (LPDP) fractions by density gradient ultracentrifugation and assayed for Hf by high-pressure liquid chromatography. The activity of LTP I in the dyslipidemic plasma samples was determined in terms of its ability to transfer cholesteryl ester from low-density lipoproteins (LDL) to high-density lipoproteins (HDL). Total plasma and lipoprotein cholesterol (esterified and unesterified), triglyceride, and protein levels in the dyslipidemic plasma samples were determined by enzymatic assays. When Hf was incubated in normolipidemic plasma for 1 h at 37 degreesC, the majority of drug was found in the LPDP fraction. When Hf was incubated in human plasma of varying total lipid, lipoprotein lipid, and protein concentrations and LTP I activity, the following relationships were observed. As the triglyceride-rich lipoprotein (TRL) lipid and protein concentration increased from hypolipidemia through to hyperlipidemia, the proportion of Hf associated with TRL increased (r > 0.90). As the HDL lipid and protein concentration increased, the proportion of Hf associated with HDL decreased (r > 0.70). As the total and lipoprotein lipid levels increased, the LTP I activity of the plasma also proportionally increased (r > 0.85). Furthermore, with the increase in LTP I activity, the proportion of Hf associated with the TRL fraction increased (r > 0.70) and the proportion of Hf associated with the HDL fraction decreased (r > 0.80). In addition, a positive correlation between the proportion of apolar lipid and Hf recovered within each lipoprotein fraction was observed within hypo- (r > 0.80), normo- (r = 0.70), and hyperlipidemic (r > 0.90) plasmas. These findings suggest that changes in the HDL and TRL lipid and protein concentrations, LTP I activity, and the proportion of apolar lipid within each lipoprotein fraction may influence the plasma lipoprotein distribution of Hf in
dyslipidemia
.
...
PMID:Differences in the lipoprotein distribution of halofantrine are regulated by lipoprotein apolar lipid and protein concentration and lipid transfer protein I activity: in vitro studies in normolipidemic and dyslipidemic human plasmas. 995 Jun 36
Cholesteryl ester transfer protein (CETP) plays a pivotal role in the reverse transport of cholesterol and in the remodeling of circulating lipoproteins. While plasma and adipose tissue levels of CETP are affected by a variety of metabolic conditions, the extent of the effects of dietary factors, other than high cholesterol feeding, are not well understood. To further explore this paradigm, male Golden Syrian hamsters were fed for 4 weeks with a 60%-enriched fructose diet (F) and were compared to a matched group of animals fed with a normal chow diet (N). After feeding for 4 weeks, plasma insulin concentrations were lower in animals fed fructose than in control animals (F: 3.3+/-0.8 vs N: 7.4+/-1.9 ng/mL; p<0.03), but there was no significant difference in plasma glucose concentrations between the two groups (F: 138+/-7 vs N: 148+/-10 mg/dL; p>0.05). Fructose-fed animals showed significant increases in plasma triglyceride (F: 269+/-22 vs N: 165+/-22 mg/dL; p<0.01) and plasma cholesterol (F: 150+/-10 vs N: 113+/-6 mg/dL; p<0.02) concentrations compared with control animals. Total CETP activity and immunoreactive mass were higher in the plasma of fructose-fed animals that in that of controls (F: 1036+/-70 vs N: 826+/-43 pmol/h/mL, p<0.04 and F: 24.5+/-3.1 vs N: 37.5+/-4.3 AU, p<0.02, respectively). Adipose tissue
CETP mRNA
levels, assessed by the very sensitive ribonuclease protection assay, were 53% higher in fructose-fed animals than in controls (F: 14.1+/-2.0 vs N: 9.2+/-1.0 AU over a rRNA control; p<0.04). Adipose tissue CETP activity and immunoreactive mass also showed a statistically significant increase in the fructose-fed hamsters compared with those fed a normal diet (p<0.04). In conclusion, fructose feeding in Syrian hamsters induces a mixed
dyslipidemia
. These metabolic changes are accompanied by a significant increase in CETP levels, both in plasma and in adipose tissue. This phenomenon suggests that the increase in the expression of adipose tissue CETP may be caused either by the ambient hypercholesterolemia resulting from fructose feeding or by an attenuation of a possible inhibitory effect of plasma insulin concentrations on the expression of adipose tissue CETP in this feeding paradigm.
...
PMID:Induction of cholesteryl ester transfer protein in adipose tissue and plasma of the fructose-fed hamster. 1147 89
