Fluvastatin slow-release lowers platelet-activating factor acetyl hydrolase activity: a placebo-controlled trial in patients with type 2 diabetes

Fluvastatin reduces atherogenic dense low-density lipoprotein (dLDL) in patients with type 2 diabetes mellitus (T2DM). dLDLs are associated with platelet-activating factor acetyl hydrolase (PAF-AH), an enzyme involved in inflammation and related to coronary artery disease (CAD). The association of preexisting CAD and PAF-AH and the effect of fluvastatin on enzyme activity is investigated in a placebo-controlled trial in patients with T2DM. A multicenter, double-blind, randomized comparison of fluvastatin XL (80 mg) (n = 42) and placebo (n = 47), each given once-daily for 8 wk, in 89 patients with T2DM, was conducted. At baseline and on treatment, lipoproteins, including lipoprotein (a) [Lp(a)] and LDL subfractions, and the activity of PAF-AH were measured. Increasing PAF-AH activity was significantly associated with a positive history of CAD (+0.7% per IU/liter PAH-AH; P = 0.010), the odds ratio estimate adjusted for age, gender, and body mass index of the highest quartile being 10.6 (P = 0.036). At baseline and at study end, PAF-AH activity was associated with the apolipoprotein B (apoB) content in dLDL (LDL-5 and LDL-6) (r = 0.447; P < 0.001 and r = 0.651; P < 0.001, respectively) and with non-HDL cholesterol at baseline (r = 0.485; P < 0.001). However, after additional adjustment for apoB in dLDL and non-HDL cholesterol at baseline, the odds ratio increment for CAD across PAF-AH quartiles was 2.09 (95% confidence interval, 1.02-4.29; P = 0.043). Fluvastatin treatment decreased the activity of PAF-AH by 22.8% compared with an increase of 0.4% in the placebo group (P < 0.001). This effect was independent of changes of Lp(a) concentrations. In patients with T2DM, PAF-AH activity is associated with a positive history of CAD. Fluvastatin not only decreases atherogenic dLDL but also PAF-AH activity, emphasizing the significance of fluvastatin treatment in T2DM. The antiatherogenic potential of fluvastatin in T2DM may thus be greater than expected from its effects on LDL-C and triglycerides alone.     

Effect of fluvastatin slow-release on low density lipoprotein (LDL) subfractions in patients with type 2 diabetes mellitus: baseline LDL profile determines specific mode of action

The objective of this study was to determine the effect of slow-release (XL) fluvastatin on low density lipoprotein (LDL) subfractions in type 2 diabetes. A multicenter, double-blind, randomized, parallel-group comparison of fluvastatin XL 80 mg (n = 42) and placebo (n = 47), each given once-daily for 8 wk, in 89 patients with type 2 diabetes (HbA1c: 7.2 +/- 1.0%, LDL cholesterol (LDL-C): 3.4 +/- 0.7 mmol/liter, high density lipoprotein cholesterol: 1.1 +/- 0.3 mmol/liter, and triglycerides (TG): 2.4 +/- 1.4 mmol/liter). At baseline and on treatment, plasma lipoproteins were isolated and quantified. Eight weeks of fluvastatin treatment decreased total cholesterol (-23.0%, P < 0.001), LDL-C (-29%, P < 0.001) and TG (-18%, P < 0.001), compared with placebo. At baseline, there was a preponderance of dense LDL (dLDL) (apolipoprotein B in LDL-5 plus LDL-6 > 25 mg/dl) in 79% of patients, among whom fluvastatin decreased all LDL subfractions, reductions in dLDL being greatest (-28%, P = 0.001; cholesterol in dLDL -29%). In patients with low baseline dLDL (apolipoprotein B in LDL-5 plus LDL-6 相似文献   

Is glycation of low density lipoproteins in patients with Type 2 diabetes mellitus a LDL pre-oxidative condition?

AIMS: The study aimed to evaluate whether low density lipoprotein (LDL) in diabetic patients is more glycated and susceptible to oxidation than in non-diabetic subjects and investigated the hypothesis that LDL glycation is associated with an increased plasma concentration of LDL- (a circulating electronegatively charged LDL), proposed as an index of in vivo oxidation. METHODS: LDL glycation was measured by a competitive enzyme immunoadsorbent assay, using a monoclonal antibody against glycated apoB in 24 Type 2 diabetic patients and 12 healthy controls. LDL- was separated by ion-exchange HPLC in LDL samples obtained after sequential preparative ultracentrifugation (density range 1.019-1.063). In vitro LDL susceptibility to oxidation was evaluated by following the kinetics of conjugated diene formation and by measuring the lag-phase time in the presence of copper (Cu2+) ions. RESULTS: The percentages of glycated apoB (3.33+/-2.54% vs. 1.24+/-0.71%) and of LDL- (3.88+/-1.49% vs. 2.34+/-1.03%) in total LDL were significantly higher in diabetic patients (P<0.01 for both). LDL- was positively correlated with glycated apoB (r = 0.68, P<0.001). LDL isolated from Type 2 diabetic patients showed a significant decrease (P<0.001) in the resistance to oxidative stress, as indicated by the shorter lag-phase time (91+/-12.6 vs. 120+/-24.5 min). The lag-phase time was inversely correlated with glycated apoB (r = -0.65, P<0.001) and LDL- concentrations (r = -0.69, P<0.001). CONCLUSIONS: In this population of Type 2 diabetic patients, LDL were more glycated, more susceptible to in vitro oxidation and had a higher percentage of electronegative LDL. The glycation of apoB is proposed to be associated with a significative increase of in vivo and in vitro LDL oxidation.     

Qualitative effect of fenofibrate and quantitative effect of atorvastatin on LDL profile in combined hyperlipidemia with dense LDL.

INTRODUCTION: The association of elevated plasma triglyceride concentrations, decreased HDL-cholesterol, and dense LDL (dLDL) is referred to as the atherogenic lipoprotein phenotype. dLDL particularly plays a role in the metabolic syndrome and type 2 diabetes and may be one of the factors responsible for the increased risk for coronary artery disease in these patients. The effect of fenofibrate and atorvastatin on the LDL subfraction profile in patients with combined hyperlipidemia and a preponderance of dLDL was studied in a sequential design. METHODS: Six male patients with combined hyperlipidemia and dLDL received 160 mg/die supra-bioavailable fenofibrate. After a washout phase of 8 weeks all patients received 10 mg/die atorvastatin for another 8 weeks. At baseline, after fenofibrate, and after atorvastatin treatment LDL subfractions were analyzed by equilibrium density gradient ultracentrifugation. RESULTS: Treatment with atorvastatin and fenofibrate reduced serum cholesterol by 30 % and 21 % (p = 0.046) (p-values for differences between treatment groups), triglycerides by 32 % and 45 %, LDL cholesterol by 28 % and 16 %, and increased HDL cholesterol by 3 % and 6 %, respectively. Atorvastatin and fenofibrate treatment resulted in the following changes of apoB and LDL subfractions: LDL-1 (1.019 - 1.031 kg/L) - 31 % and + 15 % (p = 0.028); LDL-2 (1.031 - 1.034 kg/L) - 14 % and + 57 % (p = 0.028); LDL-3 (1.034 - 1.037 kg/L) - 20 % and + 30 % (p = 0.028); LDL-4 (1.037 - 1.040 kg/L) - 25 % and - 6 %; LDL-5 (1.040 - 1.044 kg/L) - 29 % and - 38 %; and LDL-6 (1.044 - 1.063 kg/L) - 39 % and - 55 % (p = 0.028). As a consequence, fenofibrate reduced LDL density significantly (p = 0.028 versus atorvastatin). CONCLUSIONS: Atorvastatin decreased all LDL-subfractions to a similar extent (quantitative effect) whereas fenofibrate reduced predominantly dLDL and changed the LDL profile towards medium dense LDL-particles (qualitative effect). Since medium dense LDL have a higher affinity to the LDL-receptor fenofibrate may have a higher antiatherogenic potential than assessed by the reduction of total LDL-cholesterol and triglycerides alone.     

Intermediate density lipoprotein levels are strong predictors of the extent of aortic atherosclerosis in the St. Thomas's Hospital rabbit strain

This study assessed nonfasting cholesterol and triglyceride in plasma and in lipoproteins as predictors of the extent of aortic atherosclerosis in 2 similar groups of rabbits from the St. Thomas's Hospital strain; the lipoprotein classes studied in the 2 groups were very low (VLDL), intermediate (IDL), low (LDL), and high density lipoprotein (HDL), and Sf greater than 60 lipoprotein, Sf 12-60 lipoprotein, LDL and HDL, respectively. These rabbits exhibit elevated plasma levels of VLDL, IDL, and LDL, with plasma cholesterol and triglyceride of up to 23 mmol/l and 7 mmol/l, respectively, and with up to 100% of the aortic intima bearing atherosclerosis-like lesions. In group 1 rabbits (n = 25), univariate linear regression showed that cholesterol in plasma, LDL, IDL and in VLDL each were positively associated with the extent of aortic atherosclerosis. In group 2 rabbits (n = 20), cholesterol in plasma, LDL and Sf 12-60, but not in Sf greater than 60 lipoprotein, was consistently positively associated with the extent of aortic atherosclerosis. Neither plasma triglyceride, triglyceride in lipoprotein fractions nor HDL cholesterol was associated consistently with the extent of atherosclerosis. Using step-up multiple linear regression among lipoprotein lipids, IDL and Sf 12-60 lipoprotein cholesterol were the most powerful independent predictors of the extent of aortic atherosclerosis in the 2 groups of rabbits. LDL cholesterol was the only other independent predictor. The results suggest that remnant lipoproteins, whether defined as IDL or Sf 12-60 lipoprotein, play an important causal role in atherosclerosis under conditions where plasma levels of these lipoproteins are elevated.     

Mechanism of action of a 3-hydroxy-3-methylglutaryl coenzyme a reductase inhibitor on apolipoprotein B-100 kinetics in visceral obesity

We examined the effect of atorvastatin, an inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A reductase, on the kinetics of apolipoprotein B-100 (apoB) metabolism in 25 viscerally obese men in a placebo-controlled study. Very-low-density lipoprotein (VLDL), intermediate-density lipoprotein (IDL), and low-density lipoprotein (LDL) apoB kinetics were measured using an iv bolus injection of [(2)H(3)]leucine. ApoB isotopic enrichment was measured using gas chromatography-mass spectrometry. Kinetic parameters were derived by using a multicompartmental model (SAAM-II). Compared with the placebo group, atorvastatin treatment resulted in significant (P < 0.001) decreases in total cholesterol (-34%), triglyceride (-19%), LDL cholesterol (-42%), total apoB (-39%), and lathosterol (-86%); VLDL-apoB, IDL-apoB, and LDL-apoB pool sizes also fell significantly (P < 0.002) by -27%, -22%, and -41%, respectively. This was associated with an increase in the fractional catabolic rates of VLDL-apoB (+58%, P = 0.019), IDL-apoB (+40%, P = 0.049), and LDL-apoB (+111%, P = 0.001). However, atorvastatin did not significantly alter the production and conversion rates of apoB in all lipoproteins. We conclude that in obese subjects, atorvastatin decreases the plasma concentration of all apoB-containing lipoproteins chiefly by increasing their catabolism and not by decreasing their production or secretion. This may be owing to up-regulation of hepatic receptors as a consequence of inhibition of cholesterogenesis.     

Two subpopulations of intermediate density lipoprotein and their relationship to plasma triglyceride and cholesterol levels

We observed the appearance of two intermediate density lipoprotein (IDL) subfractions on gradient gel electrophoresis of lipoproteins in the density range 1.006-1.030 g/ml and estimated their approximate concentrations in plasma in subjects with a wide range of lipid levels, from 0.55 to 28.0 mmol/l plasma triglyceride and 3.75-10.0 mmol/l cholesterol. The larger species, IDL-I (31.7 +/- 0.7 nm, mean +/- SD), showed little variation in size in normal and moderate hyperlipidaemic individuals. The estimated concentration of IDL-I was positively related to plasma triglyceride (r = 0.63, P = 0.0004) and low density lipoprotein (LDL) cholesterol (r = 0.68, P = 0.0003). These findings are consistent with the view that IDL-I is a metabolic intermediate between very low density lipoprotein (VLDL) and LDL. The smaller subfraction, IDL-II (25.7 +/- 2.4 nm) was virtually the only true species observed in subjects with plasma triglyceride < 1.0 mmol/l and its estimated concentration fell as plasma triglyceride increased (r = -0.58, P = 0.0002). IDL-II particle size changed in concert with LDL particle size (r = 0.61, P < 0.0001), suggesting that they were influenced by common metabolic factors. These observations provide further support for the hypothesis outlined by Musliner et al. [1] that IDL-I was part of the delipidation chain from VLDL to LDL, whereas IDL-II arose from a separate source, possibly directly released from the liver. Hence the two subpopulations of IDL differ in their relationship to plasma triglyceride and cholesterol levels.     

Lipoprotein alterations in hemodialysis: differences between diabetic and nondiabetic patients

Both renal failure and type 2 diabetes may contribute synergistically to the dyslipemia of diabetic renal failure with the development of atherosclerosis as the possible consequence. It has not yet been conclusively evaluated whether diabetic patients with end-stage renal failure under maintenance hemodialysis (HD) show accentuated alterations in plasma lipids and lipoproteins in comparison to nondiabetics under HD. These abnormalities would involve hepatic lipase activity and the regulation of triglyceride-rich lipoprotein metabolism. The purpose of the present study was to evaluate whether type 2 diabetic patients undergoing HD exhibited a lipid-lipoprotein profile different from that of nondiabetic hemodialyzed patients. We compared plasma lipids, apoprotein (apo) A-I and B, and lipoprotein parameters among 3 groups: 25 type 2 diabetics, 25 nondiabetics, both undergoing HD, and 20 healthy control subjects. Intermediate-density lipoprotein (IDL) and low-density lipoprotein (LDL) were isolated by sequential ultracentrifugation. Hepatic lipase activity was measured in postheparin plasma. Both groups of HD patients showed higher triglyceride and IDL cholesterol (P <.001), and lower high-density lipoprotein (HDL) cholesterol (P <.01) and apo A-I (P <.001) levels compared to the control group, even after adjustment for age and body mass index (BMI). However, no differences were found in lipid, lipoprotein, and apoprotein concentrations between diabetic and nondiabetic HD patients, except for high LDL triglyceride content of diabetic HD patients (P <.01). Nondiabetics undergoing HD also presented higher LDL triglyceride levels than controls (P <.05). LDL triglyceride correlated with plasma triglycerides (r = 0.51, P <.001). A lower LDL cholesterol/apo B ratio was found in each group of HD patients in comparison to controls (P <.02). Comparing the diabetic and nondiabetic patients, hepatic lipase activity remained unchanged, but significantly lower than control subjects (P <.001). Hepatic lipase correlated with log-triglyceride (r = -0.31, P <.01), IDL cholesterol (r = -0.41, P <.001), and LDL triglyceride (r = -0.32, P <.01). In conclusion, both diabetic and nondiabetic HD patients shared unfavorable alterations in lipid-lipoprotein profile not different between them but different from a healthy control group. The only difference between the groups of HD patients was a significant LDL triglyceride enrichment, which correlated negatively with hepatic lipase activity. Lipoprotein abnormalities in HD patients would enhance their risk for the development of atherosclerosis.     

Influence of plasma triglycerides on lipoprotein patterns in normal subjects and in patients with coronary artery disease

This study examined the correlation of plasma triglyceride levels with concentrations of intermediate, low and high density lipoproteins (IDL, LDL, and HDL, respectively) and to particle sizes of LDL in 93 normal men and 106 men with coronary artery disease. Plasma triglyceride concentrations were in the normal range for all persons in both groups. Analysis of lipoproteins of density less than 1.063 g/ml was carried out by analytical ultracentrifugation. The analytical pattern gave the peak Sf for LDL as well as an indication of heterogeneity of particle sizes in the density range of LDL. In both normal subjects and patients with coronary artery disease, a positive correlation was found between peak Sf for LDL and concentrations of plasma triglycerides. Plasma triglyceride levels also were correlated positively with concentrations of Sf 20 to 60 lipoproteins and total IDL mass, and inversely with HDL cholesterol levels. Furthermore, the value for peak Sf for LDL correlated inversely with the IDL mass concentration and IDL/LDL mass ratio, and positively with the HDL cholesterol levels. The results indicate that the lipoprotein pattern, including lipoprotein concentrations and particle sizes, is sensitive to concentrations of plasma triglycerides even when the latter are within the normal range.     

Preferential reduction of very low density lipoprotein-1 particle number by fenofibrate in type IIB hyperlipidemia: consequences for lipid accumulation in human monocyte-derived macrophages

The combined (mixed) type IIB phenotype is typically associated with premature atherosclerosis and characterised by concomitant elevation of plasma levels of atherogenic triglyceride-rich lipoproteins, consisting of very low density lipoprotein (VLDL)-1 (Sf 60-400), VLDL-2 (Sf 20-60), and intermediate density lipoprotein (IDL) (Sf 12-20), as well as small dense LDL. After dietary stabilisation, type IIB patients received micronised fenofibrate (267 mg/day) for up to 12 months. At baseline (T0), patients (n=11) displayed fasting triglyceride, cholesterol and apoB levels of 308+/-13, 350+/-17 and 187+/-9 mg/dl, respectively. Micronised fenofibrate (M-fenofibrate) induced marked reductions in plasma triglyceride (TG) (-61%, P<0.0001), total cholesterol (-32%, P=0.0005) and apolipoprotein (apo) B (-33%, P<0.001) at 12 months (T12); similar effects were seen after 3 months (T3) of treatment. These changes resulted from significant reductions in VLDL-1 (-75%, P=0.00001), VLDL-2 (-46%, P=0.002) and LDL (-33%, P<0.0003); IDL concentrations were unchanged. At baseline, VLDL-1 constituted the major TG-rich lipoprotein (TRL) fraction (50% of total mass), but only 25% at T12. These drug effects were accompanied by marked increase in HDL-C (+20%, P=0.018). Quantitative changes in triglyceride-rich lipoproteins were accompanied by significant qualitative modifications in particle size and chemical composition (VLDL-1: TG, -10.7%, P<0.001; FC, +59%, P=0.0002; PL, +19%, P=0.033; VLDL-2: FC, +11%, P=0.027; IDL: FC, +14%, P=0.0004; PL, +12%, P=0.002). Reduction in the TG content of VLDL-1 was reflected in a shift of particle size distribution to smaller diameters (mean 45.4 and 42.3 nm, respectively, at T0 and T12). We evaluated the relative atherogenicity of TRL subfractions by determining their capacity, when normalised to equal particle numbers (as apoB 100 content), to induce lipid accumulation in human monocyte-derived macrophages. Among TRL subfractions, VLDL-1 (100 microg apoB/ml) possessed the highest capacity to induce macrophage lipid loading (up to sevenfold increase in TG content, P<0.001; free cholesterol, up to 1.7-fold; P<0.05). At 100 microg apoB/ml, cellular TG loading from VLDL-1 was twofold greater than that for VLDL-2 (P<0.01), and fivefold greater than for IDL (P<0.01). Despite drug-induced changes in the qualitative properties of TRL subfractions, the activity of VLDL-1, VLDL-2 and IDL as ligands which lead to induction of macrophage lipid accumulation, at equivalent particle numbers, was not detectably altered. By contrast, the fibrate-mediated reduction in the number of circulating VLDL-1 and VLDL-2 particles (four and twofold, respectively) resulted in marked decrease in cellular lipid loading. Considered together, these findings suggest that fenofibrate may act at systemic and arterial levels to reduce the cardiovascular risk associated with VLDL subfractions in patients with a combined hyperlipidemic (type IIB) phenotype. Indeed, we speculate that reductions in circulating levels of VLDL-1 and VLDL-2 may diminish intimal penetration of these particles and thus their propensity to enhance arterial macrophage lipid accumulation and foam cell formation. Finally, fenofibrate further attenuated the atherogenic lipid profile in these patients by inducing marked reduction in LDL and elevation in cardioprotective HDL.     

Estimation of cholesterol loading of the low-density lipoprotein fraction in diabetic subjects without ultracentrifugation

We report here a new formula for estimating apolipoprotein (apo) B concentration in the low-density lipoprotein (LDL) fraction from measurements of plasma triglyceride and apoB. ApoB in plasma and in the triglyceride-rich lipoprotein fraction (VLDL, d less than 1.019) and plasma triglyceride were measured in 112 subjects, including 56 diabetics. There was a significant correlation between VLDL-apoB and plasma triglyceride (Y = 0.07X + 1, r = 0.73, P less than 0.001). We calculated LDL-apoB according to this formula: LDL-apoB = total apoB - (0.07 x total triglyceride + 1). We found an excellent relationship between LDL-apoB (total apoB - VLDL-apoB) and calculated LDL-apoB (Y = 1.0X + 1, r = 0.96, P less than 0.001). This new formula will enable us to estimate the apoB concentration in the LDL fraction without ultracentrifugation.     

Influence of atorvastatin and simvastatin on apolipoprotein B metabolism in moderate combined hyperlipidemic subjects with low VLDL and LDL fractional clearance rates

Subjects with moderate combined hyperlipidemia (n=11) were assessed in an investigation of the effects of atorvastatin and simvastatin (both 40 mg per day) on apolipoprotein B (apoB) metabolism. The objective of the study was to examine the mechanism by which statins lower plasma triglyceride levels. Patients were studied on three occasions, in the basal state, after 8 weeks on atorvastatin or simvastatin and then again on the alternate treatment. Atorvastatin produced significantly greater reductions than simvastatin in low density lipoprotein (LDL) cholesterol (49.7 vs. 44.1% decrease on simvastatin) and plasma triglyceride (46.4 vs. 39.4% decrease on simvastatin). ApoB metabolism was followed using a tracer of deuterated leucine. Both drugs stimulated direct catabolism of large very low density lipoprotein (VLDL(1)) apoB (4.52+/-3.06 pools per day on atorvastatin; 5.48+/-4.76 pools per day on simvastatin versus 2.26+/-1.65 pools per day at baseline (both P<0.05)) and this was the basis of the 50% reduction in plasma VLDL(1) concentration; apoB production in this fraction was not significantly altered. On atorvastatin and simvastatin the fractional transfer rates (FTR) of VLDL(1) to VLDL(2) and of VLDL(2) to intermediate density lipoprotein (IDL) were increased significantly, in the latter instance nearly twofold. IDL apoB direct catabolism rose from 0.54+/-0.30 pools per day at baseline to 1.17+/-0.87 pools per day on atorvastatin and to 0.95+/-0.43 pools per day on simvastatin (both P<0.05). Similarly the fractional transfer rate for IDL to LDL conversion was enhanced 58-84% by statin treatment (P<0.01) LDL apoB fractional catabolic rate (FCR) which was low at baseline in these subjects (0.22+/-0.04 pools per day) increased to 0.44+/-0.11 pools per day on atorvastatin and 0.38+/-0.11 pools per day on simvastatin (both P<0.01). ApoB-containing lipoproteins were more triglyceride-rich and contained less free cholesterol and cholesteryl ester on statin therapy. Further, patients on both treatments showed marked decreases in all LDL subfractions. In particular the concentration of small dense LDL (LDL-III) fell 64% on atorvastatin and 45% on simvastatin. We conclude that in patients with moderate combined hyperlipidemia who initially have a low FCR for VLDL and LDL apoB, the principal action of atorvastatin and simvastatin is to stimulate receptor-mediated catabolism across the spectrum of apoB-containing lipoproteins. This leads to a substantial, and approximately equivalent, percentage reduction in plasma triglyceride and LDL cholesterol.     

Reduction in visceral adipose tissue is associated with improvement in apolipoprotein B-100 metabolism in obese men.

We investigated the effect of reduction in visceral obesity on the kinetics of apolipoprotein B-100 (apoB) metabolism in a controlled dietary intervention study in 26 obese men. Hepatic secretion of very low density lipoprotein (VLDL) apoB was measured using a primed, constant, infusion of 1-[13C]leucine. In seven men receiving the reduction diet, intermediate density lipoprotein (IDL) and low density lipoprotein (LDL) apoB kinetics were also determined. ApoB isotopic enrichment was measured using gas chromatography-mass spectrometry, and SAAM-II was used to estimate the fractional turnover rates. Subcutaneous and visceral adipose tissues at the L3 vertebra were quantified by magnetic resonance imaging. With weight reduction there was a significant decrease (P < 0.05) in body mass index, waist circumference, and visceral adipose tissue. The plasma concentrations of total cholesterol, triglyceride, insulin, and lathosterol also significantly decreased (P < 0.05). Compared with weight maintenance, weight reduction significantly decreased the VLDL apoB concentration, pool size, and hepatic secretion of VLDL apoB (delta+2.5+/-4.6 vs. delta-14.7+/-4.0 mg/kg fat free mass-day; P = 0.010), but did not significantly alter its fractional catabolism. Weight reduction was also associated with an increased fractional catabolic rate of LDL apoB (0.24+/-0.07 vs. 0.54+/-0.10 pools/day; P = 0.002) and conversion of VLDL to LDL apoB (11.7+/-2.5% vs. 56.3+/-11.4%; P = 0.008). A change in hepatic VLDL apoB secretion was significantly correlated with a change in visceral adipose tissue area (r = 0.59; P = 0.043), but not plasma concentrations of insulin, free fatty acids, or lathosterol. The data support the hypothesis that a reduction in visceral adipose tissue is associated with a decrease in the hepatic secretion of VLDL apoB, and this may be due to a decrease in portal lipid substrate supply. Weight reduction may also increase the fractional catabolism of LDL apoB, but this requires further evaluation.     

Negatively charged low-density lipoprotein is associated with atherogenic risk in hypertensive patients

Negatively charged low-density lipoprotein (LDL), generated via multiple processes such as oxidation, acetylation, or glycosylation, plays a key role in the initiation and progression of atherosclerosis and related diseases. Anion-exchange high-performance liquid chromatography (AE-HPLC) can subfractionate LDL into LDL-1, LDL-2, and LDL-3 based on LDL particle charge, but the clinical significance of LDL subfractions has not yet been elucidated. The aim of this study was to determine the clinical significance of these fractions with particular regard to atherogenic risk in hypertensive patients. Ninety-eight patients with essential hypertension (age 67.0 ± 10.7 years; 54 males) were enrolled in the present study. The relationships between LDL subfractions and atherogenic risk factors, including lipid profiles, blood pressure and plasma 8-isoprostane as a marker of oxidative stress, were examined. LDL-1 levels were significantly and negatively correlated with body mass index (r = -0.384, p < 0.001), systolic blood pressure (r = -0.457, p < 0.001), non-high-density lipoprotein cholesterol levels (r = -0.457, p < 0.001) and 8-isoprostane levels (r = -0.415, p < 0.001). LDL-3, which is the most negatively charged fraction of total LDL, was significantly and positively correlated with these parameters (r = 0.267, 0.481, 0.357, and 0.337, respectively). LDL-1 levels were significantly lower (p < 0.001), and LDL-2 and LDL-3 levels were significantly higher (each p < 0.001) in patients with poorly controlled hypertension than in patients with well-controlled hypertension. In addition, an increase in the total number of traditional risk factors at time of study participation, but not previous diagnosis, was associated with a decrease in LDL-1 levels and increases in LDL-2 and LDL-3 levels. These data suggest that LDL subfractions are associated with multiple atherogenic risk factors and that treatment to modify these risk factors could result in changes in LDL subfraction levels. In conclusion, LDL subfractions isolated by AE-HPLC may represent a marker of atherogenic risk in patients with hypertension.     

Effect of LDL+VLDL oxidizability and hyperglycemia on blood cholesterol, phospholipid and triglyceride levels in type-I diabetic patients

Oxidative modification of low-density lipoproteins has been implicated in impaired lipid metabolism and its deposition in the arterial wall, and atherosclerosis. This study was carried out to determine the relationship between the in vitro oxidizability of low-density lipoprotein (LDL) and very-low-density lipoprotein (VLDL) and the cholesterol, phospholipid and triglyceride (TG) levels in the blood of Type-I diabetic patients. LDL+VLDL was isolated using a micro-affinity column from serum of diabetic patients (n = 34) and age-matched normal individuals (n = 22). The oxidative susceptibility of LDL+VLDL was determined by treatment with 25 microM CuCl(2) for 1.5 h. The levels of total-, LDL-, and HDL-cholesterol, phospholipids and triglycerides, as well as glycated hemoglobin (HbA(t)), were measured in the blood using standard methods. The diabetics had significantly higher levels of triglycerides and phospholipids, but cholesterol levels were similar between Type-I diabetics and age-matched normals. However, among diabetics, there was a significant correlation between the in vitro oxidation of LDL+VLDL at 1.5 h and total cholesterol (r = 0.49, P<0.002), and LDL cholesterol (r = 0.54, P<0.001) and TG (r = 0.34, P<0.05) levels. The level of in vitro oxidizability of LDL+VLDL did not have any correlation with HDL-cholesterol or phospholipid levels. The level of glycemic control (HbA(1)) did not have any correlation with levels of LDL- or HDL-cholesterol or triglycerides, but was significantly correlated with phospholipid levels (r = 0.48, P<0.005). This study suggests that the levels of LDL-cholesterol and triglycerides in the blood are directly related to the degree of in vitro oxidative susceptibility of low-density lipoproteins in Type-1 diabetic patients.     

Dose-dependent action of atorvastatin in type IIB hyperlipidemia: preferential and progressive reduction of atherogenic apoB-containing lipoprotein subclasses (VLDL-2, IDL,small dense LDL) and stimulation of cellular cholesterol efflux

Type IIB hyperlipidemia is associated with premature vascular disease, an atherogenic lipoprotein phenotype characterised by elevated levels of triglyceride-rich VLDL and small dense LDL, together with subnormal levels of HDL. The dose-dependent and independent effects of a potent HMGCoA reductase inhibitor, Atorvastatin, at daily doses of 10 and 40 mg, were evaluated on triglyceride-rich lipoprotein subclasses (VLDL-1, VLDL-2 and IDL), on the major LDL subclasses (light LDL, LDL-1+LDL-2, D: 1.019-1.029 g/ml; intermediate LDL, LDL-3, D: 1.029-1.039 g/ml and small dense LDL, LDL-4+LDL+5, D: 1.039-1.063 g/ml), on CETP-mediated cholesteryl ester transfer from HDL to apoB-containing lipoproteins, on phospholipid transfer protein activity and on plasma-mediated cellular cholesterol efflux in patients (n=10) displaying type IIB hyperlipidemia. Plasma concentrations of triglyceride-rich lipoprotein subclasses (TRL: VLDL-1, Sf 60-400; VLDL-2, Sf 20-60 and IDL, Sf 12-20) and of LDL (D: 1.019-1.063 g/ml) were markedly diminished after 6 weeks of statin treatment at 10 mg per day (-31 and -36%, respectively; P<0.002) and by 42 and 51%, respectively at the 40 mg per day dose. Increasing doses of atorvastatin progressively normalised both the quantitative and qualitative features of the LDL subclass profile, in which dense LDL predominated at baseline. Indeed, dense LDL levels were reduced by up to 57% at the 40-mg dose, leading to a shift in the peak of the density profile towards larger, buoyant LDL particles typical of normolipidemic subjects. In addition, marked reduction in numbers of apoB100-containing particle acceptors led to a 30% decrease (P<0.02) in CETP-mediated CE transfer from HDL. Finally, a significant dose-dependent statin-mediated elevation (+15% at 10 mg; P=0.0003 and +35% at 40 mg; P<0.0001 compared to baseline) in the capacity of plasma from type IIB subjects to mediate free cholesterol efflux from Fu5AH hepatoma cells was observed. Moreover, atorvastatin (40 mg per day) significantly increased plasma apoAI levels (+24%; P<0.05), thereby suggesting that this statin enhances production of apoAI and with it, formation of nascent pre-beta HDL particles. Plasma PLTP activity was not affected by either dose of atorvastatin. We conclude that increasing the dose of atorvastatin leads to dose-dependent, preferential and progressive reduction in particle numbers of atherogenic VLDL-2, IDL and dense LDL, and concomitantly, to enhanced cellular cholesterol efflux in type IIB dyslipidemia, thereby diminishing the atherosclerotic burden in subjects characterised by high cardiovascular risk.     

Differences in low density lipoprotein subfractions and apolipoproteins in premenopausal and postmenopausal women

Postmenopausal or oophorectomized women are at higher risk for the development of coronary artery disease than are premenopausal women. These differences in risk may be due to alternations in plasma lipoproteins modulated by hormonal changes. Plasma cholesterol, triglyceride, lipoprotein cholesterol, and apolipoprotein A-I and B (apoB) concentrations, as well as low density lipoprotein (LDL) particle size (LDL 1-7), as assessed by 2-16% polyacrylamide-agarose gradient gel electrophoresis, were determined in 87 premenopausal and 43 postmenopausal women. All were participants in the Framingham Offspring Study, were gynecologically normal, and were not taking any hormones. The postmenopausal women had significantly (P less than 0.05) higher plasma LDL cholesterol concentrations than did the premenopausal women. Plasma triglyceride, total cholesterol, very low density lipoprotein cholesterol, and apoB levels were higher, and apoA-I and high density lipoprotein cholesterol were lower in the postmenopausal group, but these differences were not significant at P less than 0.05. The postmenopausal women were likely to have small LDL particles compared to premenopausal women. Controlling for age and body mass index effects significantly reduced the differences in total cholesterol, LDL cholesterol, apoB, and LDL particle size and broadened the differences in apoA-I and high density lipoprotein cholesterol. These data indicate that menopause is positively correlated with LDL cholesterol (P less than 0.05) and decreased LDL particle size (P less than 0.05) after adjusting for significant covariates.     

Factors Influencing the Low Density Lipoprotein Profile in Type 2 Diabetic Patients

The lipoprotein distribution profile was examined in Type 2 (non-insulin-dependent) diabetic patients (n = 52), with particular emphasis on factors influencing low density lipoproteins (LDL). Triglycerides were negatively correlated with LDL-2 (r = 0.34, p < 0.05) and positively correlated with smaller, denser LDL-3 (r = 0.57, p < 0.001). This yielded a highly significant, negative correlation between triglycerides and the LDL-2/LDL-3 mass ratio (r = -0.59, p < 0.001) which is an indication of the presence of smaller LDL particles. Parameters of glycaemic control, in the form of fasting blood sugar and glycated haemoglobin (HbA_1c), were also negatively correlated with the LDL-2/LDL-3 mass ratio in univariate analyses; both remained significantly correlated with the mass ratio when corrected for triglycerides. Stepwise multiple regression analysis identified a three-parameter model comprising triglycerides, HbA_1c, and high density lipoprotein cholesterol as best defining the variations in the LDL-2/LDL-3 mass ratio (adjusted r² = 0.52). These observations are consistent with an independent impact of diabetes on the LDL distribution profile and the possibility that the latter may be subjected to multiple pathological influences in diabetic patients.     

The association of increased levels of intermediate-density lipoproteins with smoking and with coronary artery disease

Studies were undertaken to determine whether there is an association between elevated levels of intermediate-density lipoproteins (IDL) (Sf 12-60 lipoproteins) and coronary artery disease. Forty-five to sixty-five-year-old men with objectively documented coronary artery disease (n = 58) who were free of known risk factors (diabetes, hypertension, obesity, hyperuricemia, and hypercholesterolemia) were compared with similar men who were free of coronary artery disease (n = 52). Smokers could not be excluded. The coronary artery disease group had a higher rate of cigarette smoking (NS, due to large variations); higher concentrations of triglycerides in their plasma (p = .003) and higher levels of very low-density lipoproteins (VLDL) (p = .007), IDL (p = .016), and low-density lipoproteins (LDL) (p = .04); as well as somewhat lower levels of high-density lipoprotein (HDL) cholesterol (p = .04). Chi-squared analysis demonstrated a strong association between coronary artery disease and IDL apolipoprotein (apo) B (p = .006), coronary artery disease and IDL triglyceride (p = .032), and coronary artery disease and IDL apo B times IDL triglyceride (p = .006) when the top quintile of the population was compared with the bottom quintile for each of these variables. Stepwise logistic regression analysis resulted in rejection of an association between coronary artery disease and HDL cholesterol, plasma triglyceride, VLDL triglyceride, or LDL triglyceride. However, it did show that coronary artery disease was most strongly associated with smoking and that the second strongest association was with IDL.(ABSTRACT TRUNCATED AT 250 WORDS)