Treatment of small dense LDL

The increased frequency of small, dense LDL is associated with the risk of coronary heart disease (CHD). Possible mechanisms include the increased susceptibility of small, dense LDL to oxidation and its high affinity for LDL-receptor-independent cell surface binding sites. Although more than 30% of adult men in the USA have been reported to have small,dense LDL, only 5.4% of young Japanese men are affected. However, more than 76% of Japanese diabetics with coronary heart disease have small, dense LDL. Furthermore, almost half of all obese women (BMI > 35 kg/m(2)) have small, dense LDL. Our previous observation revealed that type 2 diabetics had smaller LDL even if they were apparently normolipidemic. In the normotriglycelidemic group there was also a close relationship between LDL size and plasma triglyceride. Diabetics with microalbuminuria had smaller LDL than those with normoalbuminuria, indicating the early nephrotoxicity of small, dense LDL. We also found that young men with high-normal blood pressure have smaller LDL than those with optimal blood pressure. Furthermore, LDL size was decreased not only in preeclamptic women but also in normal pregnant women. Finally, weight reduction by obese women through strict diet control, the treatment of diabetics by acarbose or troglitazone, and the treatment of hyperlipidemia by new statins as well as fibrates were all successful in increasing LDL size associated with decreased plasma triglyceride.     

Regulation of small dense LDL concentration in Korean and Scottish men and women

Small dense LDL is now emerging as an important risk factor for coronary artery disease. The amount of the LDL III has been reported to differ between ethnic groups. To investigate differences in the distribution of LDL subfractions between Korean and Scottish populations, we measured the plasma concentration and percent distribution of three major LDL subfractions in age-and sex-matched, middle aged, healthy 124 Korean and Scottish subjects (32 Korean men vs. 32 Scottish men; 30 Korean women vs. 30 Scottish women). Body mass index and waist circumference did not differ between the two ethnic groups. Total cholesterol and LDL cholesterol concentrations were higher in Scottish men compared with Korean men (P<0.01), while plasma triglyceride concentration was higher in Korean men and women (P<0.01 in men, P<0.05 in women). HDL cholesterol concentrations in both Korean men and women were lower than that of their Scottish counterparts (P<0.05 in men; P<0.001 in women). Korean men had lower concentrations of total LDL (242+/-65 vs. 325+/-122 mg/dl, P<0.01), LDL I (24+/-18 vs. 60+/-36 mg/dl, P<0.001) and LDL II (110+/-56 vs. 196+/-78 mg/dl, P<0.001). In contrast, LDL III concentration was markedly higher in Korean men (108+/-75 vs. 70+/-65 mg/dl, P<0.05). Likewise, the percent of LDL I (10.0+/-7.3 vs. 19.1+/-10.1%, P<0.001) and LDL II (47.2+/-20.7 vs. 60.1+/-10.9%, P<0.01) were lower in Korean men, while that of LDL III was higher (42.8+/-24.9 vs. 20.8+/-15.0%, P<0.001). In the female population, there were no differences in total LDL and LDL I concentrations between Korean and Scottish. LDL II concentration was lower in Korean women (106+/-53 vs. 151+/-57 mg/dl, P<0.01). Korean women showed a higher percent of LDL III (24.8+/-24.7 vs. 14.2+/-5.9%, P<0.05) and a lower LDL II (47.8+/-19.1 vs. 61.0+/-10.0%, P<0.01). Multiple linear regression revealed that plasma triglyceride concentration was the most important determinant of the LDL III subfraction concentration in Korean men and women and in Scottish men. In Korean men, the LDL III concentration rose linearly through the whole range of plasma triglyceride concentration, whereas in Scottish men, there was a threshold at 108 mg/dl triglyceride above which there was a positive association. Korean women showed the same pattern as Scottish men. We suggest that LDL concentrations and LDL subfraction distributions are regulated differently in these two ethnic groups. The different relationships between triglyceride and LDL III subfraction in Koreans versus Scots suggest that other factors, such as hepatic lipase or cholesteryl ester transfer protein may additionally play a role determining the LDL subfraction profile.     

The atherogenic lipoprotein phenotype: small dense LDL and lipoprotein remnants in nephrotic range proteinuria.

The dyslipidaemia in nephrotic-range proteinuria is believed to contribute to the increased atherogenesis associated with the condition. Excess small dense low density lipoprotein (LDLIII) contributes to this risk. Lipoprotein remnants (RLP) may also be implicated but have not been studied in this population. We measured the plasma concentration of low density lipoprotein (LDL) subfractions (by density gradient ultracentrifugation), RLP (by immunoaffinity gel), very low density lipoprotein (VLDL) subfractions, post heparin lipases and cholesteryl ester transfer protein (CETP) activity in 27 patients with glomerular disease and albuminuria >2.0g. These were compared with 27 age and sex matched controls. Proteinuric patients had increased LDLIII concentration (patients 182 (84:267) vs. controls 31 (27:62); P<0.0001) with reduced lighter LDLI (36 (24:43) vs 69 (46:101); P<0.0005) and LDLII (124 (79:220) vs 178 (129:236); P<0.04, all mg/dl, median+interquartile range). RLP-cholesterol (RLP-C) and triglyceride (RLP-TG) were increased in proteinuric patients (RLP-C 18.9 (11.0:26.9) vs 7.7 (6.0:8.8); P<0.0001, RLP-TG 35.8 (11.8:54.7) vs. 7.2 (4.3:10.0); P<0.0001, all mg/dl). Increased LDLIII and RLP were independent of renal function. VLDL(1) and VLDL(2) concentrations were increased by 258 and 260% (both P<0.0001). CETP activity was increased by 46% (P<0.005). Lipoprotein and hepatic lipase activities did not differ from control values. LDLIII concentration (r(2)=45.7%, P<0.001), RLP-C (r(2)=85.2%, P<0.001) and RLP-TG (r(2)=87.5%, P<0.001) all correlated positively with plasma triglyceride. Moreover, increased LDLIII was associated with both RLP-C (r(2)=31.3%, P<0.002) and RLP-TG (r(2)=33.6%, P<0.002). Excess LDLIII and RLP are present in nephrotic-range proteinuria and add to the spectrum of cardiovascular risk factors present in proteinuric patients. Increases in LDLIII and RLP are closely related to plasma triglyceride. The association between excess RLP and LDLIII suggests that RLP contribute to the increased atherogenicity attributed to the atherogenic lipoprotein phenotype.     

The small, dense LDL phenotype and the risk of coronary heart disease: epidemiology, patho-physiology and therapeutic aspects.

More than decade ago, several cross-sectional studies have reported differences in LDL particle size, density and composition between coronary heart disease (CHD) patients and healthy controls. Three recent prospective, nested case-control studies have since confirmed that the presence of small, dense LDL particles was associated with more than a three-fold increase in the risk of CHD. The small, dense LDL phenotype rarely occurs as an isolated disorder. It is most frequently accompanied by hypertriglyceridemia, reduced HDL cholesterol levels, abdominal obesity, insulin resistance and by a series of other metabolic alterations predictive of an impaired endothelial function and increased susceptibility to thrombosis. Whether or not the small, dense LDL phenotype should be considered an independent CHD risk factor remains to be clearly established. The cluster of metabolic abnormalities associated with small, dense LDL particles has been referred to as the insulin resistance-dyslipidemic phenotype of abdominal obesity. Results from the Québec Cardiovascular Study have indicated that individuals displaying three of the numerous features of insulin resistance (elevated plasma insulin and apolipoprotein B concentrations and small, dense LDL particles) showed a remarkable increase in CHD risk. Our data suggest that the increased risk of CHD associated with having small, dense LDL particles may be modulated to a significant extent by the presence/absence of insulin resistance, abdominal obesity and increased LDL particle concentration. We suggest that the complex interactions among the metabolic alterations of the insulin resistance syndrome should be considered when evaluating the risk of CHD associated with the small, dense LDL phenotype. From a therapeutic standpoint, the treatment of this condition should not only aim at reducing plasma triglyceride levels, but also at improving all features of the insulin resistance syndrome, for which body weight loss and mobilization of abdominal fat appear as key elements. Finally, interventions leading to reduction in fasting triglyceride levels will increase LDL particle size and contribute to reduce CHD risk, particularly if plasma apolipoprotein B concentration (as a surrogate of the number of atherogenic particles) is also reduced.     

Flaxseed dietary fibers suppress postprandial lipemia and appetite sensation in young men

Background and aimDietary fibers (DF) are linked to a reduced risk of life-style diseases, which relate to their physiological effects in the gastrointestinal tract. The aim was to examine whether flaxseed DF-enriched meals suppress postprandial lipemia and reduce appetite.Methods and resultsFour different iso-caloric meals were tested in 18 young men in a double-blind randomized crossover design. Test meals were served after an overnight fast. DF content and source were: control (C): 1.4 g/MJ; whole flaxseed (WF): 2.4 g/MJ from whole flaxseeds; low-mucilage dose (LM): 2.4 g/MJ from flaxseed DF; high-mucilage dose (HM): 3.4 g/MJ from flaxseed DF. During the 7 h test day, subjective appetite sensation was assessed using visual analogue scales and appetite-regulating hormones, and lipemia and glycemia were measured, after which ad libitum energy intake was recorded. There was a significant time × meal effect on triacylglycerols (TG) (p = 0.02) and an 18% smaller area under the curve (AUC) for TG after meal HM compared to meal C was observed (p < 0.01). AUC for insulin was smaller after both LM and HM meals compared to C and WF meals. Higher mean ratings of satiety (p < 0.01) and fullness (p = 0.03) was seen following the HM meal compared to meal C. AUC for ghrelin, CCK and GLP-1 and ad libitum energy intake did not differ between meals, but ghrelin response exhibited a different response pattern after the mucilage-containing meals.ConclusionThese findings suggest that flaxseed DF may suppress postprandial lipemia and appetite although subsequent energy intake was not affected.     

The impact of postprandial lipemia in accelerating atherothrombosis

Several clinical studies have shown that the magnitude and duration of postprandial lipemia is positively related to the pathogenesis and progression of coronary heart disease. Postprandial lipid metabolism refers to the series of metabolic events that occur following the ingestion of a meal containing fat. Dietary fat is principally composed of triacylglycerol, postprandial lipaemia therefore being characterized by an increase in plasma triacylglycerol concentration. This review will describe the nature of the postprandial response and show the direct and indirect pro-atherogenic effects of triacylglycerol-rich lipoprotein metabolism. An elevated postprandial lipemic response precipitates a number of adverse metabolic events, including the production of atherogenic chylomicron remnants, the formation of the highly atherogenic small, dense low-density lipoprotein particles, and a reduction in the concentration of the cardioprotective high-density lipoprotein fraction. Postprandial lipemia also interacts with the process of thrombosis, in that an elevated postprandial triacylglycerol-rich lipoprotein concentration has the ability to activate the coagulation factor VII and plasminogen activator inhibitor. In the light of the potential impact of an elevated postprandial lipemia on atherothrombosis, the genetic determinants of the magnitude of the postprandial response will be identified. Finally, the nutritional factors that modulate the postprandial response will also be discussed.     

Pronounced postprandial lipemia impairs endothelium-dependent dilation of the brachial artery in men.

OBJECTIVE: Pronounced postprandial lipemia has been established as a risk factor for cardiovascular disease, but reports regarding its effect on endothelial function have been controversial. In the present study the influence of a standardized fatty meal with its ensuing postprandial lipemia of highly varying magnitude on endothelium-dependent dilation (EDD) was investigated. METHODS: In 17 healthy, normolipidemic men EDD of the brachial artery was quantified in two series of three measurements each. In both series initial measurements were performed at 08:00 h after an overnight fast followed by measurements at 12:00 and 16:00 h, in the first series with continued fasting and in the second following the ingestion of a standardized fatty test meal 4 and 8 h postprandially. RESULTS: Measurements of EDD in the fasting state revealed the recently appreciated diurnal variation with higher values in noon and afternoon hours compared with morning values (2.5+/-1.6% at 08:00, 7.5+/-2.7% at 12:00, and 7.0+/-2.1% at 16:00 h, P<0.001 by analysis of variance). Postprandial EDD values measured at 12:00 h were, at the average, lower than fasting EDD values measured at 12:00 h and correlated inversely with the magnitude of postprandial triglyceridemia (r=-0.81, P<0.001). In multivariate analysis, higher postprandial lipemia was associated with impaired postprandial EDD (P<0.001) independent of fasting triglycerides, low density lipoprotein (LDL) and high density lipoprotein (HDL) cholesterol, insulin, age and body mass index. CONCLUSION: We conclude that pronounced postprandial lipemia is associated with transient impairment of endothelial function. Our findings support the notion that impaired triglyceride metabolic capacity plays an important role in atherogenesis.     

Postprandial hyperlipidemia, small and dense LDL, HDL sub-fractions]

The association of postprandial hyperlipidemia, small and dense LDL particles and low HDL cholesterol levels is a major cardiovascular risk factor, highly prevalent in insulin resistant and diabetic patients. Several recent epidemiological studies have demonstrated that an abnormal increase in the postprandial triglyceride levels is an independent cardiovascular risk factor, independent from fasting triglyceride levels. A decreased clearance of postprandial triglycerides is related to an abnormal intravascular lipoprotein metabolism, most of the time secondary to an insulin resistant state and genetic factors. This abnormal lipoprotein metabolism also induces a redistribution of LDL particles towards small and dense particles and a decrease in the HDL cholesterol levels. Small, dense LDL are associated with a 3 fold increase in the risk of ischemic heart disease, but does not remain a significant risk factor after adjustment for triglyceride levels. Decreased HDL cholesterol and apolipoprotein A-I levels are strong cardiovascular risk factors, which does not seem to be better assessed with the assay of various HDL sub-fractions (HDL(2) et HDL(3), LpA-I et LpA-I: A-II.).     

Small dense LDL phenotype is associated with postprandial increases of large VLDL and remnant-like particles in patients with acute myocardial infarction

BACKGROUND: The small dense low-density lipoprotein (LDL) phenotype (pattern B), high concentrations of remnant-like particles (RLPs), and postprandial lipemia are newly recognized risk factors for coronary heart disease (CHD). However, the associations of these lipoprotein abnormalities remain unclear. The aim of this study was to investigate the relationships among LDL phenotype, very-low-density lipoprotein (VLDL) subclasses, and postprandial lipoprotein metabolism in CHD patients. METHOD: We performed an oral fat tolerance test in 32 patients with acute myocardial infarction and compared the following parameters between patients characterized by either large buoyant LDL (pattern A) versus pattern B: lipids and apolipoproteins (apo) in the plasma and Svedberg flotation rates (Sf) >400 (chylomicron), Sf 60-400 (large VLDL), and Sf 20-60 (small VLDL) fractions. RESULT: Fasting levels of triglyceride, RLP-cholesterol and RLP-triglyceride were slightly higher in the pattern B patients. Postprandial increases of RLP-cholesterol and the cholesterol and triglyceride of large VLDL fractions were significantly greater in the pattern B patients. The areas under the curves of cholesterol, triglyceride, and apo-B in large VLDL fractions were significantly higher in pattern B, while those in small VLDL were not. RLP-cholesterol and RLP-triglyceride in fasting and fed states correlated very highly with the corresponding cholesterol and triglyceride concentrations in large VLDL fractions. CONCLUSION: These results suggest that postprandial increase of large VLDL fractions and RLPs contribute to the formation of small dense LDL in CHD patients.     

The role of small, dense low density lipoprotein (LDL): a new look

Plasma low density lipoprotein (LDL) plays a central role in atherogenesis, and elevated levels of LDL are associated with an increased risk of coronary heart disease (CHD). Studies have now revealed that LDL is structurally heterogeneous, based on its size and density. Patients with combined hyperlipidemia exhibit a lipid profile - the so-called atherogenic lipoprotein phenotype - that is associated with elevated triglyceride levels, low levels of high density lipoprotein and a preponderance of atherogenic, small, dense LDL particles. Such individuals are at an increased risk of CHD events, regardless of their total LDL circulating mass. Evidence suggests that when plasma triglycerides exceed a critical threshold of approximately 133 mg/dl (1.5 mmol/l), this favours the formation of small, dense LDL from larger, less dense species. Lipid-lowering agents that are capable of lowering triglyceride levels below this threshold value will cause a shift to a less dense and, therefore, less atherogenic LDL profile. This effect has been demonstrated for the HMG-CoA reductase inhibitor atorvastatin which, in addition to its ability to markedly decrease the total LDL circulating mass, can also shift the LDL profile towards less dense, larger species. This suggests that atorvastatin may also affect the atherogenic lipoprotein phenotype found in patients with combined hyperlipidemia.     

Fenofibrate effectively reduces remnants, and small dense LDL, and increases HDL particle number in hypertriglyceridemic men - a nuclear magnetic resonance study

Hypertriglyceridemia is often associated with small dense low density lipoprotein (LDL), elevated remnants, and decreased high density lipoprotein (HDL)-cholesterol (C), which comprise the dyslipidemic triad. The objective of this study was to investigate the effect of fenofibrate on the lipoprotein subfraction profile and inflammation markers in hypertriglyceridemic men. Twenty hypertriglyceridemic men were administered fenofibrate, 200 mg daily, for 8 weeks. Lipoprotein subclasses were measured by nuclear magnetic resonance (NMR) spectroscopy. Inflammation markers including C-reactive protein (CRP), interleukin-6 (IL-6), and monocyte chemotactic protein-1 (MCP-1) were also determined. Fenofibrate lowered triglyceride (TG) by 58% and increased HDL-C by 18%. NMR analysis revealed that very low density lipoprotein (VLDL), particularly large VLDL, intermediate density lipoprotein (IDL), and small LDL, were significantly decreased, and LDL distribution shifted towards the larger particles. HDL distribution was altered; there was an increase in small HDL and a decrease in large HDL, resulting in a significant decrease in HDL particle size, from 9.1 to 8.9 nm, as well as a 27% increase in HDL particle number. Among inflammation markers, CRP was significantly decreased by 42%. In conclusion, fenofibrate effectively improves atherogenic dyslipidemia by reducing remnants and small LDL, as well as by increasing HDL particles. These effects, together with the favorable effect on inflammation, might provide a clinical benefit in hypertriglyceridemic subjects.     

Effect of weight loss on postprandial lipemia and low-density lipoprotein receptor binding in overweight men

Obestity is associated with a range of metabolic abnormalities including fasting and postprandial dyslipidemia, both of which may contribute to increased atherosclerotic risk. Male obese subjects have a decreased level of low-density lipoprotein (LDL) receptor binding in mononuclear cells, the level of which reflects binding in the liver, compared with lean controls. In this study, we investigated whether the implementation of a weight loss regimen in viscerally obese subjects improves LDL receptor binding level. We examined apolipoprotein B(48) (apo B(48)) and retinyl palmitate (RP) metabolism following an oral fat challenge to determine whether weight loss improves postprandial dyslipidemia in viscerally obese subjects. Male obese, mildly dyslipidemic, and insulin-resistant subjects were randomly assigned to either a weight loss (n = 12) or control weight maintenance (n = 10) group. In response to weight loss of 10 kg, insulin sensitivity improved as evidenced by decreased fasting insulin and homeostatic model assessment (HOMA) score. In addition, LDL receptor binding in mononuclear cells increased significantly by 27.5% and LDL-cholesterol was significantly reduced. However, despite the increased LDL receptor levels, fasting apo B(48) levels did not fall. Postprandially, the area under the curve (AUC) for RP was significantly reduced after weight loss, but the incremental and total AUCs for apo B(48) were not altered. Apo B(48) is an unequivocal marker of chylomicron particle number; hence, the reduction in RP metabolism achieved with weight reduction may reflect decreased lipid incorporation into nascent chylomicrons or improved hydrolysis of triglyceride-rich chylomicrons resulting from a decreased competition with hepatic lipoproteins for lipoprotein lipase. Our findings suggest that the improvement in LDL receptor binding following weight reduction of 10 kg in insulin-resistant male obese subjects is insufficient to reduce the elevated chylomicron remnant levels.     

Recent findings in the study of postprandial lipemia

The study of postprandial metabolism is in the early stages compared with other areas of atherosclerosis research. Recent advances in postprandial research have included improvements in methodology and the investigation of factors that modulate the lipemic response to a meal. Enough studies have now been performed that normal ranges have been identified for blood triacylglycerol (TAG) concentrations that occur after a healthy patient consumes a standardized-mixed meal or a high-fat shake designed to elicit lipemia. Typical postprandial concentrations of other metabolites, such as apolipoproteins B48 and B100 or gastrointestinal hormones (eg, cholecystokinin), have not been studied sufficiently to be able to qualify what represents a standard postprandial response. The method of data analysis is also a key point to consider. Data from children are now becoming available, and the specific effects of ethnicity have just begun to be explored. New areas of study include the effects of different fatty acids (monosaturates or polyunsaturates), the sources of chylomicron lipids (dietary TAG and cholesterol versus that newly synthesized in the body), and the effects of alcoholic beverages consumed with the meal. Variables that can also affect the results of a meal test are under investigation. These include the type of food that is consumed the day before the meal test, the time of day the test is performed, and the palatability of the food. Given solid evidence that delayed postprandial lipemia is an independent risk factor for coronary heart disease, future scientific investigation in the area of post-prandial metabolism is likely to yield discoveries that will significantly contribute to advancements in disease treatment.     

Triglyceride, small, dense low-density lipoprotein, and the atherogenic lipoprotein phenotype

This review provides an overview of the recent data evaluating triglyceride and low-density lipoprotein (LDL) size, two highly interrelated, genetically influenced, risk factors for cardiovascular disease (CVD). An examination of new epidemiologic studies continues to demonstrate that plasma triglyceride levels predict CVD. The first prospective study of the familial forms of hypertriglyceridemia has shown that relatives in familial-combined hyperlipidemia families are at increased risk for CVD mortality and that triglyceride levels predicted 20-year, CVD mortality among relatives in familial hypertriglyceridemia families. A meta-analysis of three, large-scale, prospective studies in men, and the first study to examine the correlation of LDL particle size distribution and vascular changes measured by B-mode ultrasound, add to growing evidence that small, dense LDL is atherogenic. Quantitative genetic analysis has recently shown substantial pleiotropic (common) genetic effects on triglyceride and LDL size. At least part of this may be explained by variation at the cholesterol ester transfer protein locus on chromosome 16, possibly through its role in reverse cholesterol transport. Taken together, these data provide new insights into the importance of triglyceride and LDL particle size for understanding genetic susceptibility to cardiovascular disease and its prevention.