Scope The lipidomic analysis of high-density lipoprotein (HDL) could be useful to identify new biomarkers of HDL function.Methods and results A randomized, controlled, double-blind, crossover trial... Show moreScope The lipidomic analysis of high-density lipoprotein (HDL) could be useful to identify new biomarkers of HDL function.Methods and results A randomized, controlled, double-blind, crossover trial (33 hypercholesterolaemic subjects) is performed with a control virgin olive oil (VOO), VOO enriched with its own phenolic compounds (FVOO), or VOO enriched with additional phenolic compounds from thyme (FVOOT) for 3 weeks. HDL lipidomic analyses are performed using the Lipidyzer platform. VOO and FVOO intake increase monounsaturated-fatty acids (FAs) and decrease saturated and polyunsaturated FAs in triacylglyceride (TAG) species, among others species. In contrast, FVOOT intake does not induce these FAs changes. The decrease in TAG52:3(FA16:0) after VOO intake and the decrease in TAG52:5(FA18:2) after FVOO intake are inversely associated with changes in HDL resistance to oxidation. After FVOO intake, the decrease in TAG54:6(FA18:2) in HDL is inversely associated with changes in HDL cholesterol efflux capacity.Conclusion VOO and FVOO consumption has an impact on the HDL lipidome, in particular TAG species. Although TAGs are minor components of HDL mass, the observed changes in TAG modulated HDL functionality towards a cardioprotective mode. The assessment of the HDL lipidome is a valuable approach to identify and characterize new biomarkers of HDL function. Show less
A great majority of the morbidity and mortality worldwide can still be attributed to cardiovascular diseases, such as ischemic (coronary) heart disease, angina pectoris, and myocardial and cerebral... Show moreA great majority of the morbidity and mortality worldwide can still be attributed to cardiovascular diseases, such as ischemic (coronary) heart disease, angina pectoris, and myocardial and cerebral infarction. Atherosclerosis, narrowing of the arteries because of arterial cholesterol deposition in macrophage foam cells, is the driving force behind the cardiovascular disease pathology. Water-soluble protein/lipid complexes called lipoproteins mediate the transport of cholesterol and other lipoid substances through the blood compartment. Relatively high levels of cholesterol associated with apolipoprotein B–containing low-density lipoprotein (LDL) particles predispose human subjects to the development of atherosclerosis and, thereby, increase the risk for cardiovascular disease.1,2 Apolipoprotein B–containing lipoproteins are, therefore, generally regarded as being proatherogenic factors. Cholesterol ester–rich high-density lipoprotein (HDL) particles use apolipoprotein A1 (apoA1) as their primary protein component. In sharp contrast to LDL, HDL is considered a potent anti-atherogenic agent. This notion is based on the fact that, in the general population, a strong inverse correlation exists between plasma levels of HDL cholesterol and the risk of cardiovascular disease.1 Of note, this inverse association seems to be independent of the level of cholesterol associated with proatherogenic LDL particles. As such, increasing plasma levels of HDL cholesterol has long been regarded a promising alternative therapy to supplement classical statin–based LDL cholesterol–lowering strategies that are able to reduce cardiovascular disease by only ≈30%.3 However, over the last decade, the enthusiasm for HDL as an interesting therapeutic target has been challenged by the HDL hypothesis critics because genetic association studies have excluded HDL cholesterol levels as determinants for cardiovascular disease risk.2,4 Furthermore, several therapeutic HDL-targeting approaches have proven insufficient to secure benefit for cardiovascular disease patients. Show less
