Icosapent ethyl–induced lipoprotein remodeling and its impact on cardiovascular disease risk markers in normolipidemic individuals
Lauri Äikäs, Petri T. Kovanen, Martina B. Lorey, Reijo Laaksonen, Minna Holopainen, Hanna Ruhanen, Reijo Käkelä, Matti Jauhiainen, Martin Hermansson, Katariina Öörni
Lauri Äikäs, Petri T. Kovanen, Martina B. Lorey, Reijo Laaksonen, Minna Holopainen, Hanna Ruhanen, Reijo Käkelä, Matti Jauhiainen, Martin Hermansson, Katariina Öörni
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Clinical Research and Public Health Clinical Research Metabolism Vascular biology

Icosapent ethyl–induced lipoprotein remodeling and its impact on cardiovascular disease risk markers in normolipidemic individuals

Abstract

BACKGROUND Icosapent ethyl (IPE), an ethyl ester of eicosapentaenoic acid (EPA), reduces cardiovascular disease (CVD), but the mechanism remains elusive. We examined the effect of IPE supplementation on lipoprotein subclasses, lipidomes, and pro-atherogenic properties.METHODS Using 3 independent metabolomic platforms, we examined the effect of high-dose IPE supplementation for 28 days on fatty acid profiles, lipoprotein subclasses, lipidomes, and pro-atherogenic properties in normolipidemic volunteers (n = 38).RESULTS IPE supplementation increased lipoprotein EPA on average 4-fold within 7 days, returning to baseline after a 7-day washout. Notably, the incorporation displayed marked interindividual variance, negatively correlating with baseline levels. We identified persistent participant-specific lipoprotein fingerprints despite uniform IPE-induced lipidome remodeling across all lipoprotein classes. This remodeling resulted in reductions in saturated, monounsaturated, and n-6 polyunsaturated fatty acids, resulting in reduced clinical risk markers, including triglyceride, remnant cholesterol, and apolipoprotein B (apoB) levels and 10-year CVD risk score. Of the pro-atherogenic properties tested, IPE significantly reduced apoB lipoprotein binding to proteoglycans, which correlated with lower apoB particle concentration, cholesterol content, and specific lipid species in LDL, including phosphatidylcholine 38:3 previously associated with CVD.CONCLUSION These findings highlight IPE’s rapid, uniform remodeling of lipoproteins and reduced proteoglycan binding, likely contributing to previously observed CVD risk reduction. Persistent interindividual lipidome signatures underscore the potential for personalized therapeutic approaches in atherosclerotic CVD treatment.TRIAL REGISTRATION NCT04152291.FUNDING Jenny and Antti Wihuri Foundation, Research Council of Finland, Sigrid Jusélius Foundation, Finnish Foundation for Cardiovascular Research, Emil Aaltonen Foundation, Ida Montin Foundation, Novo Nordisk Foundation, Finnish Cultural Foundation, and Jane and Aatos Erkko Foundation.

Authors

Lauri Äikäs, Petri T. Kovanen, Martina B. Lorey, Reijo Laaksonen, Minna Holopainen, Hanna Ruhanen, Reijo Käkelä, Matti Jauhiainen, Martin Hermansson, Katariina Öörni

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Figure 5

Impact of IPE supplementation on lipoprotein lipidome composition and dynamics.

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Impact of IPE supplementation on lipoprotein lipidome composition and dy...
Lipoprotein fractions were isolated by ultracentrifugation, and their lipids were analyzed by LC/MS. (A) Pie charts show lipid class compositions of isolated lipoproteins at baseline (day 0). (B) Venn diagram displays significantly changing lipid species in each fraction after 28 days. (C) Time series clustering of significantly changing HDL, LDL, and VLDL lipids; orange lines represent individual species and brown lines, cluster medians; and cluster member counts (CM) are shown. Only species with cluster membership of >0.5 are included. Panels are named based on typical cluster members, which are listed in the panels. Lipid annotation: class, acyl carbon range, and double bond range. (D) Change in LDL lipid unsaturation from baseline to day 28, grouped by double bond count. Box plots show mean log2 fold-changes with medians, 1.5 interquartile ranges, and individual data points. N = 29 for HDL, 37 for LDL, and 38 for VLDL. Venn diagram implemented with DeepVenn, © Tim Hulsen, https://www.deepvenn.com