A Head-to-Head Comparison of a Free Fatty Acid Formulation of Omega-3 Pentaenoic Acids Versus Icosapent Ethyl in Adults With Hypertriglyceridemia: The ENHANCE-IT Study

Kevin C Maki, Harold E Bays, Christie M Ballantyne, James A Underberg, John J P Kastelein, Judith B Johnson, James J Ferguson, Kevin C Maki, Harold E Bays, Christie M Ballantyne, James A Underberg, John J P Kastelein, Judith B Johnson, James J Ferguson

Abstract

Background MAT9001 is an omega-3 free fatty acid (FFA) formulation containing mainly eicosapentaenoic acid (EPA) and docosapentaenoic acid (DPA). Compared with icosapent ethyl (EPA-ethyl esters [EE]), EPA+DPA-FFA previously showed enhanced triglyceride lowering and higher plasma EPA when both were administered once daily with a very-low fat diet. This trial compared pharmacodynamic responses and plasma omega-3 levels following twice daily dosing, with meals, of EPA+DPA-FFA and EPA-EE in hypertriglyceridemic subjects consuming a Therapeutic Lifestyle Changes diet. Methods and Results This open-label, randomized, 2-way crossover trial, with 28-day treatment periods separated by ≥28-day washout, was conducted at 8 US centers and included 100 subjects with fasting triglycerides 1.70 to 5.64 mmol/L (150-499 mg/dL) (median 2.31 mmol/L [204 mg/dL]; 57% women, average age 60.3 years). The primary end point was least squares geometric mean percent change from baseline plasma triglycerides. In the 94 subjects with analyzable data for both treatment periods, EPA+DPA-FFA and EPA-EE reduced least squares geometric mean triglycerides from baseline: 20.9% and 18.3%, respectively (P=not significant). EPA+DPA-FFA reduced least squares geometric mean high-sensitivity C-reactive protein by 5.8%; EPA-EE increased high-sensitivity C-reactive protein by 8.5% (P=0.034). EPA+DPA-FFA increased least squares geometric mean plasma EPA, DPA, and total omega-3 (EPA+docosahexaenoic acid+DPA) concentrations by 848%, 177%, and 205%, respectively, compared with corresponding changes with EPA-EE of 692%, 140%, and 165% (all P<0.001). EPA+DPA-FFA increased docosahexaenoic acid by 1.7%; EPA-EE decreased docosahexaenoic acid by 3.3% (P=0.011). Lipoprotein cholesterol and apolipoprotein responses did not differ between treatments. Conclusions EPA+DPA-FFA raised plasma EPA, DPA, and total omega-3 significantly more than did EPA-EE. EPA+DPA-FFA also reduced triglycerides and high-sensitivity C-reactive protein without increasing low-density lipoprotein cholesterol. Registration URL: https://www.clinicaltrials.gov; Unique identifier: NCT04177680.

Keywords: docosapentaenoic acid; eicosapentaenoic acid; hypertriglyceridemia; omega‐3 fatty acids; triglycerides.

Figures

Figure 1. Flow diagram of subjects assessed…
Figure 1. Flow diagram of subjects assessed for eligibility, randomized, and included in the populations analyzed for the study.
The intent‐to‐treat population included all subjects who were randomly assigned to a treatment sequence. The safety population included all subjects who were randomly assigned and received at least 1 dose of any study treatment. The pharmacodynamic (PD) population included subjects with PD parameters for both treatment periods. The per protocol population included all subjects in the PD population for whom compliance for both treatment periods was at least 80%, and for whom no clinically important protocol violations or deviations occurred during the trial. DPA indicates docosapentaenoic acid; EE, ethyl esters; EPA, eicosapentaenoic acid; FFA, free fatty acids; and TG, triglycerides. *Both discontinuations because of adverse events during the study were in subjects receiving EPA‐EE.

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