Time Course Change in Skeletal Muscle and Blood Phospholipid Composition with Omega-3 Fatty Acid Supplementation

Previous work has shown that supplementing with omega-3 fatty acids leads to increased omega-3 fatty acid composition of skeletal muscle phospholipids. This increase in skeletal muscle omega-3 fatty acid phospholipid composition following omega-3 fatty acid intake is linked to potentiated rates of skeletal muscle protein synthesis in response to amino acid and insulin infusion in older and younger women and men. Supplementation with omega-3 fatty acids is also known to enhance skeletal muscle strength and size in older adults. The exact biological mechanisms responsible for the anabolic influence of omega-3 fatty acid are unknown. However, there is emerging data that acid (EPA) and docosahexaenoic acid (DHA) play an active role. Indeed, there is now a growing body of evidence in cells, preclinical models, and humans that these key omega-3 fatty acids are primarily responsible for the observed anabolic impact of omega-3 fatty acids supplement intake towards skeletal muscle.

Whilst there is a growing body of literature supporting the anabolic potential of EPA and DHA in skeletal muscle, few studies have examined how biological sex influences EPA and DHA incorporation into skeletal muscle. Indeed, it has been purported that women EPA to DHA more efficiently in blood erythrocytes compared to men. To the investigators knowledge, no study examined how biological sex impacts changes in skeletal muscle phospholipid profiles in response to EPA and DHA intake. Moreover, no study has established a time course washout of EPA and DHA from skeletal muscle phospholipids in response to the cessation of EPA and DHA intake. The lack of data regarding EPA and DHA washout from skeletal muscle in response to EPA and DHA intake limits the ability to execute within subject cross over trials, which is important given that within-subject cross over trials possess more statistical power than parallel arm trials. Thus, establishing a washout of EPA and DHA from skeletal muscle phospholipids in response to EPA and DHA intake would provide important information for the design of future trials in this field.