Abstract
This study investigates the effect of various minor components (MCs) on the oxidation kinetics and molecular self-assembly in stripped canola oil during thermal and photo oxidation processes using experimental and simulation tools. The peroxide value (PV) and fatty acid content were measured to evaluate the formation of oxidation products and the consumption rate of unsaturated fatty acids. In the thermal oxidation experiment, adding MCs slightly increased the oxidation rate, while in the photo oxidation experiment, stearic acid (SA) and glycerol monostearate (GMS) significantly decreased it. GMS demonstrated a pronounced ability to self-assemble and form molecular organizations during photo oxidation, resulting in lower critical micelle concentration (CMC) values of lipid hydroperoxides (LOOHs) and reduced oxidation rates. These GMS self-assemblies seem to scatter light, thus decreasing absorbed energy during photo oxidation, leading to lower oxidation rates. SA exhibited the highest surface activity, effectively lowering the LOOH CMC and facilitating the formation of stable reverse micelles at lower concentrations. Interestingly, the addition of MCs did not influence the tendency of LOOHs to form hydrogen bonds with water, suggesting that the lower CMC resulted from the formation of mutual reverse micelles of MCs and LOOHs. Meso-phase formation was observed at very high PVs, indicating a high concentration of secondary oxidation products, which also possess surface activity. These findings underscore the importance of molecular interactions in oxidation stability, providing insights for improving edible oil preservation.