Evaluation of oxygen partial pressure, temperature and stripping of antioxidants for accelerated shelf-life testing of oil blends using 1H NMR

Lipid oxidation compromises the shelf-life of lipid-containing foods, leading to the generation of unpleasant offflavours. Monitoring lipid oxidation under normal shelf-life conditions can be time-consuming (i.e. weeks or months) and therefore accelerated shelf-life conditions are often applied. However, little is known on their impact on the lipid oxidation mechanisms. In this study, different oxygen partial pressures (PO2; 10 and 21%), temperatures (20, 30 and 40 degrees C), and the removal of antioxidants through stripping of the oil were tested to accelerate lipid oxidation. Increasing the incubation temperature of stripped oil blends from 30 to 40 degrees C reduced the onset of lipid oxidation from 4 to 2 weeks, whereas the PO2 had no impact. Surprisingly, at room temperature, an increase in PO2 resulted in a longer onset time (10 weeks under 10% oxygen, 15 weeks under 21% oxygen). We hypothesize that this is due to a shift in (initiation) mechanism. In non-stripped oil, an increase in PO2 from 10 to 21% decreased the onset time from 16 to 10 weeks (40 degrees C). Temperature elevations and stripping led to a shift towards more trans-trans diene hydroperoxides, as compared to the cis-trans conformation. Additionally, oil stripping led to an increase in oxidized PUFAs with three or more double bonds in which the hydroperoxide group is located between the double bond pattern, instead of on the edge of it. Lastly, it was shown that small additions of LC-PUFAs (0, 0.3, 0.6, 1.2 and 2.3%, w/w) accelerate lipid oxidation, even in relatively stable stripped oils. In conclusion, increased PO2 and slightly elevated temperatures hold fair potential for accelerated shelf-life testing of non-stripped oils with a limited impact on the lipid oxidation mechanisms, whereas stripping significantly changes propagation mechanisms.

Automated summary

The study compared the effects of temperature and oxygen partial pressure on lipid oxidation through testing different accelerated conditions. The results showed that temperature elevation and removal of antioxidants significantly affected lipid oxidation, while the impact of oxygen partial pressure was minor.