Oxygen content and oxidation in frying oil.

The relation between oxygen content and oxidation was investigated in frying oils. When canola oil, a canola-soybean oil blend or a trioctanoylglycerol (glycerol tricaprate) sample were heated with stirring, their dissolved oxygen content decreased abruptly at about 120°C and the carbonyl values (CV) increased gradually with heating and reached values of 6-7 at 180°C in the blended and canola oils, while the CV of trioctanoylglycerol was zero up to 150°C. Probably this abrupt decrease in oxygen content above 120°C can be attributed to the solubility of oxygen in oil rather than because of oxidative reactions. The oxygen content of oil that has been stripped of part of its oxygen, increased at temperatures between 25 and 120°C. In oils that have lost their oxygen by being heated to 180°C, standing at room temperature will slowly restore their oxygen content as the oil cools. Intermittent simple heating of oil promoted oxygen absorbance during cooling periods and standing times, and it resulted in an elevated content of polar compounds (PC). Domestic deep-frying conditions also favor the presence of oxygen in oil below 120°C and during the oil's long standing at room temperature. The oxygen content in oil was low during deep-frying, but oxidation was active at the oil/air interface of bubbles generated by foods being fried. Repeated use of oil at temperatures between 25-180°C resulted in oil with low oxygen values.

Oxidation of frying oils during intermittent usage.

We reported previously that in oils used for frying by commercial establishments, a high correlation was observed among their Gardner colors, polar compound contents (PC), carbonyl values (CV) and acid values (AV). However, this was not true for frying oils used in hospitals. In the present study, oils that had been used for deep-frying in hospital kitchens were collected and assayed for PC, CV, AV, and Gardner color value to determine the reason for the differences from oil used in commercial establishments. Hospitals were selected so that variation in the number of inpatients, frying oil fatty acid composition, and frying frequency was obtained. As previously observed, we did not find good correlations between the color of the frying oil and the PC, CV or AV, respectively. The extent of oxidation in batches of oil repeatedly used for deep-frying was in the following order: soybean oil > blended oil > canola oil. After use in deep-frying, where the oxygen content goes effectively to zero, allowing the oil to stand at room temperature resulted in the quick and steady absorption of oxygen until it returned to its initial content. In addition to the effect of thermal treatment of oil, standing time between usages is a significantt cause of oxidation.