Oxidation of fats and oils during storage causes their degradation and loss of nutritional value and appearance. Electron spin resonance (ESR) is the only method that can be used to directly observe the radicals. In...Oxidation of fats and oils during storage causes their degradation and loss of nutritional value and appearance. Electron spin resonance (ESR) is the only method that can be used to directly observe the radicals. In this study, the authors used an ESR spin-trapping method to study the oxidation of triacylglycerols (TAG) containing different fatty acids (FAs) commonly found in food. The ESR adduct signals were analyzed to study the effect of double bonds and the chain length of the FAs of TAG on oxidation. Oxidation was conducted by applying UV irradiation to TAG by dissolving it in N-tert-buthyl〈t-phenylnitrone (PBN), which trapped the radicals induced in the TAG as an ESR adduct signal. The detection was clearly successful. There were no differences in the spectra of tristearin (18:0) and tripalmitin (16:0); thus, it can be concluded that the length of the carbon chain of the FAs of TAG does not affect the oxidation reactions. However, the ESR spectra of tristearin (18:0), triolein (18:1) and trilinolein (18:3) were clearly different due to the presence/absence of a new peak corresponding to new induced radicals, leading to the conclusion that double bonds play a major role in the oxidation reactions of fats and oils.展开更多
文摘Oxidation of fats and oils during storage causes their degradation and loss of nutritional value and appearance. Electron spin resonance (ESR) is the only method that can be used to directly observe the radicals. In this study, the authors used an ESR spin-trapping method to study the oxidation of triacylglycerols (TAG) containing different fatty acids (FAs) commonly found in food. The ESR adduct signals were analyzed to study the effect of double bonds and the chain length of the FAs of TAG on oxidation. Oxidation was conducted by applying UV irradiation to TAG by dissolving it in N-tert-buthyl〈t-phenylnitrone (PBN), which trapped the radicals induced in the TAG as an ESR adduct signal. The detection was clearly successful. There were no differences in the spectra of tristearin (18:0) and tripalmitin (16:0); thus, it can be concluded that the length of the carbon chain of the FAs of TAG does not affect the oxidation reactions. However, the ESR spectra of tristearin (18:0), triolein (18:1) and trilinolein (18:3) were clearly different due to the presence/absence of a new peak corresponding to new induced radicals, leading to the conclusion that double bonds play a major role in the oxidation reactions of fats and oils.
