Amounts of malondialdehyde do not accurately represent the real oxidative level of all vegetable oils: a kinetic study of malondialdehyde formation

Euro J Lipid Sci & Tech

2019

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The formation of three toxic reactive aldehydes, malondialdehyde (MDA), 4‐hydroxy‐hexenal (HHE), and 4‐hydroxy‐2‐nonenal (HNE), is investigated in five commonly consumed vegetable oils using a method based on the Schaal oven test. HHE is only detected in linseed oil (LO) and rapeseed oil (RO), while MDA and HNE are found to be present in all tested oils. The formation potential of MDA, HHE, and HNE in the tested oils is closely related to the initial polyunsaturated fatty acid (PUFA) content in the oil. Correlation analyses reveal low correlation coefficients for MDA, determining its unsuitability to evaluate the oxidation of oils with low PUFA content, such as palm oil and camellia oil; in contrast, HHE and HNE show sufficient correlations with other oxidation indices in all tested oils. Furthermore, regression analysis indicates that HHE content can predict the oxidation of ω‐3 type oil, while HNE content can estimate oxidative deterioration of ω‐6 type oils. Particularly, HNE content can also evaluate the oxidation of ω‐9 type oils such as PO and CLO with relatively low PUFA level for the high correlations (>0.991, P < 0.01) toward the total oxidation value (TOTOX). Practical Applications: Edible oil consumption continues to increase worldwide. Therefore, it is very important to understand the conditions under which potentially health‐damaging compounds are formed in these oils and to develop methods to inhibit their formation or eliminate them from the oils. This study investigates the formation of three toxically reactive aldehydes, namely MDA, HHE, and HNE, through lipid oxidation, specifically PUFA peroxidation. The application of these aldehydes as oxidation indicators for different vegetable oils is also explored. This work could prove beneficial for the quality control of vegetable oils in the edible oil industry. The formation of three toxic aldehydes, MDA, HHE, and HNE in different types of vegetable oils is investigated. Considerable amounts of MDA, HHE, and HNE is found in all the tested oils. The results show the formation of these three aldehydes is competitive. Besides, MDA content is not appropriate to evaluate the oxidation of oils with low PUFA content, such as PO and CLO; while HHE and HNE can characteristically depict the oxidation of ω‐3 and ω‐6 type oil.

Section: Resultssupporting

confidence: 89%

Malondialdehyde, 4‐Hydroxy‐2‐Hexenal, and 4‐Hydroxy‐2‐Nonenal in Vegetable Oils: Formation Kinetics and Application as Oxidation Indicators

Euro J Lipid Sci & Tech

2019

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“…The levels of MDA also varied in different oils; the highest was observed in the LO, and the lowest was in the CO. This is probably because linolenic acid (ω‐3) was the strong precursor of MDA in the LO in which it was found to be most abundant, but it was a relatively weak one in the CO in which it was also found (Ayala et al , ; Ma et al , ). The MDA levels in the CO used for the FF frying group were significantly ( P < 0.05) higher than those in the CO used for the FCBM frying group (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Guillén & Uriarte () observed high levels of HHE and HNE in sunflower and linseed oils after prolonged heating at frying temperatures. Ma et al () investigated the formation kinetics of MDA during thermal processing at 100–180 °C. LaFond et al () studied the formation of HNE during frying but not its levels in potato sticks.…”

Section: Introductionmentioning

confidence: 99%

Formation of malondialdehyde, 4‐hydroxy‐hexenal and 4‐hydroxy‐nonenal during deep‐frying of potato sticks and chicken breast meat in vegetable oils

Cheng

et al. 2019

Int J of Food Sci Tech

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Summary The present work investigated the formation of three toxic aldehydes, malondialdehyde (MDA), 4‐hydroxy‐hexenal (HHE) and 4‐hydroxy‐nonenal (HNE), during deep‐frying of different foods in corn oil (CO), rapeseed oil (RO) and linseed oil (LO). Besides, their contents in French fries (FF) and fried chicken breast meat (FCBM) were also explored. Results showed that the MDA/HHE/HNE levels in frying groups were all lower than those in control, indicating the incorporation into the fried foods. Apart from the different levels, MDA/HHE/HNE in FF and FCBM possessed similar variation tendencies, revealing the matrix‐mediated distribution. The combined exposure assessment based on the threshold of toxicological concern (TTC) levels was conducted, and risks of exceeding the limitation values (1.5 μg kg bw−1 day−1) for HNE in CO and HHE in LO were exhibited. The consumption of both FF and FCBM should be regulated, considering the levels of MDA, HHE and HNE these fried foods may contain.

“…It had been reported that the tocopherols in vegetable oils might influence the rate constant (Ma et al ., ), but in our experiment the tocopherols were stripped prior to the heating experiment. Therefore, differences among rate constants were due to differences between oil types.…”

Section: Resultsmentioning

confidence: 99%

“…The tocopherol contents of vegetable oils vary, which can affect kinetic parameters (Farhoosh et al, 2008). Our group found that tocopherol affected the rate constant of MDA formation in different oils (Ma et al, 2019). To eliminate the influence of tocopherol and obtain kinetic and thermodynamic data for HHE and HNE formation influenced only by the type of vegetable oil used, the tocopherols were stripped from the oils prior to heating on an alumina column based on a previous report (Fuster et al, 1998).…”

Section: Purification Of Vegetable Oilsmentioning

confidence: 99%

Understanding the difference of 4‐hydroxyhexenal and 4‐hydroxynonenal formation in various vegetable oils during thermal processes by kinetic and thermodynamic study

Zhang

et al. 2019

Int J of Food Sci Tech

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Summary The formation of two toxic aldehydes, 4‐hydroxyhexenal (HHE) and 4‐hydroxynonenal (HNE) were monitored in five vegetable oils during thermal processing (100–200 °C) with the results modelled. HHE was only determined in rapeseed and linseed oil, while HNE was determined in all tested oils and the contents varied significantly depending on the oil type. For HHE/HNE‐detected oils, the evolution during heating was well described by the pseudo‐first‐order kinetic model. The equilibrium contents of HHE/HNE increased and the duration until equilibrium decreased as a function of temperature. The calculated reaction rate constants followed the Arrhenius law. The formation rate of HHE/HNE was remarkably oil‐dependent, which was also in accordance with the calculated kinetic and thermodynamic parameters. Accordingly, the above results can contribute to a prediction of HHE/HNE formation in different vegetable oils during thermal processing, especially the temperature/time required during frying, which is generally higher than 100 °C and 6 h., respectively.