Impact of Nonthermal Plasma on Lipid Oxidation from the Perspective of Plasma Treatment Parameters and Plasma Species: Identification of Key Reactive Species
Danyang Liu, Charlie Van Paepeghem, Joke Sierens, Mehrnoush Narimisa, Anton Nikiforov, Nathalie De Geyter, Kristof Demeestere, Bruno De Meulenaer
Abstract
Nonthermal plasma is a mild processing technology for food preservation. Its impact on lipid oxidation was investigated in this study. Stripped methylesters were considered as a basic lipid model system and were treated by a multihollow surface dielectric barrier discharge. In dry air plasma, O 3, · NO 2, · NO 3, and 1 O 2 were identified as the main reactive species reaching the sample surface. Treatment time was the most prominent parameter affecting lipid oxidation, followed by the (specific) power input and the plasma-sample distance. In humid air plasma, less O 3 was detected, but ONOOH and O 2 NOOH were generated and presumed to play a role in lipid oxidation. Ozone mainly resulted in the formation of carbonyl substances via the trioxolane pathway, while reactive nitrogen species (i.e., · NO 2, · NO 3, ONOOH, and O 2 NOOH) led to the formation of hydroperoxides. The impact of short-living radicals (e.g., · O, · N, · OH, and · OOH) was restricted in general, since they dissipated too fast to reach the sample. · NO, HNO 3, H 2 O 2, and UV radiation did not induce lipid oxidation. All the reactive species identified in this study were associated with the presence of O 2 in the input gas.