Abstract
Cold plasma is formed by the nonthermal ionization of gas into free electrons, ions, reactive atomic and molecular species, and ultraviolet (UV) radiation. This cold plasma can be used to alter the surface of solid and liquid foods, and it offers multiple advantages over traditional thermal treatments, such as no thermal damage and increased output variation (due to the various input parameters gas, power, plasma type, etc.). Cold plasma appears to have limited impact on the sensory and color properties, at lower power and treatment times, but there has been a statistically significant reduction in pH for most of the cold plasma treatments reviewed (p < 0.05). Carbohydrates (cross linking and glycosylation), lipids (oxidation), and proteins (secondary structure) are more significantly impacted due to cold plasma at higher intensities and longer treatment times. Although cold plasma treatments and food matrices can vary considerably, this review has identified the literary evidence of some of the influences and impacts of the vast array of cold plasma treatment parameters on the biomolecular and organoleptic properties of these foods. Due to the rapidly evolving nature of the field, we have also identified that authors prioritize the presentation of different information when publishing from different research areas. Therefore, we have proposed a number of key physical and chemical cold plasma parameters that should be considered for inclusion in all future publications in the field.
Highlights
There is a pressing need to develop nonthermal processing technologies that can provide the same antimicrobial effects as thermal processing technologies without the same loss of quality
This review has shown that Cold plasma (CP) can be used to increase quality-based shelf life, gel strength, and that using lower power and shorter periods of exposure of the CP is key in minimizing negative organoleptic impacts
CP does not significantly impact color, and some have found that it reduces L* and increases b*, these were heavily dependent on parameters such as gas flow
Summary
There is a pressing need to develop nonthermal processing technologies that can provide the same antimicrobial effects as thermal processing technologies without the same loss of quality. Depending on the source of energy applied to the gas, these ionized atoms, molecules, and free electrons will exist in a thermodynamic equilibrium (thermal plasma), a quasi-equilibrium (low temperature plasma in intraspecies thermodynamic equilibrium: ∼100–150◦C), or a nonequilibrium state (nonthermal or cold plasma
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