INNOVATIVE COLD PLASMA-ASSISTED EXTRACTION FOR BIOACTIVE COMPOUNDS FROM AGRICULTURAL BYPRODUCTS

Yiwen Bao (8232060)

06 May 2020

<p>Fruits play a necessary role in the human diet, and their cultivation is important to the prosperity of any country worldwide. However, fruit waste generated in large quantities in agricultural value chain is normally used to feed animals or directly disposed to landfill, ending up with low economic value and a heavy environmental burden. Agricultural waste that contains significant amounts of bioactive compounds can be utilized as byproducts and valorized through bioactives recovery. Conventional bioactive compounds extraction includes intensive uses of organic solvents and also has relatively low efficiency. Therefore, an environment-friendly alternative with higher extraction efficiency is needed. Cold plasma can convert gaseous medium to a highly reacting state with low energy cost, generating reactive species that are able to disrupt cell structures as well as modify material surfaces. This study has developed an innovative cold plasma-assisted extraction technology to enhance the recovery of bioactive compounds from fruit processing byproducts. The objectives of this study are to examine the effects of dielectric barrier discharge plasma on fruit pomaces, in terms of (i) surface microstructure and properties, (ii) extraction efficiency of their bioactive compounds, and (iii) bioactives composition and nutritional value of their extracts.</p><p>High voltage atmospheric cold plasmas (HVACP) generated with different working gases (air, argon, helium and nitrogen) were applied on tomato pomace (TP). In addition to creating ruptures on TP epidermal cells, HVACP treatments were found to decrease the water contact angles of tomato peels and accelerate the drying of tomato fruits, indicating the formation of more hydrophilic surfaces. Helium and nitrogen plasmas-treated TP showed increased PC extraction yields by 10%, and all HVACP-treated samples exhibited higher AA and changes in their phenolic compositions.</p><p>Grape pomace (GP) from red wine production was treated by helium-HVACP for different time periods (5, 10 and 15 min). Similar cell structure disruption and surface hydrophilicity enhancement were observed, and the effects became more significant as treatment extended. HVACP treatment also increased the total phenolic content in GP extracts, by 10.9−22.8%, which contained a higher anthocyanin concentration and showed an improved AA (16.7−34.7%). Furthermore, competitive effects of HVACP treatment on PC extractability enhancement and their degradation were observed.</p><p>The results of this study have proved that HVACP-assisted extraction successfully improved the extraction efficiency of bioactive compounds from fruit pomace and enhanced the nutritional quality of their extracts. This novel technology is a promising method for valorizing different agriculture byproducts into functional food ingredients and nutraceuticals with high nutritional values, which thus can bring significant economic benefits to the agricultural, food and nutraceutical industries.</p>

Food Engineering

Food Processing

Food Sciences not elsewhere classified

High Voltage Atmospheric Cold Plasma

Surface Modification

Extraction Enhancement

Bioactive Compounds

INTERACTIONS OF HIGH VOLTAGE ATMOSPHERIC COLD PLASMA WITH MICROORGANISM AND PROTEIN IN FOOD SYSTEMS

Lei Xu (5930420)

12 February 2019

<p>Multiple studies have demonstrated atmospheric cold plasma (ACP) as an effective non-thermal technology for microbial decontamination, surface modification, and functionality alteration in food processing and packaging. ACP constitutes charged particles, such as positive and negative ions, electrons, quanta of electromagnetic radiation, and excited and non-excited molecules, which corresponds to its predominant reactive properties. However, in many of these applications, the interactions between plasma and the components in food matrix are not well-understood. The <b>overall goals</b> of this dissertation were to 1) evaluate the interactions between high voltage atmospheric cold plasma (HVACP) and microbes in liquid and semi-solid food; 2) investigate plasma transfer into semi-solid foods and determine the relationship between microbial inactivation and plasma transfer; 3) explore the interactions between plasma and proteins. </p> <p>The first study explored the microbial (<i>Salmonella</i> <i>enterica</i> serovar Typhimurium, <i>S</i>. <i>enterica</i>) inactivation efficacy of HVACP. The physicochemical interactions between HVACP and biomolecules, including an enzyme (pectin methylesterase, PME), vitamin C and other components in orange juice (OJ) under different conditions was also evaluated. Both direct and indirect HVACP treatment of 25 mL OJ induced greater than a 5 log reduction in <i>S</i>. <i>enterica</i> following 30 s of treatment with air and MA65 gas with no storage. For 50 mL OJ, 120 s of direct HVACP treatment followed by 24 h storage achieved <i>S</i>. <i>enterica</i> reductions of 2.9 log in air and 4.7 log in MA65 gas. An indirect HVACP treatment of 120 s followed by 24 hours storage resulted in a 2.2 log reduction in air and a 3.8 log reduction in MA65. No significant (<i>P </i>< 0.05) Brix or pH change occurred following 120 s HVACP treatment. HVACP direct treatment reduced vitamin C content by 56% in air and PME activity by 74% in air and 82% in MA65. These results demonstrated that HVACP can significantly reduce <i>Salmonella</i> in OJ with minimal quality degradation.</p> <p>The second study in this dissertation examined the penetration process of plasma into semi-solid food and the resulting microbial inactivation efficacy. Agar gels of various densities (0.25, 0.5, 1.0, and 2%) with a pH indicator were inoculated with <i>S</i>. <i>enterica</i> (10⁷>CFU) and exposed directly (between the electrode) or indirectly (adjacent to the plasma field created between the two electrodes) to 90 kV at 60 Hz for up to 1.5 h. A long treatment time (1.5 h) caused sample temperature to increase 5~10 °C. The microbial analysis indicated a greater than 6 log₁₀ (CFU) reduction (both with air and MA65) in the zone with a pH change. Inactivation of bioluminescence cells in the plasma penetrated zone confirmed that the plasma, and its generated reactive species, inactivate microbial as it penetrates into the gel. A two-minute HVACP direct treatment with air at 90 kV induced greater than 5 log₁₀ (CFU)<i> S</i>. <i>enterica </i>reduction in applesauce. <em></em></p> <p>The third study investigated the interactions between HVACP and protein, using bovine serum albumin (BSA) as a model protein. The physicochemical and structural alteration of BSA and its reaction mechanism, when subjected to HVACP, were investigated. After treating 10 mL of BSA solution (50 mg/mL) at 90 kV for 20, 40, or 60 min, we characterized structural alteration and side-group modification. FTIR spectroscopy, Raman spectroscopy, and circular dichroism analysis indicated protein unfolding and decreased secondary structure (25 % loss of α-helix, 12% loss of β-sheet) in HVACP treated BSA. Average particle size in the protein solutions increased from 10 nm to 113 µm, with a broader distribution after 60 min HVACP treatment indicating protein aggregation. SDS-PAGE and mass spectrometer analysis observed a formation of new peptides of 1 to 10 kDa, indicating that the plasma triggered peptide bond cleavage. Chemical analysis and mass spectrometer results confirmed the plasma modifications on the side chains of amino acids. This study reveals that HVACP treatment may effectively introduce structural alteration, protein aggregation, peptide cleavage, and side-group modification to proteins in aqueous conditions, through several physicochemical interactions between plasma reactive species (reactive oxygen species and reactive nitrogen species) and the proteins. This finding can be readily applied to other plasma-protein studies or applications in the food system, such as enzyme inactivation or protein-based film modifications.</p>

Nuclear Engineering

Food Engineering

Food Packaging, Preservation and Safety

Food Processing

Atmospheric Cold Plasma

Microbial Inactivation

Plasma Penetration

Protein Modification

Physiochemical Interactions

Salmonella enterica serovar Typhi

Novel Microplastics Remediation Strategy Using High-Voltage Atmospheric Cold Plasma

Juan Velasquez (15353575)

27 April 2023

<p>  </p> <p>Plastics are the most common polymers used in various industries. However, million tons of plastics are produced and disposed every year around the world, and part of them end up entering the environment and agricultural ecosystems in the form of microplastics. Microplastics have become an environmental and health threat to aquatic species and humans because they are small and can easily reach water bodies for municipal and agricultural uses. Microplastics have been traced in food commodities and products derived from animals and even found in bottles of drinking water. As an approach to permanently remediating microplastics, current microplastic degradation techniques, however, require high energy inputs and thus are generally not cost-efficient. High-voltage atmospheric cold plasma (HVACP) is a low-cost energy-efficient technology to produce highly reactive species that can induce physicochemical changes in polymers. This study, for the first time, used HVACP as a novel remediation strategy for microplastics. HVACP was generated by dielectric barrier discharge at 50 kV using oxygen, nitrogen, or their mixture as working gas. Two types of microplastics, polypropylene (PP) and low-density polyethylene (LDPE), were treated for 30 min, and the effect of 24-h post-treatment was also studied. The properties of HVACP-treated microplastics, including weight, particle size, crystallinity, melting point, carbonyl index (CI), and surface morphology, were comprehensively analyzed. HVACP treatments were found effective in degrading both PP and LDPE microplastics. A larger extent of degradation was observed with PP microplastics treated by O/N mixture plasma, but the nitrogen plasma-treated sample showed a higher degree of oxidation according to its CI. For PE microplastics, oxygen plasma caused more degradation, but post-treatment did not promote further oxidation. The results indicated two potential mechanisms for microplastic degradation by HVACP. LDPE microplastics were degraded by oxidative reactions caused by highly reactive oxygen species, and PP microplastics followed a hydrolytic pathway of degradation as they became more hydrophilic after HVACP treatment. This study proved that HVACP is a promising method for microplastic degradation, and thus has great potential for addressing the severe challenges of microplastics that the food and agriculture sectors are currently facing.</p>

Food sustainability

Food engineering

Environmentally sustainable engineering

Microplastics

Cold Plasma

Degradation

High Voltage Atmospheric Cold Plasma