Dishwashing tools such as sponges, scourers, and dishcloths are known to harbor dense and diverse microbial communities, including pathogenic bacteria. In this study, the potential of corona discharge plasma jet (CDPJ) as a disinfectant was tested to improve the hygienic quality of dishwashing tools. For the simulation of microbial contamination, selective pathogenic bacteria (Escherichia coli O157:H7, Staphylococcus aureus, and Pseudomonas putida) were inoculated on selected dishwashing tools (dishcloth, sponge, and scourer) at concentrations of 6.55 to 8.77 log CFU/cm 2 . CDPJ generated at 20 kV voltage and 1.5A current was used for decontamination, whereas a sample-to-electrode distance of 25 mm was maintained during the treatment. Following CDPJ treatment for 5 min, the viable counts of E. coli O157:H7, S. aureus, and P. putida were reduced by 4.30-4.56, 3.71-4.78, and 3.50-3.83 log, respectively. The rates of inactivation were varied among the pathogens, decreasing in the order E. coli O157:H7 > S. aureus > P. putida. Among tested kinetic models, namely log-linear, log-linear with shoulder, and Weibull models, the log-linear with shoulder model was found to be the most suitable model to explain the CDPJ inactivation of the pathogens. In conclusion, CDPJ can be used as a potential sanitizing agent for dishwashing tools.

Benzo[α]pyrene (BaP), a carcinogenic polycyclic aromatic hydrocarbon, is ubiquitous in nature. It is generally found in heat-treated foods like roasted sesame seeds. BaP degradation has attracted attention due to the recalcitrant nature of BaP. In this study, corona discharge plasma jet (CDPJ) was used to degrade BaP on glass slides and in food materials. The plasma discharges were generated using air as working gas under atmospheric pressure conditions and at different currents (1.00, 1.25, and 1.50 A). Optimal BaP degradation was observed upon using CDPJ generated at 1.50 A current and at 15 mm sample-to-electrode distance (STED). Under these conditions, initial BaP concentration on slides was reduced maximally by 87.09% in 30 min. The degradation kinetics were well-fitted by Weibull tail model compared with others. In food commodities (roasted sesame and perilla seeds), the average levels of BaP degradation ranged between 32.96-45.90% following CDPJ treatment for 30 min.

Sodium dodecylbenzen sulfonate (DBS) and linear alkylbenzene sulfonate (LAS) are widely used in dishwashing products. Residual levels of these surfactants are commonly found on the surfaces of dishware following dishwashing. Residual surfactants and detergents can act as potential toxicants and may pose health risks. This study explored the applicability of dielectric barrier discharge plasma (DBDP) for the degradation of residual surfactants in order to minimize their harmful effects. The plasma was generated using 10 kV pulsed DC power supply at different input currents (2.0-3.0 A) and at various inter-electrode gaps (2.0-3.0 mm). Under simulatory treatment conditions, diluted surfactants (DBS and LAS) and DBS-containing dishwashing detergents dispersed on slide glasses were exposed to DBDP for predetermined periods of time. Results indicated that, under optimal treatment conditions of 3.0 A current and 2.0 mm inter-electrode gap, tested surfactants and surfactants in detergents were degraded in the range of 60- 70% following the plasma treatment for 120 min. Modeling of degradation kinetics indicated that Weibull distribution was the best-fit model, and decimal degradation times (δ) were calculated. Pure surfactants were degraded at relatively higher level than surfactants in detergents. Among these anionic surfactants, DBS was more rapidly degraded than LAS by plasma treatment.

Stream of afterglow of an atmospheric pressure plasma can conveniently be used for large scale decontamination operations. In the present study, an afterglow dielectric-barrier discharge air plasma (ADDAP) was used to inactivate Escherichia coli O157:H7 as a model microorganism for studying the plasma inactivation effect. The plasma was generated at current levels in the range of 0.4 - 0.8 A. The power consumption of ADDAP generation system ranged 169.5 - 221.9 W with respect to the current intensity range. At this current level, the temperature observed in the treatment chamber remained less than 30℃. Regarding chemical composition of ADDAP in the treatment chamber, NOx species were predominantly generated. The levels of NOx species increased as the current intensity increases and the maximum NO and NO2, concentrations noted were 6 and 4 ppm, respectively, but that of CO was less than 1 ppm level at 0.8 A. Upon treating with the ADDAP generated at 0.4 - 0.8 A for 180 min, E. coli O157:H7 showed 1.24 – 2.71 log reductions. The inactivation patterns exhibited better fit to Weibull-tail model. The comparison of delta values indicated that superior inactivation effects were observed as the current intensity increased.

Residual detergents and surfactants on utensils have brought about health issues because they can be absorbed to human digestion system together with containing foods. In the present study, a dielectric barrier discharge plasma (DBDP) was used to explore the applicability of non-thermal plasma for the degradation of residual surfactants and dishwashing detergents in order to reduce the intake of the residues remaining on utensils as the result of incomplete rinsing during dishwashing procedures. DBDP was generated at current intensity 2.0 - 3.0 A, and electrode gap 2.5 mm. Diluted dishwashing detergents and surfactants were spotted on slide glasses and exposed to DBDP for different periods of time. The results indicated that the dishwashing detergents and surfactants were degraded by 46.9 - 84.3% after up to 120 min treatments. Weibull equation was the best fit model to the degradation patterns of surfactants, and the decimal degradation time(δ) of 180.2 - 688.9 min were observed according to currents. Surfactants contained in detergents were degraded more effectively than the surfactants themselves. Among the anion surfactants, DDBS was more rapidly degraded than LAS and ABS.

Curry ingredients such as turmeric, coriander, cumin, fennel, fenugreek often contain microbial contaminants. Our preliminary analysis showed that microbial contamination in fenugreek was relatively higher than other ingredients, and therefore the decontamination using a non-thermal plasma was performed to enhance its microbial quality. Corona discharge plasma jet (CDPJ) was used for the decontamination of fenugreek seeds. The results showed that aerobic bacteria were decreased by 0.88 - 2.51 log units, and yeast and mold exhibited the reduction of 0.58-1.95 log units with the treatment for 20 min. For the microbial inactivation pattern, the Weibull model gave the best distribution fit among the models tried. The decontamination effect of the CDPJ was enhanced with the decrease of the distance from the plasma electrode, and with the increase of the current intensity. The effect of the plasma treatment on antioxidant capacity of fenugreek seed was also investigated, and the obtained results indicated that total phenolic content and DPPH radical scavenging ability were unaffected by the treatment at a current intensity of 1.00 A regardless the treatment distance from the electrode, whereas significant increases were observed with the treatment at 1.25 A and 1.50 A currents.

In this study, a two-factor-six-level factorial design was adopted for optimizing brine (saturated salt solution) and water flow rates in electrolyzed water generator in order to produce electrolyzed water (EW) having best performance for vegetable washing. The pH, electro-conductivity, chlorine contents of produced EW were determined. The optimum EW for broccoli sprouts washing was produced at flow rates of brine and water of 100 mL/min and 300 mL/min respectively. The optimum washing time was 20 s based on the quality of washed broccoli sprouts. The microbial counts were decreased by 1.4 log for aerobic bacteria and 1.0 log for yeasts and mold. The functional quality and sensory characteristics of broccoli sprouts were unaffected by the EW washing. The results demonstrated the applicability of EW for the improvement of hygiene of broccoli sprouts without affecting quality.