This study, for the first time, investigated the packaging requirements of in-package dielectric barrier discharge cold plasma treatment (DBD-CPT). The parameters determining packaging requirements include the internal oxygen concentration, headspace volume to sample volume ratio (HSR), direct or indirect treatment, and kind of packaging material. Grape tomato and mixed vegetables, composed of romaine lettuce, red cabbage, carrot with and without the inoculation with Salmonella, were subjected to DBD-CPT at 32.5 kV for 3 min. Increasing the oxygen concentration in the container from 5% to 90% did not influence Salmonella inactivation (p>0.05). Increasing the HSR of air packaging material from 54:1 to 522:1 increased Salmonella inhibition on grape tomato (p<0.05). Higher Salmonella inhibition was found in grape tomatoes in directly treated salads than in indirect-treated salads (p<0.05). The inactivation of indigenous mesophilic aerobic bacteria was exhibited higher when packaged with PE than with PET (p<0.05). Optimal package requirements were determined as HSR of 522:1, direct treatment, and uses of PE as packaging material for the microbial inactivation using in-package cold plasma treatment. DBD-CPT increased the water vapor permeability of all packaging materials (p<0.05), but did not change their tensile properties and transparency (p>0.05). Overall, DBD-CPT was found effective in decontaminating mixed vegetables, prepackaged with commercial packages, without affecting the tensile and optical properties of the packages. Furthermore, the HSR, the electrode-container distance and kind of packaging material were identified as the major packaging requirements affecting the microbial inactivation efficacy of in-packaged cold plasma treatment.

Muffin was developed using blueberry powder and the shelf life of the muffin packaged in modified atmosphere was determined. Blueberry was freeze-dried and milled to prepare powder. As the concentration of blueberry powder increased from 0 to 15% (w/w), hardness and gumminess also increased (p<0.05). The Hunter L and b values of the crust and crumb of muffin decreased as the concentration increased, while their Hunter a values increased. Blueberry powder concentrations of 10 and 15% resulted in high preference in taste, texture, and overall acceptability. Blueberry muffin containing powder at 10% was packaged in modified atmosphere (MA). The optimum gas for modified atmosphere packaging (MAP) of the muffin was the mixture of carbon dioxide (CO2) and nitrogen (N2) (7:3), which improved microbial stability without altering muffin hardness. The shelf life of modified atmosphere packaged blueberry muffin was determined using the accelerated life test. The shelf life values for MA packaged blueberry muffin stored at 25 and 35°C were predicted as 21 and 5 d, respectively. Further, the Q10 values for 25- 35°C and 35-45°C were determined as 4.2 and 2.9, respectively. The MAP can preserve blueberry muffin for 3 weeks at 25°C, without the external addition of preservatives.

Effects of dynamic high-pressure (DHP) treatments with and without integration with heating on microbial stability, vitamin C concentration, color, sugar content, and pH of orange juice were studied and compared with those of the conventional thermal treatment. Freshly squeezed orange juice was heated at 90oC for 1 min or DHP-treated at 205 MPa and 20, 50, 60, or 70oC. The DHP treatment at 20oC without heating and the treatment at 50oC inactivated indigenous mesophilic aerobic microorganisms in orange juice by 4.2 and >7 log CFU/mL, respectively. The DHPtreated juice exhibited brighter color and higher vitamin C concentration and sugar content than the thermally treated juice, regardless of integration with heating. The DHP-treated juice demonstrated brighter color and higher sugar contents than untreated juice and thermally treated juice during storage at 4oC for 63 days. The results have demonstrated the potential of applying DHP treatments to pasteurize orange juice with increasing brightness and sugar content of the juice.

The effects of pressure and number of passes upon Biji paste properties using a high-pressure homogenizer (HPH)were investigated. A hydrocolloid of Biji was processed with a HPH at 15,000 or 25,000 psi and with 1 or 2 passes.The hydrocolloid was assessed for dietary fiber, protein, sugar content, water absorption index (WAI), water solu-bility index (WSI), rheological character, and distribution stability. As pass number and pressure increased, solubledietary fiber, sugar content, WAI, and distribution stability also increased, whereas particle size decreased. As aresult, processing at 25,000 psi and 2 passes is considered as a proper treatment for processing quality. In breadmaking with HPH treated Biji, volume, hardness, and cohesiveness of bread increased, while density decreased. Theoptimum processing condition for bread with HPH treated Biji was determined by a design expert program. Nineexperimental points were selected, and wheat flour (91-95%) and HPH Biji (5-9%) were chosen as the independentvariables. The optimum formulation of bread using the numerical analysis was set at 94.2% wheat flour and 5.8%HPH Biji with a 0.725 desirability value.

본 연구에서는 DSM을 이용하여 단백질 추출이나 정제 없이 식품에 적용 가능성이 있는 가식성 필름을 개발하였다. HPH 처리는 표면이 매끄럽고 균일한 형태의 필름을 형성시켰고, 필름의 WVP값을 감소시켜 수분 방벽 효과를 높였다. 필름 내 글리세롤 농도 증가는 WVP값을 전반적으로 높였다. 농산물 가공 부산물인 DSM으로 제작된 가식성 필름은 새로운 식품 소재로서 상업적 적용 가능성을 보여주었다.