Journal of Bio-Environment Control (생물환경조절학회지)

The Korean Society for Bio-Environment Control (한국생물환경조절학회)
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Effects of Active Modified Atmosphere Packaging on the Storability of Fresh-cut Paprika

Active MAP가 파프리카 신선편이 저장성에 미치는 영향

  • Received : 2011.06.20
  • Accepted : 2011.09.02
  • Published : 2011.09.30
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Abstract

The processing techniques are need to use the non-marketable paprika fruit because paprika that is difficult crop for cultivation and produced easily non-marketable fruits, such as physiological disorder fruit, malformed fruit, and small size fruit. This study was carried out to investigate the proper active modified atmosphere packaging (MAP) condition for enhancing the storability of fresh-cut paprika fruit. The fresh-cut paprika (cv 'Score', seminis) put into $7cm{\times}0.7cm$ size and packed them in 20 g bags. The active MAP and vacuum treated paprika fruits were packaged with LLDPE/Nylon, EVOH, Tie film, and injected partial pressures of $CO_2$ and $O_2$, and $N_2$ in the packages immediately after sealing to treat active MAP. The ratio of $CO_2$, $O_2$, and $N_2$ of active MAP conditions were 0 : 20 : 80 (air), 5 : 5 : 90, 30 : 10 : 60, 10 : 70 : 20 and vacuum treatment did not contain any gas. The passive packaging treated paprika packaged with $40{\mu}m$ ceramic film. After 7 days of storage at $9^{\circ}C$, the fresh weight decreased less than 2% in all treatments, and showed lower in 5 : 5 : 90 ($CO_2:O_2:N_2$) active-MAP treatment and higher in vacuum treatment than other treatments. The $CO_2$ and $O_2$ concentration in packages did not change remarkably in active-MA treatments except 30 : 10 : 60 active-MAP treatment that showed sharply decreased $O_2$, concentration and increased $CO_2$ concentration at $1^{st}$ day of storage at $9^{\circ}C$. The ethylene concentration in package was the highest in 30 : 10 : 60 active-MAP treatment and the lowest in the passive MAP treatment that packaged with gas permeable film during $9^{\circ}C$ storage for 7 days. The 30 : 10 : 60 active-MAP treatments were not proper condition to storage fresh-cut paprika. The visual quality was maintained higher in 0 : 20 : 80 (air), 5 : 5 : 90, and 10 : 70 : 20 active MAP treatments and passive MAP treatment than others and the firmness, off-odor, and electrolyte leakage was investigated at 7th day of storage at $9^{\circ}C$. The 5 : 5 : 90 and 10 : 70 : 20 active-MAP treatment showed higher firmness and lower off-odor than other treatments after $7^{th}$ day of storage at $9^{\circ}C$. In addition, the electrolyte leakage was reduced less than 20% at 0 : 20 : 80 (air), 5 : 5 : 90, 10 : 70 : 20, and passive MA treatments. Therefore, 10 : 70 : 20 ($CO_2:O_2:N_2$) and 0 : 20 : 80 (air) might be recommended for proper active MAP conditions.

파프리카 신서편이 제품화 및 품질과 저장성 향상을 위해 Active MA 조건을 비교 규명 하였다. Active MA 처리구와 진공처리, 일반 MA 포장 처리를 하였으며 생체중, 산소, 이산화탄소, 에틸렌 농도와 경도, 이취 전해질 누출량을 측정하였다. 생체중은 진공처리가 가장 큰 감소를 보였고 5 : 5 : 90($CO_2:O_2:N_2$), 가장 낮은 감소 보였으며 다른 처리에서는 처리간의 큰 차이를 보이지 않았다. 산소, 이산화 탄소, 에틸렌농도 변화는 30 : 10 : 60($CO_2:O_2:N_2$) 처리가 산소 감소율과 이산화 탄소 증가율이 가장 크게 측정되었으며 그 외 처리는 감소율과 증가율에서 특별한 특징을 나타내지는 않았다. 에틸렌 농도는 30 : 10 : 60 처리 조건이 가장 크게 측정 되었으며 MA 조건이 가장적은 농도로 측정 되었다. 경도는 진공처리 조건이 가장 낮게 측정되었으며 이취의 경우 30 : 10 : 60 처리조건과 진공 포장 처리구의 이취 발생량이 가장 많은것으로 평가 되었다. 전해질 용출량은 진공조건 처리가 70%로 가장 많았고 30 : 10 : 60 처리가 35%로 Active MA 조건에서 가장 많은 누출을 보였다. 이상의 결과로 볼 때, 진공처리와 고농도 이산화탄소 처리는 파프리카 신선편이 포장 처리에 적합하지 않으며 Active MA 처리시 10 : 70 : 20($CO_2:O_2:N_2$)와 0 : 20 : 80이 가장 적합하다고 사료된다.

Keywords

References

  1. Choi, J.W., H.E. Lee, W.M. Lee, M.A. Cho, and Y.P. Hon. 2010. Effect of MA and Active MA on the quality Maintenance of Bell Pepper during Cold Storage. Kor. J. Hort. Sci. Technol. 28(SUPPL. I):74-75.
  2. Gil, M.I., M.A. Conesa, and F. Arte's. 2002. Quality changes in fresh cut tomato as affected by modified atmosphere packaging. Postharvest Biology and Technology 25:199-207. https://doi.org/10.1016/S0925-5214(01)00166-1
  3. Guevara, J.C., E.M. Yahia, E. Brito de la Fuente, and S.P. Biserka. 2003. Effects of elevated concentrations of $CO_{2}$ in modified atmosphere packaging on the quality of prickly pear cactus stems (Opuntia spp.) Postharvest Biology and Technology 29:167-176 https://doi.org/10.1016/S0925-5214(03)00021-8
  4. Jacxsens, L., F. Devlieghere, and J. Debevere. 1999. Spoilage and safety of fresh-cut vegetables packaged under equilibrium modified atmosphere: A case study of mixed lettuce followed through the distribution chain. MEDEDELINGEN- FACULTE IT LANDBOUWKUNDIGE EN TOEGEPASTE BIOLOGISCHE WETENSCHAPPEN 64:493-498.
  5. Kader, A.A. 1992. Postharvest technology of horticultural crops. Univ. of California, CA, USA.
  6. Kader, A.A. 2002. Postharvest technology of horticultural crops. 3rd edition. University of California, Division of Agriculture and Natural Resources. USA.
  7. Kang, H.M. and K.W Park. 1998. Changes in composition of free acids in relation to ethylene production during the ripening of tomato fruits. Kor. Soc. Hort. Sci. 39:385-390.
  8. Kang, H.M., K.W. Park, and M.E. Saltveit. 2002. Elevated growing temperatures during the day improve the postharvest chilling tolerance of greenhouse-grown cucumber (Cucmis sativus) fruit. Postharvest Biology and Technology 24:49-57. https://doi.org/10.1016/S0925-5214(01)00129-6
  9. Kays J. Stanley and Paull E. Robert. 2004. Postharvest Biology.Exon Press, Athens,GA.
  10. Kays, S.J. 1991. Extension physiology of perishable plant products AVI publishing. New York.
  11. Kubo, Y., A. India, and R Nakamura. 1989. Effects of high $CO_{2}$ on respiration in various horticultural crops. J. Jaoan. Soc. Hort. Sci. 58:731-736. https://doi.org/10.2503/jjshs.58.731
  12. Mateosa, M., D. Kea, M. Cantwllb, and A.A. Kadera. 1993. Phenolic metabolism and ethanolic fermentation of intact and cut lettuce exposed to CO2-enriched atmospheres. Postharvest Biol. Technol. 3:225-233. https://doi.org/10.1016/0925-5214(93)90058-B
  13. MIFAFF (minister for food, agriculture, forestry and fisheries) 2009. 2008 Status of protected vegetables and production of vegetables in Korea http://ebook.maf.go.kr/17628.
  14. Park, K.W., H.M. Kang, D.M. Kim, and H.W. Park. 1999. Effects of the packaging films and storage temperature on modified atmosphere storage of ripe tomato. J. Kor. Soc. Hort. Sci. 40:643-646 (in Korean).
  15. Park, K.W., H.M. Kang, and C.H. Kim. 2000. Comparison of storability on film sources and storage temperature for fresh Japanese mint in MA storage. J. Bio. Env. Con. 9:40-46 (in Korean).
  16. Yang, Y.J. and K.A. Lee. 1997. Physiological characteristics of chilling and CA effect on its reduction during cold storage of pepper fruit. J. Kor. Soc. Hort Sci. 38:478-482.
  17. Wang, C.Y. 1990. Chilling injury of horticultural crops. CRC press, Boca Raton. USA.
  18. Wardowski, W.F., W. Grierson, and G.J. Edwards. 1973. Chilling injury of stored limes and grapefruit as affected by differentially permeable packaging films. HortScience 8:173-175.
  19. Wills, R.B.H. and P. Wimaladiri. 1979. Short pre-storage exposures to high carbon dioxide of low oxygen atmospheres for the storage of some vegetables. Hortscience 14:528-530.
  20. Yun, I.J., M.Y. Lee, D.S. Chung, and C.S. Jeong. 2003. Effects of MA Active Packaging for shelf-life of Fresh-cut Head Lettuce. Kor. J. Hort. Sci. Technol. 21(SUPPL. II):56.
  21. Zagory, D. and A.A. Kader. 1988. Modified atmosphere packaging of fresh produce. Food Technol. 42:70-77.