Artículo de revista
Removal of Pesticides during Washing and Cooking of Rice
[2013]
Hwang, L.H., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul, Republic of Korea;
Kim, A.K., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul, Republic of Korea;
Jung, B.K., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul, Republic of Korea;
Lee, J.K., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul, Republic of Korea;
et al.
Removal of Pesticides during Washing and Cooking of Rice
2013
Hwang, L.H., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul; Kim, A.K., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul; Jung, B.K., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul; Lee, J.K., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul; Shin, J.M., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul; Park, Y.H., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul; Park, H.W., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul; Kim, M.J., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul; Park, K.A., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul; Yun, E.S., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul; Kim, M.S., Seoul Metropolitan Goverment Research Institute of Public Health and Environment, Seoul
In this study, the pesticide residues of polished rice and brown rice were measured after washing and cooking process. The initial concentrations of isoprothiolane and fthalide were 7.134 ± 0.03 mg/kg and 2.024 ± 0.04 mg/kg for polished rice, and 17.941 ± 1.41 mg/kg and 6.413 ± 0.19 mg/kg for brown rice, respectively. After first washing process, the removal rates of isoprothiolane were 23.0% (polished rice) and 18.5% (brown rice). Also, the case of fthalide, the removal rates were 14.0% and 9.7%, respectively. The removal dose was increased, but the removal rate was decreased in proportion to the number of washing process, After the cooking process, the removal rates of isoprothiolane and fthalide were 66.0% and 79.0% (polished rice), and 88.7% and 92.9% (brown rice), respectively. The removal rate of isoprothiolane was higher in the washing process, and the case of fthalide was higher in the cooking process. The optimum washing process for the pesticides removal was five times and the cooking process was the most effective to use the new water after soaking the rice in water during 30 minutes.
[Journal of Food Hygiene and Safety]
2015/KR/KR2015_0.rdf
In this study, the pesticide residues of polished rice and brown rice were measured after washing and cooking process. The initial concentrations of isoprothiolane and fthalide were 7.134 ± 0.03 mg/kg and 2.024 ± 0.04 mg/kg for polished rice, and 17.941 ± 1.41 mg/kg and 6.413 ± 0.19 mg/kg for brown rice, respectively. After first washing process, the removal rates of isoprothiolane were 23.0% (polished rice) and 18.5% (brown rice). Also, the case of fthalide, the removal rates were 14.0% and 9.7%, respectively. The removal dose was increased, but the removal rate was decreased in proportion to the number of washing process, After the cooking process, the removal rates of isoprothiolane and fthalide were 66.0% and 79.0% (polished rice), and 88.7% and 92.9% (brown rice), respectively. The removal rate of isoprothiolane was higher in the washing process, and the case of fthalide was higher in the cooking process. The optimum washing process for the pesticides removal was five times and the cooking process was the most effective to use the new water after soaking the rice in water during 30 minutes.
