Food Science and Preservation (한국식품저장유통학회지)

The Korean Society of Food Preservation (한국식품저장유통학회)
권호 표지
DOI QR코드

DOI QR Code

Influence of usage environment from camping cooking utensils on migration of hazardous metals

사용 환경에 따른 캠핑용 조리 기구로부터 유해금속 용출의 변화

  • Lee, Jin-hee (Department of Pharmaceutical Chemicals, Daegu Metropolitan City Institute of Health and Environment) ;
  • Kim, Ji-Yeon (Department of Pharmaceutical Chemicals, Daegu Metropolitan City Institute of Health and Environment) ;
  • Park, Ye-Seul (Department of Pharmaceutical Chemicals, Daegu Metropolitan City Institute of Health and Environment) ;
  • Park, Sang-Gyu (Department of Pharmaceutical Chemicals, Daegu Metropolitan City Institute of Health and Environment) ;
  • Lee, Jae-Ho (Department of Pharmaceutical Chemicals, Daegu Metropolitan City Institute of Health and Environment) ;
  • Yoon, Jong-Ho (Department of Pharmaceutical Chemicals, Daegu Metropolitan City Institute of Health and Environment) ;
  • Kim, Gyung-Tae (Department of Pharmaceutical Chemicals, Daegu Metropolitan City Institute of Health and Environment) ;
  • Han, Gi-Dong (Department of Food Science and Technology College of Life Applied Science, Yeungnam University)
  • 이진희 (대구광역시 보건환경연구원 약품화학과) ;
  • 김지연 (대구광역시 보건환경연구원 약품화학과) ;
  • 박예슬 (대구광역시 보건환경연구원 약품화학과) ;
  • 박상규 (대구광역시 보건환경연구원 약품화학과) ;
  • 이재호 (대구광역시 보건환경연구원 약품화학과) ;
  • 윤종호 (대구광역시 보건환경연구원 약품화학과) ;
  • 김경태 (대구광역시 보건환경연구원 약품화학과) ;
  • 한기동 (영남대학교 생명응용과학대학 식품공학과)
  • Received : 2017.10.19
  • Accepted : 2017.12.07
  • Published : 2017.12.30
Download PDF
⟨ Previous Next ⟩

Abstract

Hazardous metals leaching experiment was carried out in accordance with various usage environments for camping cooking utensils distributed in the market. There was a significant difference in the degree of migration for lead, arsenic, cadmium and nickel defending on the solvent and how to use, although they were all appropriate for criteria. In general, the migrated amount of aluminum was increased in acidic condition, and the migrated amount of arsenic was increased in salty condition. Physical scratches increased the overall release of hazardous metals from the portable pots and pans for camping in all solvents. Especially, in 0.5% citric acid solution, cadmium was migrated by physical scratch in stainless steel and hard aluminum pots and pans. The longer the leaching time, the higher the migration of aluminum in acid condition and arsenic in basic condition. From these results, it is desirable to use the cooking utensil for camping without being exposed to strong acidic or basic solution and scratches in order to reduce the migration of hazardous metals from them.

대구시내 대형마트에서 유통되고 있는 스테인레스, 경질알루미늄, 연질알루미늄 재질 코펠 및 불소수지 코팅 불판에 대해 0.5% citric acid 용액에서 용출되는 유해 금속을 유도결합플라즈마 발광광도측정기(ICP-OES)로 측정한 결과, 식품용 기구 및 용기 포장 공전에 기준이 설정된 납, 카드뮴, 비소, 니켈의 경우는 모두 적합한 것으로 나타났다. 그러나 용출 용액과 사용 환경에 따라 그 용출 정도에 차이가 있는 것으로 나타났다. 증류수, 0.5% citric acid 용액, 1% NaCl 용액 등 용출 용액을 달리하여 30분간 가열한 뒤 평균 용출량을 비교한 결과, 증류수에서 경질알루미늄 재질 코펠의 알루미늄 용출량이 0.007 mg/L 수준이었으나, 0.5% citric acid 용액에서는 스테인레스 재질 코펠은 0.021 mg/L, 경질알루미늄 재질 코펠은 51.97 mg/L, 연질알루미늄 재질 코펠은 24.89 mg/L, 불소수지 코팅 불판은 0.040 mg/L로 증류수와 1% NaCl 용액에서의 용출량보다 높았다. 1% NaCl 용액에서 비소는 스테인레스와 연질알루미늄 재질 코펠 0.006 mg/L, 경질알루미늄 재질 코펠 0.008 mg/L로 증류수와 0.5% citric acid 용액에서의 용출량보다 다소 높게 용출되었다. 0.5% citric acid 용액에서 니켈이 스테인레스 재질 코펠이 0.007 mg/L로 증류수와 1% NaCl 용액에서의 용출량보다 다소 높게 용출되었는데, 이는 스테인레스 코펠의 니켈 조성 특성 때문으로 사료된다. 카드뮴은 모든 용액에서 검출되지 않았다. 물리적 스크래치를 가한 후의 용출 용액에 따른 유해 금속 용출량은 스크래치를 가하기 전보다 모든 용액에서 전반적으로 증가하는 것으로 조사되었다. 특히, 0.5% citric acid 용액에서는 스테인레스와 경질알루미늄 재질 코펠에서 카드뮴이 용출되는 것으로 나타났다. 용출 시간에 따른 유해 금속 용출량 변화를 살펴보면, 증류수에서는 경질알루미늄, 연질알루미늄 재질 코펠과 불소수지 코팅 불판의 알루미늄 용출량이 증가하였다. 0.5% citric acid 용액에서는 스테인레스, 경질알루미늄, 연질알루미늄 재질 코펠의 니켈과 알루미늄 용출량이 증가하였고, 불소수지 코팅 불판은 납, 비소, 알루미늄 용출량이 증가하였다. 1% NaCl 용액에서는 스테인레스, 경질알루미늄 재질 코펠과 불소수지 코팅 불판의 비소 용출량이 증가하였고, 연질알루미늄 재질 코펠의 비소와 알루미늄 용출량이 증가하였다.

Keywords

References

  1. Wernick S, Pinner R, Sheasby PG (1987) The Surface Treatment and Finishing of Aluminium and its Alloys. Vol. I, 5th Ed, Finishing Publications Ltd, UK, p 1-50
  2. Maynard RL (2001) The Merck Index, Merck & CO INC, White House Station, NJ, USA, p 60, 136, 272, 967, 1165
  3. Scncar J, Stibilj V, Milacic R (2004) Determination of aluminium in Slovenian foodstuffs and its leachability from aluminium-cookware. Food Chem, 85, 151-157 https://doi.org/10.1016/j.foodchem.2003.07.028
  4. Gunnar FN, Bruce AF, Monica N, Lars TF (2007) Aluminium Handbook on the Toxicology of Metals. 3rd Ed, Academic Press, Burlington, VT, USA, p 339-352
  5. Gramiccioni L, Ingrao G, Milana MR, Santaroni P, Tomassi G (1996) Aluminium levels in Italian diets and in selected foods from aluminium utensils. Food Addit Contam, 13, 767-774 https://doi.org/10.1080/02652039609374464
  6. Kamerud KL, Hobbie KA, Anderson KA (2013) Stainless steel leaches nickel and chromium into food during cooking. J Agric Foods Chem, 61, 9495-9501 https://doi.org/10.1021/jf402400v
  7. World Health Organization. http://www.who.int /mediacentre/factsheets/en/ (accessed July 2017)
  8. Croghan CW, Park NC, Egeghy PP (2003) Methods of dealing with values below the limit of detection using SAS. EPA Science Inventory
  9. Kwon JW (2009) Definition and application of detection and quantification limits. Korean J Environ Agric, April 85-102
  10. Choi JC, Park SJ, Goh HA, Lee JY, Eom MO, Kim MH (2014) A study on migration of heavy metals from kitchen utensils including glassware, ceramics, enamel, earthen and plastics. J Food Hyg Saf, 29, 334-339 https://doi.org/10.13103/JFHS.2014.29.4.334
  11. Lee KH, Kwon KS, Jeon DH, Choi BH, Lee SH, Lee CW (1999) Migration mechanism of hazard elements from brass kitchenwares. J Korea Soc Packag Sci Technol, 5, 24-30
  12. Lim JG (2005) The monitoring of harmful elements on food packaging (I)-Metallic kitchenware, Biodegradability disposable package. Report of Korea Environment & Merchandise Testing Institute, 1470002069, 15-76
  13. Kim MS, Cho TH, Kim CK, Kim HS, Shin GY, Kim JH, Jung K (2014) Measurement of hazardous metals migrated from cooking utensils for camping. Report of Seoul Institute Health Environment, 29-36
  14. Lee SH, Jung KJ, Lee YK, Sung JH, Eom MO, Lee YJ, Lim JG (2007) Monitoring of lead and antimony in metallic kitchenware. J Food Hyg Saf, 22, 52-56

Cited by

  1. 유통 주방기구의 재질별 용출 특성 평가 -금속제 주방기구 중심으로- vol.36, pp.1, 2017, https://doi.org/10.13103/jfhs.2021.36.1.51