Journal of Biosystems Engineering

Korean Society for Agricultural Machinery (한국농업기계학회)
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Using Hyperspectral Fluorescence Spectra of Deli Commodities to Select Wavelengths for Surveying Deli Food Contact Surfaces

  • Lefcourt, Alan M. (USDA, Agricultural Research Service, Environmental Microbial and Food Safety Laboratory) ;
  • Beck, Elizabeth A. (USDA, Agricultural Research Service, Environmental Microbial and Food Safety Laboratory) ;
  • Lo, Y. Martin (Department of Nutrition and Food Science, University of Maryland) ;
  • Kim, Moon S. (USDA, Agricultural Research Service, Environmental Microbial and Food Safety Laboratory)
  • Received : 2015.04.29
  • Accepted : 2015.05.29
  • Published : 2015.06.01
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Abstract

Purpose: The inability to adequately judge the efficacy of cleaning and sanitation procedures in deli departments is a recognized food safety concern. In a prior study, our research group demonstrated that visual inspection of cleaned produce processing surfaces could be enhanced through the use of a portable fluorescence imaging device that detected residual produce residues. Methods: To explore the feasibility of using fluorescence imaging to similarly detect residual deli residues, spectra of American, Cheddar, Provolone, and Swiss cheeses and of processed chicken, ham, roast beef, and turkey were acquired using a laboratory hyperspectral imaging system. Circular punches of these commodities were placed onto stainless steel and high density polyethylene coupons for imaging. The coupon materials were selected to represent common surfaces found in deli departments. Results: Analysis of hyperspectral fluorescence images showed that cheeses exhibited peaks in the blue-green region and at around 675 nm. Meats exhibited peaks in the blue-green region with one of four ham and one of four chicken brands exhibiting peaks at around 675 nm, presumably due to use of plant-derived additives. When commodities were intermittently imaged over two weeks, locations of spectral peaks were preserved while intensity of peaks at shorter wavelengths increased with time. Conclusion: These results demonstrate that fluorescence imaging techniques have the potential to enhance surface hygiene inspection in deli departments and, given the immediate availability of imaging results, to help optimize routine cleaning procedures.

Keywords

References

  1. Beck, E.A., A.M. Lefcourt, Y.M. Lo and M.S. Kim. 2015. Use of a portable fluorescence imaging device to facilitate cleaning of deli slicers. Food Control 51: 256-262. https://doi.org/10.1016/j.foodcont.2014.11.031
  2. Chappelle, E.W., J.E. McMurtrey and M.S. Kim. 1991. Identification of the pigment responsible for the blue fluorescence band in the laser-induced fluorescence (LIF) spectra of green plants, and the potential use of this band in remotely estimating rates of photosynthesis. Remote Sensing of Environment 36(3):213-218. https://doi.org/10.1016/0034-4257(91)90058-E
  3. Cunningham, A.E., R. Rajagopal, J. Lauer and P. Allwood. 2011. Assessment of hygienic quality of surfaces in retail food establishments based on microbial counts and real-time detection of ATP. Journal Food Protection 74(4):686-690. https://doi.org/10.4315/0362-028X.JFP-10-395
  4. FDA. 2013. Interagency risk assessment: Listeria monocytogenes in retail delicatessens technical report, 1-175. (accessed 8.26.14).
  5. Jun, W., M.S. Kim, B.K. Cho, P.D. Millner, K. Chao and D.E. Chan. 2010. Microbial biofilm detection on food contact surfaces by macro-scale fluorescence imaging. Journal of Food Engineering 99(3):414-322.
  6. Kim, M.S., A.M. Lefcourt and Y.R. Chen. 2003. Optimal fluorescence excitation and emission bands for detection of fecal contamination. Journal of Food Protection 66(7):1198-1207. https://doi.org/10.4315/0362-028X-66.7.1198
  7. Kim, M.S., K. Chao, D.E. Chan, W. Jun, A.M. Lefcourt, S.R. Delwiche and K. Lee. 2011. Line-scan hyperspectral imaging platform for food safety and quality evaluation: System characterization and enhancement. Transactions of the ASABE. 54(2):703-711. https://doi.org/10.13031/2013.36473
  8. Kim, M.S., A.M Lefcourt, K. Chao, Y.R. Chen, A.G. Senecal and P. Marek. 2012. Handheld inspection tool and method. US patent number 8,310,544.
  9. Kim, T., H. Lee, M.S. Kim and B. Cho. Optimal optical filters of fluorescence excitation and emission for poultry fecal detection. Journal of Biosystems Engineering 37(4):265-270. 2012. https://doi.org/10.5307/JBE.2012.37.4.265
  10. Lee, H., M.S. Kim, K. Chao, A.M. Lefcourt and D.E. Chan. 2013. Development of fluorescence based handheld imaging devices for food safety inspection. Proc. SPIE 8721, Sensing for Agriculture and Food Quality and Safety V, 872109 (May 29, 2013).
  11. Lefcourt, A.M., M.S. Wiederoder, N. Liu, M.S. Kim and Y.M. Lo. 2013. Development of a portable hyperspectral imaging system for monitoring the efficacy of sanitation procedures in food processing facilities. Journal of Food Engineering 117:59-66. https://doi.org/10.1016/j.jfoodeng.2013.01.043
  12. Murata, N., M. Nishimura and A. Takamiya. 1966. Fluorescence of chlorophyll in photosynthetic systems: III. Emission and action spectra of fluorescence-Three emission bands of chlorophyll a and the energy transfer between two pigment systems. Biochimica et Biophysica Acta (BBA) - Biophysics including Photosynthesis, 126(2): 234-243.
  13. Sebranek, J.G. and J.N. Bacus. 2007. Cured meat products without direct addition of nitrate or nitrite: what are the issues? Meat Science 77(1):136-147. https://doi.org/10.1016/j.meatsci.2007.03.025
  14. USDA FSIS. 2010. FSIS Comparative risk assessment for Listeria monocytogenes in ready-to-eat meat and poultry deli meats report. (accessed 8.26.14).
  15. USDA FSIS. 2013. FSIS Directive: Safe and suitable ingredients used in the production of meat, poultry, and egg products. (accessed 9.3.14).
  16. USDEC (United States Dairy Export Council). 2005. Deli operators training program: Food safety. (accessed 8.27.2014).
  17. Wiederoder, M.S., A.M Lefcourt, M.S. Kim and Y.M. Lo. 2012. Detection of fresh-cut produce processing residues on food contact surface materials using hyperspectral imaging. Journal of Food Measurement and Characterization 6(1-4):48-55. https://doi.org/10.1007/s11694-012-9132-1
  18. Wiederoder, M.S., N.T. Liu, A.M. Lefcourt, M.S. Kim and Y.M. Lo. 2013. Use of a portable hyperspectral imaging system for monitoring the efficacy of sanitation procedures in produce processing plants. Journal of Food Engineering 117:217-226. https://doi.org/10.1016/j.jfoodeng.2013.02.019
  19. Wold, J.P., A. Veberg, F. Lundby, A.N. Nilsen and J. Moan. 2005. Influence of storage time and color of light on photooxidation in cheese: A study based on sensory analysis and fluorescence spectroscopy. International dairy journal 16(10):1218-1226. https://doi.org/10.1016/j.idairyj.2005.10.023

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