Optimizing Human Health Through Effective Food Safety Measures
DOI: 10.54647/cm321206 102 Downloads 263931 Views
Author(s)
Abstract
INTRODUCTION: Food safety affects everyone worldwide. Individuals and the public can experience health problems when proper food safety measures are compromised in any country. Food production needs to be conducted safely to optimize individual and public health. Food safety entails the protection of food supply chain at all the stages involved by preventing the introduction, growth, and survival of risky chemical and microbial agents in food items. Unsafe food containing harmful micro-organisms (bacteria, viruses, parasites), or chemical substances cause more than 200 diseases. A high burden of health problems results from unsafe food procedures annually worldwide. It is preferred that safety food measures are put in place to prevent food-diseases globally among individuals and public for health security. The aim of the article is to demonstrate the food safety issues existing in the communities from available evidence, their health implications and ways to optimize the safety procedures to ensure healthy populations.
MATERIAL AND METHOD: A secondary study in the form of review of literature through online search for articles and other academic publications from credible sources was conducted. Relevant resources were identified and evidence extracted for the review.
RESULTS: Various food safety issues were recognized, including microbial food contamination, chemical food contamination, food adulteration, food additive misuse, mislabeling, genetically modified foods, and marketing of expired foods. They can affect food products at any stage in the food supply chain.
DISCUSSION: Health impact of inadequate food safety includes diseases that affect individuals and populations from insufficient food safety procedures. The health consequences were identified and means to prevent them discussed.
CONCLUSIONS: As the health impact of inadequate food measures affect individuals and populations, it is essential that all stakeholders including physicians collaborate in ensuring proper food safety measures in order to prevent and manage the menace in humans.
Keywords
Food safety measures; Food safety issues, Foodborne illness, Public health.
Cite this paper
Akeem Opeyemi AKINBODE, Basira Rabiu IDRIS,
Optimizing Human Health Through Effective Food Safety Measures
, SCIREA Journal of Clinical Medicine.
Volume 8, Issue 6, December 2023 | PP. 419-437.
10.54647/cm321206
References
[ 1 ] | Uyttendaele M, Franz E, Schlüter O. Food safety, a global challenge. Int J Environ Res Public Health. 2016;13(1):67. https://doi.org/10.3390/ ijerph13010067. |
[ 2 ] | Radovanovic R. Food safety: the global problem as a challenge for future initiatives and activities. Advances in Food Protection: Springer; 2011. p. 27- 48. |
[ 3 ] | World Health Organization (WHO). Food safety fact sheet. Available at https://www.who.int/news-room/fact-sheets/detail/food-safety. Accessed on 06 May 2023 |
[ 4 ] | Hawkes C. Uneven dietary development: linking the policies and processes of globalization with the nutrition transition, obesity and diet-related chronic diseases. Global Health. 2006;2(1):4. |
[ 5 ] | Athukorala PC, Jayasuriya S. Food safety issues, trade and WTO rules: a developing country perspective. World Econ. 2003;26(9):1395–416. |
[ 6 ] | Negri S. Food safety and global health: an international law perspective. Global Health Governance. 2009;3(1). |
[ 7 ] | Kruse H. Food safety in an international perspective. J. Verbr. Lebensm. 2015;10:105–7. https://doi.org/10.1007/s00003-015-0948-6. |
[ 8 ] | Spink J, Moyer DC. Defining the public health threat of food fraud. J Food Sc. 2011;76(9):R157–R63. |
[ 9 ] | Aung MM, Chang YS. Traceability in a food supply chain: safety and quality perspectives. Food Control. 2014;39:172–84. |
[ 10 ] | Wu F. Global impacts of aflatoxin in maize: trade and human health. World Mycotoxin J. 2014;8(2):137–42. |
[ 11 ] | Bryden WL. Mycotoxins in the food chain: human health implications. Asia Pacific J Clin Nutr. 2007;16(S1):95–101. |
[ 12 ] | Gizaw Z. Public health risks related to food safety issues in the food market: a systematic literature review. Environmental Health and Preventive Medicine 2019;24:68 https://doi.org/10.1186/s12199-019-0825-5 |
[ 13 ] | Adeyanju GT, Ishola O. Salmonella and Escherichia coli contamination of poultry meat from a processing plant and retail markets in Ibadan, Oyo State, Nigeria. Springerplus. 2014;3(1):139. |
[ 14 ] | Giammanco GM, Pepe A, Aleo A, D’Agostino V, Milone S, Mammina C. Microbiological quality of Pecorino Siciliano “primosale” cheese on retail sale in the street markets of Palermo, Italy. 2011;34(2):New Microbiologica, 179–85. |
[ 15 ] | Zhao C, Ge B, De Villena J, Sudler R, Yeh E, Zhao S, et al. Prevalence of Campylobacter spp., Escherichia coli, and Salmonella serovars in retail chicken, turkey, pork, and beef from the Greater Washington, DC, area. Appl Environ Microbiol. 2001;67(12):5431–6. |
[ 16 ] | Cárdenas C, Molina K, Heredia N, García S. Evaluation of microbial contamination of tomatoes and peppers at retail markets in Monterrey, Mexico. J Food Protect. 2013;76(8):1475–9. |
[ 17 ] | Pérez-Rodríguez F, Castro R, Posada-Izquierdo G, Valero A, Carrasco E, García-Gimeno R, et al. Evaluation of hygiene practices and microbiological quality of cooked meat products during slicing and handling at retail. Meat Science. 2010;86(2):479–85. |
[ 18 ] | Kumari S, Sarkar PK. Prevalence and characterization of Bacillus cereus group from various marketed dairy products in India. Dairy Sci Technol. 2014;94(5): 483–97. |
[ 19 ] | Vantarakis A, Affifi M, Kokkinos P, Tsibouxi M, Papapetropoulou M. Occurrence of microorganisms of public health and spoilage significance in fruit juices sold in retail markets in Greece. Anaerobe. 2011;17(6):288–91. |
[ 20 ] | Hosseini A. The prevalence of bacterial contamination of table eggs from retails markets by Salmonella spp., Listeria monocytogenes, Campylobacter jejuni and Escherichia coli in Shahrekord, Iran. Jundishapur J Microbiol 2011; 4(4):249. |
[ 21 ] | Simforian E, Nonga H, Ndabikunze B. Assessment of microbiological quality of raw fruit juice vended in Dar es Salaam City, Tanzania. Food Control. 2015;57:302–7. |
[ 22 ] | Mailafia S, God’spower Richard Okoh HO, Olabode K, Osanupin R. Isolation and identification of fungi associated with spoilt fruits vended in Gwagwalada market, Abuja, Nigeria. Veterinary World. 2017;10(4):393. |
[ 23 ] | Islam M. Study on bacteriological quality of street-vended and expired food items collected from different areas in Dhaka City. Bangladesh: East West University; 2017. |
[ 24 ] | Bai Y, Zhou L, Wang J. Organophosphorus pesticide residues in market foods in Shaanxi area, China. Food Chem. 2006;98(2):240–2. |
[ 25 ] | Othman ZAA. Lead contamination in selected foods from Riyadh City market and estimation of the daily intake. Molecules. 2010;15(10):7482–97. |
[ 26 ] | Zaied C, Abid S, Hlel W, Bacha H. Occurrence of patulin in apple-based foods largely consumed in Tunisia. Food Control. 2013;31(2):263–7. |
[ 27 ] | Schecter A, Colacino J, Haffner D, Patel K, Opel M, Päpke O, et al. Perfluorinated compounds, polychlorinated biphenyls, and organochlorine pesticide contamination in composite food samples from Dallas, Texas, USA. Environmental health perspectives. 2010;118(6):796–802. |
[ 28 ] | Onianwa P, Adeyemo A, Idowu O, Ogabiela E. Copper and zinc contents of Nigerian foods and estimates of the adult dietary intakes. Food Chem. 2001; 72(1):89–95. |
[ 29 ] | Vinci RM, Jacxsens L, De Meulenaer B, Deconink E, Matsiko E, Lachat C, et al. Occurrence of volatile organic compounds in foods from the Belgian market and dietary exposure assessment. Food Control. 2015;52:1–8. |
[ 30 ] | Tittlemier SA, Forsyth D, Breakell K, Verigin V, Ryan JJ, Hayward S. Polybrominated diphenyl ethers in retail fish and shellfish samples purchased from Canadian markets. J Agricult Food Chem. 2004;52(25):7740–5. |
[ 31 ] | Ali MH, Al-Qahtani KM. Assessment of some heavy metals in vegetables, cereals and fruits in Saudi Arabian markets. Egypt J Aquatic Res. 2012;38(1):31–7. |
[ 32 ] | Moret S, Purcaro G, Conte LS. Polycyclic aromatic hydrocarbons (PAHs) levels in propolis and propolis-based dietary supplements from the Italian market. Food Chem. 2010;122(1):333–8. |
[ 33 ] | Ali ANMA. Food safety and public health issues in Bangladesh: a regulatory concern. Eur Food Feed Law Rev. 2013:31–40. |
[ 34 ] | Bansal S, Singh A, Mangal M, Mangal AK, Kumar S. Food adulteration: Sources, health risks, and detection methods. Crit Rev Food Sci Nutr. 2017; 57(6):1174–89. |
[ 35 ] | Nasreen S, Ahmed T. Food adulteration and consumer awareness in Dhaka City, 1995-2011. Journal of health, population, and nutrition. 2014;32(3):452. |
[ 36 ] | Chanda T, Debnath G, Hossain M, Islam M, Begum M. Adulteration of raw milk in the rural areas of Barisal district of Bangladesh. Bangladesh J Anim Science. 2012;41(2):112–5. |
[ 37 ] | Singuluri H, Sukumaran M. Milk adulteration in Hyderabad, India-a comparative study on the levels of different adulterants present in milk. J Chromatogr Sep Techn. 2014;5(1):1. |
[ 38 ] | Barham GS, Khaskheli M, Soomro AH, Nizamani ZA. Extent of extraneous water and detection of various adulterants in market milk at Mirpurkhas, Pakistan. J Agri Vet Sci. 2014;7(3):83–9. |
[ 39 ] | Waghray K, Gulla S, Thyagarajan P, Vinod G. Adulteration pattern in different food products sold in the twin cities of Hyderabad and Secunderabad-India. Journal of Dairying Foods & Home Sciences. 2011;30(2). |
[ 40 ] | Peng G-J, Chang M-H, Fang M, Liao C-D, Tsai C-F, Tseng S-H, et al. Incidents of major food adulteration in Taiwan between 2011 and 2015. Food Control. 2017;72:145–52. |
[ 41 ] | Woldemariam HW, Abera BD. The extent of adulteration of selected foods at Bahir Dar, Ethiopia. Int J Interdisciplin Res. 2014;1(6):1–6. |
[ 42 ] | Assefa A, Teka F, Guta M, Melaku D, Naser E, Tesfaye B, et al. Laboratory investigation of epidemic dropsy in Addis Ababa, Ethiopia. Ethiop Med J. 2013:21–32. |
[ 43 ] | Carocho M et al. Adding molecules to food, pros and cons: A review on synthetic and natural food additives. Comprehensive Reviews in Food Science and Food Safety. 2014;13(4):377-379. |
[ 44 ] | Inetianbor JE, Yakubu BM, Ezeonu SC. Effects of food additives and preservatives on man – a review. Asian Journal of Science and Technology. 2015;6(2):1118-1135. |
[ 45 ] | Dixit S, Purshottam S, Khanna S, Das M. Usage pattern of synthetic food colours in different states of India and exposure assessment through commodities preferentially consumed by children. Food Addit Contam Part A Chem Anal Control Expo Risk Assess. 2011;28(8):996–1005. |
[ 46 ] | Stevens LJ, Burgess JR, Stochelski MA, Kuczek T. Amounts of artificial food colors in commonly consumed beverages and potential behavioral implications for consumption in children. Clin Pediatr. 2014;53(2):133–40. |
[ 47 ] | Tsai C-F, Kuo C-H, Shih DY-C. Determination of 20 synthetic dyes in chili powders and syrup-preserved fruits by liquid chromatography/tandem mass spectrometry. J Food Drug Anal. 2015;23(3):453–62. |
[ 48 ] | Moradi-Khatoonabadi Z, Amirpour M, AkbariAzam M. Synthetic food colours in saffron solutions, saffron rice and saffron chicken from restaurants in Tehran, Iran. Food Additives Contaminants: Part B. 2015;8(1):12–7. |
[ 49 ] | Saleem N, Umar ZN. Survey on the use of synthetic food colors in food samples procured from different educational institutes of Karachi City. J Trop Life Sci. 2013;3(1):1–7. |
[ 50 ] | Petigara Harp B, Miranda-Bermudez E, Barrows JN. Determination of seven certified color additives in food products using liquid chromatography. J Agricul Food Chem. 2013;61(15):3726– |
[ 51 ] | Sood M. The supervision of government on implementation of import of processed food products in effort of legal protection for consumers. JL Pol’y & Globalization. 2014;25:72 |
[ 52 ] | Miller DD, Mariani S. Smoke, mirrors, and mislabeled cod: poor transparency in the European seafood industry. Front Ecol Environ. 2010;8(10):517–21. |
[ 53 ] | Jacquet JL, Pauly D. Trade secrets: renaming and mislabeling of seafood. Marine Policy. 2008;32(3):309–18. |
[ 54 ] | Chin TC, Adibah A, Hariz ZD, Azizah MS. Detection of mislabelled seafood products in Malaysia by DNA barcoding: improving transparency in food market. Food Control. 2016;64:247–56. |
[ 55 ] | Nagalakshmi K, Annam P-K, Venkateshwarlu G, Pathakota G-B, Lakra WS. Mislabeling in Indian seafood: an investigation using DNA barcoding. Food Control. 2016;59:196–200. |
[ 56 ] | Galal-Khallaf A, Ardura A, Mohammed-Geba K, Borrell YJ, Garcia-Vazquez E. DNA barcoding reveals a high level of mislabeling in Egyptian fish fillets. Food Control. 2014;46:441–5. |
[ 57 ] | Cawthorn D-M, Steinman HA, Witthuhn RC. DNA barcoding reveals a high incidence of fish species misrepresentation and substitution on the South African market. Food Res Int. 2012;46(1):30–40. |
[ 58 ] | Di Pinto A, Bottaro M, Bonerba E, Bozzo G, Ceci E, Marchetti P, et al. Occurrence of mislabeling in meat products using DNA-based assay. J Food Sci Technol. 2015;52(4):2479–84. |
[ 59 ] | Carvalho DC, Palhares RM, Drummond MG, Gadanho M. Food metagenomics: next generation sequencing identifies species mixtures and mislabeling within highly processed cod products. Food Control. 2017;80:183–6. |
[ 60 ] | Garcia-Vazquez E, Perez J, Martinez JL, Pardinas AF, Lopez B, Karaiskou N, et al. High level of mislabeling in Spanish and Greek hake markets suggests the fraudulent introduction of African species. J Agric Food Chemistry. 2010; 59(2):475–80. |
[ 61 ] | Staffen CF, Staffen MD, Becker ML, Löfgren SE, Muniz YCN, de Freitas RHA, et al. DNA barcoding reveals the mislabeling of fish in a popular tourist destination in Brazil. PeerJ. 2017;5:e4006. |
[ 62 ] | Muñoz-Colmenero M, Juanes F, Dopico E, Martinez JL, Garcia-Vazquez E. Economy matters: a study of mislabeling in salmon products from two regions, Alaska and Canada (Northwest of America) and Asturias (Northwest of Spain). Fisheries Res. 2017;195:180–5. |
[ 63 ] | Muñoz-Colmenero M, Blanco O, Arias V, Martinez JL, Garcia-Vazquez E. DNA authentication of fish products reveals mislabeling associated with seafood processing. Fisheries. 2016;41(3):128–38. |
[ 64 ] | Bosko SA, Foley DM, Hellberg RS. Species substitution and country of origin mislabeling of catfish products on the US commercial market. Aquaculture. 2018;495:715–20. |
[ 65 ] | Christiansen H, Fournier N, Hellemans B, Volckaert FA. Seafood substitution and mislabeling in Brussels' restaurants and canteens. Food Control. 2018; 85:66–75. |
[ 66 ] | Christiansen H, Fournier N, Hellemans B, Volckaert FA. Seafood substitution and mislabeling in Brussels' restaurants and canteens. Food Control. 2018; 85:66–75. |
[ 67 ] | Galal-Khallaf A, Ardura A, Borrell YJ, Garcia-Vazquez E. PCR-based assessment of shellfish traceability and sustainability in international Mediterranean seafood markets. Food Chemistry. 2016;202:302–8. |
[ 68 ] | Swanson NL, Leu A, Abrahamson J, Wallet B. Genetically engineered crops, glyphosate and the deterioration of health in the United States of America. J Organ Syst. 2014;9(2):6–37. |
[ 69 ] | Pattron DD. A survey of genetically modified foods consumed, health implications and recommendations for public health food safety in Trinidad. Internet J Food Safety. 2005;7:4–14 |
[ 70 ] | Bakshi A. Potential adverse health effects of genetically modified crops. J Toxicol Environ Health Part B. 2003;6(3):211–25. |
[ 71 ] | Aris A, Leblanc S. Maternal and fetal exposure to pesticides associated to genetically modified foods in Eastern Townships of Quebec, Canada. Reprod Toxicol. 2011;31(4):528–33. |
[ 72 ] | Bawa AS, Anilakumar KR. Genetically modified foods: safety, risks and public concerns – a review. J Food Sci Technol 2013;50(6):1035-1046. |
[ 73 ] | Karalis DT, Karalis T, Kralis S, Kleisiari AS. Genetically Modified Products, Perspectives and Challenges. Cureus 2020;12(3):e7306. |
[ 74 ] | Rhodehamel E.J. Overview of biological, chemical, and physical hazards. In: Pierson M.D., Corlett D.A. (eds) HACCP. Springer, Boston, MA, 1992. DOI https://doi.org/10.1007/978-1-4684-8818-0_3 |
[ 75 ] | Aruoma OI. The impact of food regulation on the food supply chain. Toxicology. 2006;221(1):119–27. |
[ 76 ] | Horchner PM, Brett D, Gormley B, Jenson I, Pointon AM. HACCP-based approach to the derivation of an on-farm food safety program for the Australian red meat industry. Food Control. 2006;17(7):497–510. |
[ 77 ] | Sun Y-M, Ockerman H. A review of the needs and current applications of hazard analysis and critical control point (HACCP) system in foodservice areas. Food Control. 2005;16(4):325–32. |
[ 78 ] | Kleter G, Prandini A, Filippi L, Marvin H. Identification of potentially emerging food safety issues by analysis of reports published by the European Community’s Rapid Alert System for Food and Feed (RASFF) during a four-year period. Food Chem Toxicol. 2009;47(5):932–50. |
[ 79 ] | Ahl A, Buntain B. Risk and the food safety chain: animal health, public health and the environment. Revue Scientifique et Technique-Office International des Epizooties. 1997;16(2):322–30. |
[ 80 ] | Scheule B, Sneed J. From farm to fork: critical control points for food safety. J Nutr Recipe Menu Dev. 2001;3(2):3–23. |
[ 81 ] | Bagumire A, Todd EC, Nasinyama GW, Muyanja C, Rumbeiha WK, Harris C, et al. Potential sources of food hazards in emerging commercial aquaculture industry in sub-Saharan Africa: a case study for Uganda. Int J Food Sci Technol. 2009;44(9):1677–87. |
[ 82 ] | Frewer LJ, Scholderer J, Bredahl L. Communicating about the risks and benefits of genetically modified foods: the mediating role of trust. Risk Anal. 2003;23(6):1117–33. |
[ 83 ] | Albert I, Grenier E, Denis JB, Rousseau J. Quantitative risk assessment from farm to fork and beyond: a global Bayesian approach concerning foodborne diseases. Risk Anal. 2008;28(2):557–71. |
[ 84 ] | Khairuzzaman M, Chowdhury FM, Zaman S, Al Mamun A, Bari M. Food safety challenges towards safe, healthy, and nutritious street foods in Bangladesh. Int J Food Sci. 2014;2014. |
[ 85 ] | Baluka SA, Miller R, Kaneene JB. Hygiene practices and food contamination in managed food service facilities in Uganda. African J Food Sci. 2015;9(1):31–42. |
[ 86 ] | Dharod JM, Paciello S, Bermúdez-Millán A, Venkitanarayanan K, Damio G, Pérez-Escamilla R. Bacterial contamination of hands increases risk of crosscontamination among low-income Puerto Rican meal preparers. J Nutr Educ Behav. 2009;41(6):389–97. |
[ 87 ] | Paudyal N, Anihouvi V, Hounhouigan J, Matsheka MI, Sekwati-Monang B, AmoaAwua W, et al. Prevalence of foodborne pathogens in food from selected African countries–a meta-analysis. IntJ Food Microbiol. 2017;249:35–43. |
[ 88 ] | Henson S, Jaffee S. Food safety standards and trade: enhancing competitiveness and avoiding exclusion of developing countries. Eur J Dev Res. 2006;18(4):593–621. |
[ 89 ] | Henson S, Jaffee S. Understanding developing country strategic responses to the enhancement of food safety standards. World Econ. 2008;31(4):548–68. |
[ 90 ] | Grace D. Food safety in low and middle income countries. Int J Environ Res Public Health. 2015;12(9):10490–507. |
[ 91 ] | Villanueva CM, Kogevinas M, Cordier S, Templeton MR, Vermeulen R, Nuckols JR, et al. Assessing exposure and health consequences of chemicals in drinking water: current state of knowledge and research needs. Environ Health Perspect. 2014;122(3):213–21. |
[ 92 ] | Rather IA, Koh WY, Paek WK, Lim J. The sources of chemical contaminants in food and their health implications. Front Pharmacol. 2017;8:830. |
[ 93 ] | Lawal B. Overview of the socioeconomic implications and management of product faking and adulteration. Greener J Bus Manag Stud. 2013;3(3):119–31. |
[ 94 ] | Ayza A, Belete E. Food adulteration: its challenges and impacts. Food Sci Qual Manag. 2015;41:50–6. |
[ 95 ] | Salih MAM, Yang S. Common milk adulteration in developing countries cases study in China and Sudan: a review. J Adv Dairy Res. 2017;5:192. |
[ 96 ] | Podolak R, Enache E, Stone W, Black DG, Elliott PH. Sources and risk factors for contamination, survival, persistence, and heat resistance of Salmonella in low-moisture foods. J Food Protect. 2010;73(10):1919–36. |
[ 97 ] | Nicolas B, Razack BA, Yollande I, Aly S, Tidiane OCA, Philippe NA, et al. Streetvended foods improvement: contamination mechanisms and application of food safety objective strategy: critical review. Pakistan J Nutri. 2007;6(1):1–10. |
[ 98 ] | Legnani P, Leoni E, Berveglieri M, Mirolo G, Alvaro N. Hygienic control of mass catering establishments, microbiological monitoring of food and equipment. Food Control. 2004;15(3):205–11. |
[ 99 ] | Sousa CPd. The impact of food manufacturing practices on food borne diseases. Brazilian Arch Biol Technology. 2008;51(4):615-623. |
[ 100 ] | Carrasco E, Morales-Rueda A, García-Gimeno RM. Cross-contamination and recontamination by Salmonella in foods: a review. Food Res Int. 2012;45(2): 545–56. |
[ 101 ] | Lyhs U, Korkeala H, Björkroth J. Identification of lactic acid bacteria from spoiled, vacuum-packaged ‘gravad’rainbow trout using ribotyping. Int J Food Microbiol. 2002;72(1-2):147–53. |
[ 102 ] | Rossi F, Gaio E, Torriani S. Staphylococcus aureus and Zygosaccharomyces bailii as primary microbial contaminants of a spoiled herbal food supplement and evaluation of their survival during shelf life. Food Microbiol. 2010;27(3):356–62. |
[ 103 ] | Lyhs U, Björkroth JK. Lactobacillus sakei/curvatus is the prevailing lactic acid bacterium group in spoiled maatjes herring. Food Microbiol. 2008;25(3):529–33. |
[ 104 ] | Hoffmann S, Scallan E. Epidemiology, cost, and risk analysis of foodborne disease. Foodborne Diseases, 3rd ediciton: Elsevier; 2017. p. 31-63. DOI: https://doi.org/10.1016/B978-0-12-385007-2.00002-4. |
[ 105 ] | De Bon H, Parrot L, Moustier P. Sustainable urban agriculture in developing countries. A review. Agronomy Sustain Dev. 2010;30(1):21–32. |
[ 106 ] | Abdulkadir A, Dossa L, Lompo D-P, Abdu N, Van Keulen H. Characterization of urban and peri-urban agroecosystems in three West African cities. Int J Agric Sustain. 2012;10(4):289–314. |
[ 107 ] | Atidégla SC, Huat J, Agbossou EK, Saint-Macary H, Glèlè KR. Vegetable contamination by the fecal bacteria of poultry manure: case study of gardening sites in southern Benin. Int J Food Sci. 2016;2016. |
[ 108 ] | Man SM. The clinical importance of emerging Campylobacter species. Nat Rev Gastroenterol Hepatol. 2011;8(12):669–85. |
[ 109 ] | Collignon P. Superbugs in food: a severe public health concern. Lancet 2013;13:641e3. |
[ 110 ] | Devaraj NK, Weissleder R. Biomedical applications of tetrazine cycloadditions. Acc Chem Res 2011;44:816e27. |
[ 111 ] | Mangal M, Sangita B, Satish SK, Ram GK. Molecular detection of foodborne pathogens: a rapid and accurate answer to food safety. Crit Rev Food Sci Nutr 2016;56:1568e84. |
[ 112 ] | Huang JY, Henao OL, Griffin PM, Vugia DJ, Cronquist AB, Hurd S, et al. Infection with pathogens transmitted Commonly through food and the effect of increasing use of culture-independent diagnostic tests on surveillance d foodborne diseases active surveillance network, 10 U.S. Sites, 2012e2015. MMWR Morb Mortal Wkly Rep 2016;65:368e71. |
[ 113 ] | Fung F, Wang H, Menon S. Food safety in the 21st century. Bio Med J 2018;41:88-95. |
[ 114 ] | Yang P, Hash S, Park K, Wong C, Doraisamy L, Petterson J, et al. Application of nuclear magnetic resonance to detect toxigenic Clostridium difficile from stool specimens: a proof of concept. J Mol Diagn 2017;19:230e5. |
[ 115 ] | Yang P, Wong C, Hash S, Fung F, Menon S. Rapid detection of Salmonella spp using magnetic resonance. J Food Saf 2018;e12473. |
[ 116 ] | Ferguson BA. Look at the microbiology testing market. Food Safety Magazine; February/March 2017. https://www.foodsafetymagazine.com/magazine-archive1/februarymarch-2017/a-look-at-the-microbiology-testingmarket/. [Accessed 15 May 2023]. |
[ 117 ] | Yen TH, Lin-Tan DT, Lin JL. Food safety involving ingestion of foods and beverages prepared with phthalate-plasticizer |
[ 118 ] | Billy TJ, Wachsmuth IK. Hazard analysis and critical control point systems in the United States Department of Agriculture regulatory policy. Rev Sci Tech 1997;16:342e8. |