Bacterial Community Assessed by Utilization of Single Carbon Sources in Broiler Ground Meat after Treatment with an Antioxidant, Carnosine, and Cold Plasma

Contaminated poultry meat is a major source of human foodborne illnesses. Many interventions have been developed to reduce and/or eliminate human foodborne pathogens in poultry products; however, treatments with cold plasma or carnosine or their combination have not been extensively investigated. In...

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Veröffentlicht in:	Journal of food protection 2020-11, Vol.83 (11), p.1967-1973
Hauptverfasser:	Yeh, Hung-Yueh, Line, John E, Hinton, Arthur, Gao, Yue, Zhuang, Hong
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Antioxidants Asymptotes Bacteria Carbon Carbon sources Carnosine Chemicals Chickens Cold Cold plasmas Electrodes Flora Food Food contamination Food safety Food sources Foodborne diseases Glycerol Growth kinetics Growth models Humans Kinetics Lactose Malic acid Meat Meat - analysis Meat products Microflora Microorganisms Optical density p-Hydroxybenzoic acid Pathogens Phenethylamine Phenylethylamine Plasma Plasma Gases Poultry Preservatives Principal components analysis Shelf life Software packages Stationary phase Statistical analysis
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container_end_page	1973
container_issue	11
container_start_page	1967
container_title	Journal of food protection
container_volume	83
creator	Yeh, Hung-Yueh Line, John E Hinton, Arthur Gao, Yue Zhuang, Hong
description	Contaminated poultry meat is a major source of human foodborne illnesses. Many interventions have been developed to reduce and/or eliminate human foodborne pathogens in poultry products; however, treatments with cold plasma or carnosine or their combination have not been extensively investigated. In this study, the bacterial microflora of poultry meat samples after treatments with cold plasma and carnosine were characterized with EcoPlates in the OmniLog system. The plates were incubated at 25°C for 7 days in the OmniLog chamber, and bacterial growth was monitored by recording formazan production every 30 min at an optical density of 590 nm. The kinetics of lag, log, and stationary phases of bacterial growth followed the Gompertz sigmoidal model but with different inflection times and asymptotes at the log phase and the stationary phase, respectively. Results indicated that treatment of poultry meat samples with cold plasma technology and carnosine could inhibit growth of the bacteria in the treated meat samples. Of 31 chemicals tested, phenylethylamine, α-d-lactose, d,l-α-glycerol phosphate, 2-hydroxybenzoic acid, γ-hydroxybutyric acid, α-ketobutyric acid, and d-malic acid could not be metabolized by bacteria in the meat samples. Future research is required to determine whether these seven chemicals that inhibited growth of bacteria in these meat samples can be used as food preservatives for extending the shelf life of these products. Whether the bacterial flora can be an indicator of effectiveness for meat samples treated with cold plasma, carnosine, or both needs further study.
doi_str_mv	10.4315/JFP-20-063
format	Article
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subjects	Animals Antioxidants Asymptotes Bacteria Carbon Carbon sources Carnosine Chemicals Chickens Cold Cold plasmas Electrodes Flora Food Food contamination Food safety Food sources Foodborne diseases Glycerol Growth kinetics Growth models Humans Kinetics Lactose Malic acid Meat Meat - analysis Meat products Microflora Microorganisms Optical density p-Hydroxybenzoic acid Pathogens Phenethylamine Phenylethylamine Plasma Plasma Gases Poultry Preservatives Principal components analysis Shelf life Software packages Stationary phase Statistical analysis
title	Bacterial Community Assessed by Utilization of Single Carbon Sources in Broiler Ground Meat after Treatment with an Antioxidant, Carnosine, and Cold Plasma
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