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References
Acuff GR, Vanderzant C, Savell JW, Jones DK, Griffin DB, Ehlers JG (1987). Effect of acid decontamination of beef subprimal cuts on the microbiological and sensory characteristics of steaks. Meat Science 19(3):217-226. |
|
Awwad NS, El-Nadi YA, Hamed MM (2013). Successive processes for purification and extraction of phosphoric acid produced by wet process. Chemical Engineering and Processing Process Intensification 74:69-74. |
|
Ba HV, Seo HW, Seong PN, Kim YS, Park BY, Moon SS, Kang SJ, Choi YM, Kim JH (2018). The effects of pre-and post-slaughter spray application with organic acids on microbial population reductions on beef carcasses. Meat Science 137:16-23. |
|
Bracket RE, Hao YY, Doyle MP (1994). Ineffectiveness of hot acid sprays to decontaminate E. coli O157:H7 on beef. Journal of Food Protection 57(3):198-203. |
|
Brenneman KE, Willingham C, Kong W, Curtiss R, Roland KL (2013) low-pH rescue of acid-sensitive Salmonella enterica serovar typhi strain by a rhamnose-regulated arginine decarboxylase system. Journal of Bacteriology 195(13):3062-3072. |
|
Buchanan RL, Golden MH (1994). Interaction of citric acid concentration and pH on the kinetics of Listeria monocytogenes inactivation. Journal of Food Protection 57(7):567-570. |
|
Carpenter CE, Broadbent JR (2009). External concentration of organic acid anions and pH: key independent variables for studying how organic acids inhibit growth of bacteria in mildly acidic foods. Journal of Food Science 74(1):R12-15. |
|
Chaiyakosa S, Charernjiratragul W, Umsakul K, Vuddhakul V (2007). Comparing the efficiency of chitosan with chlorine for reducing Vibrio parahaemolyticus in shrimp. Food Control 18(9):1031-1035. |
|
Chauret CP (2014). Sanitization. Encyclopedia of Food Microbiology (2ed) pp. 360-364. |
|
Chien PJ, Sheu F, Lin HR (2007). Coating citrus (Murcott tangor) fruit with low molecular weight chitosan increases postharvest quality and shelf life. Food Chemistry 100(3):1160-1164. |
|
Chung YC, Wang HL, Chen YM, Li SL (2003). Effect of abiotic factors on the antibacterial activity of chitosan against waterborne pathogens. Bioresource Technology 88(3):179-184. |
|
Coma V, Deschamps A, Martial-Gros A (2003). Bioactive packaging materials from edible chitosan polymer antimicrobial activity assessment on dairy related contaminants. Journal of Food Science 68(9):2788-2792. |
|
Dan SM, Mihaiu M, Rotaru O, Dalea I (2007). Microbial changes on the surface of pork carcasses due lactic and acetic acids decontamination. USAMV-CN 64(1-2):403-408. |
|
Dorsa WJ, Siragusa GR, Cutter CN, Berry ED, Koohmaraie M (1997). Efficacy of using a sponge sampling method to recover low levels of Escherichia coli O157:H7, Salmonella typhimurium, and aerobic bacteria from beef carcass surface tissue. Food Microbiology 14(1):63-69. |
|
Dubal ZB, Paturkar AM, Waskar VS, Zende RJ, Latha C, Rawool DB, Kadam MM (2004). Effect of grade organic acids on inoculated S. aureus, L. monocytogenes, E. coli and S. typhimurium in sheep/goat meat stored at refrigeration temperature. Meat Science 66(4):817-821. |
|
FDA (2003). Code of federal regulations title 21. Government Printing Office, USA.
|
|
Garbutt J (1997). Essentials of food microbiology. Hodder Headline Group, London UK pp. 135-174. |
|
Gonzalez-Garcia RA, McCubbin T, Navone L, Stowers C, Nielsen LK, Marcellin E (2017). Microbial propionic acid production. Fermentation 3(2):21. |
|
Haque MN, Chowdhury R, Islam KMS, Akbar MA (2009). Propionic acid is an alternative to antibiotics in poultry diet. Bangladesh Journal of Animal Science 38(1-2):115-122. |
|
Harris D, Brashears MM, Garmyn AJ, Brooks JC, Miller MF (2012). Microbiological and organoleptic characteristics of beef trim and ground beef treated with acetic acid, lactic acid, acidified sodium chlorite, or sterile water in simulated commercial processing environment to reduce Escherichia coli O157:H7 and Salmonella. Meat Science 90(3):783-788. |
|
Helander IM, Nurmiaho-Lassila EL, Ahvenainen R, Rhoades J, Roller S (2001). Chitosan disrupts the barrier properties of the outer membrane of Gram-negative bacteria. International Journal of Food Microbiology 71(2-3):235-244. |
|
Hong KN, Park NY, Lee SH, Meyers SP (2002). Antibacterial activity of chitosan and chitosan oligomers with different molecular weights. International Journal of Food Microbiology 74(1-2):65-72. |
|
Hongpattarakere T, Riyaphan O (2008). Effect of deacetylation conditions on antimicrobial activity of chitosans prepared from carapace of black tiger shrimp (Penaeus monodon). Songklanakarin Journal of Science and Technology 30:1-9. |
|
Jiang Y, Li Y (2001). Effect of chitosan coating on postharvest life and quality of longan fruit. Food Chemistry 73(2):139-143. |
|
Kandil AT, Mira HI, Taha MH, Kamel MF (2017). Production of pure phosphoric acid from El-Sebaeya low-grade phosphate ore. Separation Science and Technology 52(4):679-690. |
|
Kahya N (2019). Water soluble chitosan derivatives and their biological activities: a review. Polymer Sciences 5(3):1-11. |
|
Kanatt SR, Chander R, Arun S (2008). Chitosan glucose complex - A novel food preservative. Food Chemistry 106(2):521-528. |
|
Laury AM, Alvarado MV, Nace G, Alvarado CZ, Brook JC, Echeverry A, Brashears MM (2009). Validation of a lactic acid- and citric acid-based antimicrobial product for chicken carcass. Journal of Food Protection 72(10):2208-2211. |
|
Lipnizki F (2010). Basic Aspects and Applications of Membrane Processes in Agro-Food and Bulk Biotech Industries. Comprehensive Membrane Science and Engineering pp. 165-194. |
|
Liu H, Du YM, Wang XH, Sun LP (2004). Chitosan kills bacteria through cell membrane damage. International Journal of Food Microbiology 95(2):147-155. |
|
Liu X, Yun L, Dong Z, Zhi L, Kang D (2001). Antibacterial action of chitosan and carboxymethylated chitosan. Journal of Applied Polymer Science 79(7):1324-1335. |
|
Lucera A, Costa C, Conte A, Del Nobile MA (2012). Food applications of natural antimicrobial compounds. Frontiers in Microbiology 3(287):1-13. |
|
Mani-López E, García HS, López-Malo A (2012). Organic acids as antimicrobials to control Salmonella in meat and poultry products. Food Research International 45:713-721. |
|
Nguyen DH, Seok WJ, Kim IH (2020). Organic acids mixtures as a dietary additive for pigs-a review. Animals 10(952):1-12. |
|
Pilar HM, Eva A, Valeria DV, Dinoraz V, Rafael G (2008). Effect of chitosan coating combined with postharvest calcium treatment on strawberry (Fragaria ananassa) quality during refrigerated storage. Food Chemistry 110:428-435. |
|
Raftari M, Jalilian FA, Abdulamir AS, Son R, Sekawi Z, Fatimah AB (2009). Effect of organic acids on Escherichia coli O157:H7 and Staphylococcus aureus contaminated meat. The Open Microbiology Journal 3:121-127. |
|
Roller S, Sagooa S, Boarda R, O'Mahonyb T, Capliceb E, Fitzgeraldb G, Fogdenc M, Owenc M, Fletcherc H (2002). Novel combinations of chitosan, carnocin and sulphite for the preservation of chilled pork sausages. Meat Science 62:165-177. |
|
Sagoo S, Board R, Roller S (2002). Chitosan inhibits growth of spoilage micro-organisms in chilled pork products. Food Microbiology 19:175-182. |
|
Sallam KI, Abd-Elghany SM, Hussein MA, Imre K, Morar A, Morshdy AE, Sayed-Ahmed MZ (2020). Microbial decontamination of beef carcass surfaces by lactic acid, acetic acid, and trisodium phosphate sprays. BioMed Research International 2324358:1-11. |
|
SkÅ™ivanová E, Marounek M (2007). Influence of pH on antimicrobial activity of organic acids against rabbit enteropathogenic strain of Escherichia coli. Folia Microbiology 52(1):70-72. |
|
Smulders FJM, Greer GG (1998). Integrating microbial decontamination with organic acids in HACCP programs for muscle foods: prospects and controversies. International Journal of Food Microbiology 44(3):149-169. |
|
Sohaib M, Anjum FM, Arshad MS, Rahman UU (2016). Postharvest intervention technologies for safety enhancement of meat and meat based on products; a critical review. Journal of Food Science and Technology 53(1):19-30. |
|
Stivarius MR, Pohlman FW, McElyea KS, Waldroup AL (2002). Effects of hot water and lactic acid treatment of beef trimmings prior to grinding on microbial, instrumental color and sensory properties of ground beef during display. Meat Science 60(4):327-334. |
|
Sudarshan NR, Hoover DG, Knorr D (1992). Antibacterial action of chitosan. Food Biotechnology 6(3):257-272. |
|
Tepe B, Daferera D, Sokmen M, Polissiou M, Sokmen A (2004). In vitro antimicrobial and antioxidant activities of the essential oils and various extracts of Thymus eigii M. Zohary et PH Davis. Journal of agricultural and food chemistry 52(5):1132-1137. |
|
Wang GH (1992). Inhibition and inactivation of five species of foodborne pathogens by chitosan. Journal of Food Protection 55(11):916-919. |
|
Wang L, Liu F, Jiang Y, Chai Z, Li P, Cheng Y, Jing H, Leng X (2011). Synergistic antimicrobial activities of natural essential oils with chitosan films. Journal of agricultural and food chemistry, 59(23):12411-12419. |
|
Wee YJ, Kim JN, Ryu HW (2006). Biotechnological production of lactic acid and its recent applications. Food Technology and Biotechnology 44(2):1-11. |
|
Wu XY, Zeng QX, Mo SF, Ruan Z (2006). Antibacterial activities of chitosan with different degree of deacetylation and molecular masses. Journal of South China University Technology 34:58-62. |
|
Xiong X, Hirata M, Takanashi H, Lee MG, Hano T (1998). Analysis of acclimation behavior against nitrification inhibitors in activated sludge processes. Journal of Fermentation and Bioengineering 86(2):207-214. |
|
Yang ZP, Li YB, Slavik M (1998). Use of antimicrobial spray applied with an inside-outside birdwasher to reduce bacterial contamination on prechilled chicken carcasses. Journal of Food Protection 61(7):829-832. |
|
Yu G, Huang GH, Zhang XD, Li Y (2010). Inhibitory effects of organic acids on bacteria growth during food waste composting. Compost Science & Utilization 18(1):55-63. |
|
Zheng LY, Zhu JF (2003). Study on antimicrobial activity of chitosan with different molecular weights. Carbohydrate Polymers 54(4):527-530. |
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