Antimicrobial Efficacy of Postbiotics of Lactic Acid Bacteria and their Effects on Food Safety and Shelf Life of Chicken Meat

Anang D.M., Rusul G., Bakar J., Ling F.H. (2007). Effects of lactic acid and lauricidin on the survival of Listeria monocytogenes, Salmonella Enteritidis and Escherichia coli O157:H7 in chicken breast stored at 4°C. Food Control, 18: 961–969. Search in Google Scholar

Balthazar C.F., Guimarães J.F., Coutinho N.M., Pimentel T.C., Ranadheera C.S., Santillo A., Albenzio M., Cruz A.G., Sant’Ana A.S. (2022). The future of functional food: Emerging technologies application on prebiotics, probiotics and postbiotics. Compr. Rev. Food Sci. Food Saf., 21: 2560–2586. Search in Google Scholar

Barros C.P., Guimarães J.T., Esmerino E.A., Duarte M.C.K.H., Silva M.C., Silva R., Ferreira B.M., Sant’Ana A.S., Freitas M.Q., Cruz A.G. (2020). Paraprobiotics and postbiotics: Concepts and potential applications in dairy products. Curr. Opin. Food Sci., 32: 1–8. Search in Google Scholar

Bhoir S.A., Jhaveri M., Chawla S.P. (2019). Evaluation and predictive modeling of the effect of chitosan and gamma irradiation on quality of stored chilled chicken meat. J. Food Process. Eng., 42: 13254. Search in Google Scholar

Buchanan R.L., Golden M.H., Whiting R.C. (1993). Differentiation of the effects of pH and lactic or acetic acid concentration on the kinetics of Listeria monocytogenes inactivation. J. Food Prot., 56: 474–478. Search in Google Scholar

Cosansu S., Ayhan K. (2012). Effects of lactic and acetic acid on survival of Salmonella Enteritidis during refrigerated and frozen storage of chicken meats. Food Bioproc. Tech., 5: 372–377. Search in Google Scholar

Cuevas-González P.F., Liceaga A.M., Aguilar-Toalá J.E. (2020). Post-biotics and paraprobiotics: From concepts to applications. Food Res. Int., 136: 109502. Search in Google Scholar

Edris A., Amin R., Eleiwa N., Elnagar R. (2020). Lactic and acetic acids as bacterial decontaminators on chicken carcasses. Benha Med. J., 39: 158–60. Search in Google Scholar

Godoy C.L.A., Costa L.M., Guerra C.A., Oliveira V.S., Paula B.P., Lemos Junior W.J.F., Silva V.D., Luchese R.H., Bautitz I.R., Guerra A.F. (2022). Potentially postbiotic-containing preservative to extend the use-by date of raw chicken sausages and semifinished chicken products. Sustainability, 14: 2646. Search in Google Scholar

Gunkova P.I., Buchilina A.S., Maksimiuk N.N., Bazarnova Y.G., Girel K.S. (2021). Carbohydrate fermentation test of lactic acid starter cultures. IOP Conference Series, Earth Environ. Sci., 852: 012035. Search in Google Scholar

Habeeb G.A., Durmuşoğlu H., İlhak O.İ. (2021). The combined effect of sodium lactate, lactic acid and acetic acid on the survival of Salmonella spp. and the microbiota of chicken drumsticks. Slov. Vet. Res., 58: 47–54. Search in Google Scholar

Hayek S.A., Gyawali R., Aljaloud S.O., Krastanov A., Ibrahim S.A. (2019). Cultivation media for lactic acid bacteria used in dairy products. J. Dairy Res., 86: 490–502. Search in Google Scholar

İlhak O.İ., İncili G.K., Durmuşoğlu H. (2017). Evaluation of effect of thymol combined with lactic acid or sodium lactate on psychrophilic bacteria and Salmonella spp. on chicken drumstick. Ann. Anim. Sci., 17: 271–280. Search in Google Scholar

İlhak O.İ., İncili G.K., Durmuşoğlu H. (2018). Effect of some chemical decontaminants on the survival of Listeria monocytogenes and Salmonella Typhimurium with different attachment times on chicken drumstick and breast meat. J. Food Sci. Technol., 55: 3093–3097. Search in Google Scholar

İncili G.K., Akgöl M., Aydemir M.E., Alan S., Mutlu M., İlhak O.İ., Öksüztepe G. (2020). Fate of Listeria monocytogenes and Salmonella Typhimurium in homemade marinade and on marinated chicken drumsticks, wings and breast meat. LWT – Food Sci. Technol., 134: 110231. Search in Google Scholar

İncili G.K., Karatepe P., Akgöl M., Kaya B., Kanmaz H., Hayaloğlu A.A. (2021). Characterization of Pediococcus acidilactici postbiotic and impact of postbiotic-fortified chitosan coating on the microbial and chemical quality of chicken breast fillets. Int. J. Biol. Macromol., 184: 429–437. Search in Google Scholar

İncili G.K., Karatepe P., Akgöl M., Güngören A., Koluman A., İlhak O.İ., Kanmaz H., Kaya B., Hayaloğlu A.A. (2022). Characterization of lactic acid bacteria postbiotics, evaluation in-vitro antibacterial effect, microbial and chemical quality on chicken drum-sticks. Food Microbiology, 104: 104001. Search in Google Scholar

İncili G.K., Akgöl M., Karatepe P., Tekin A., Kanmaz H., Kaya B., Hayaloğlu A.A. (2023). Whole-cell postbiotics: An innovative approach for extending the shelf life and controlling major food-borne pathogens in chicken breast fillets. Food Bioproc. Tech. Early Access. Search in Google Scholar

Ishangulyyev R., Kim S., Lee S.H. (2019). Understanding food loss and waste. Why are we losing and wasting food? Foods, 8: 297. Search in Google Scholar

Jansen W., Linard C., Noll M., Nöckler K., Al Dahouk S. (2019). Brucella-positive raw milk cheese sold on the inner European market: A public health threat due to illegal import? Food Control, 100: 130–137. Search in Google Scholar

Jaspal M.H., Ijaz M., ul Haq H.A., Yar M.K., Asghar B., Manzoor A., Badar I.H., Ullah S., Islam M.S., Hussain J. (2021). Effect of oregano essential oil or lactic acid treatments combined with air and modified atmosphere packaging on the quality and storage properties of chicken breast meat. LWT – Food Sci. Technol., 146: 111459. Search in Google Scholar

Jay J.M., Loessner M.J., Golden D.A. (2008). Modern food microbiology: Springer Science & Business Media. Search in Google Scholar

Jo D.M., Park S.K., Khan F., Kang M.G., Lee J.H., Kim Y.M. (2021). An approach to extend the shelf life of ribbonfish fillet using lactic acid bacteria cell-free culture supernatant. Food Control, 123: 107731. Search in Google Scholar

Mani-López E., Arrioja-Bretón D., López-Malo A. (2022). The impacts of antimicrobial and antifungal activity of cell-free super-natants from lactic acid bacteria in vitro and foods. Compr. Rev. Food Sci. Food Saf., 21: 604–641. Search in Google Scholar

Milillo S.R., Story R.S., Pak D., O’Bryan C.A., Crandall P.G., Ricke S.C. (2013). Antimicrobial properties of three lactic acid bacterial cultures and their cell free supernatants against Listeria monocytogenes. J. Environ. Sci. Health B, 48: 63–68. Search in Google Scholar

Moradi M., Kousheh S., Almasi H., Alizadeh A., Guimarães J., Toy N., Lotfi Javid A. (2020). Postbiotics produced by lactic acid bacteria: The next frontier in food safety. Compr. Rev. Food Sci. Food Saf., 19: 3390–3415. Search in Google Scholar

Mun S.Y., Kim S.K., Woo E.R., Chang H.C. (2019). Purification and characterization of an antimicrobial compound produced by Lactobacillus plantarum EM showing both antifungal and antibacterial activities. LWT − Food Sci. Technol., 114: 108403. Search in Google Scholar

Nyhan L., Begley M., Mutel A., Qu Y., Johnson N., Callanan M. (2018). Predicting the combinatorial effects of water activity, pH and organic acids on Listeria growth in media and complex food matrices. Food Microbiol., 74: 75–85. Search in Google Scholar

Pelyuntha W., Vongkamjan K. (2022). Combined effects of Salmonella phage cocktail and organic acid for controlling Salmonella Enter-itidis in chicken meat. Food Control, 133: 108653. Search in Google Scholar

Petrou S., Tsiraki M., Giatrakou V., Savvaidis I.N. (2012). Chitosan dipping or oregano oil treatments, singly or combined on modified atmosphere packaged chicken breast meat. Int. J. Food Microbiol., 156: 264–271. Search in Google Scholar

Presti I., D’Orazio G., Labra M., La Ferla B., Mezzasalma V., Bizzaro G., Giardina S., Michelotti A., Tursi F., Vassallo M., Di Gennaro P. (2015). Evaluation of the probiotic properties of new Lactobacillus and Bifidobacterium strains and their in vitro effect. Appl. Microbiol. Biotechnol., 99: 5613–5626. Search in Google Scholar

Radha K.K., Babuskin S., Azhagu S.B.P., Sasikala M., Sabina K., Archana G., Sivarajan M., Sukumar M. (2014). Antimicrobial and antioxidant effects of spice extracts on the shelf life extension of raw chicken meat. Int. J. Food Microbiol., 171: 32–40. Search in Google Scholar

Rahnemoon P., Sarabi-Jamab M., Bostan A., Mansouri E. (2021). Nano-encapsulation of pomegranate (Punica granatum L.) peel extract and evaluation of its antimicrobial properties on coated chicken meat. Food Biosci., 43: 101331. Search in Google Scholar

Sabo S.S., Pérez-Rodríguez N., Domínguez J.M., Oliveira R.P.S. (2017). Inhibitory substances production by Lactobacillus plan-tarum ST16Pa cultured in hydrolyzed cheese whey supplemented with soybean flour and their antimicrobial efficiency as biopreservatives on fresh chicken meat. Food Res. Int., 99: 762–769. Search in Google Scholar

Salanță L.C., Cropotova J. (2022). An update on effectiveness and practicability of plant essential oils in the food industry. Plants, 11: 2488. Search in Google Scholar

Sohaib M., Anjum F.M., Arshad M.S., Rahman U.U. (2016). Posthar-vest intervention technologies for safety enhancement of meat and meat based products; a critical review. J. Food Sci. Technol., 53: 19–30. Search in Google Scholar

Swatland H.J. (2008). How pH causes paleness or darkness in chicken breast meat. Meat Sci. 80: 396–400. Search in Google Scholar

Thorakkattu P., Khanashyam A.C., Shah K., Babu K.S., Mundanat A.S., Deliephan A., Deokar G.S., Santivarangkna C., Nirmal N.P. (2022). Postbiotics: Current trends in food and pharmaceutical industry. Foods, 11: 3094. Search in Google Scholar

Tyl C., Sadler G.D. (2017) pH and titratable acidity. In: Food Analysis, Nielsen S.S. (ed.). Springer International Publishing. Switzerland, pp. 389–406. Search in Google Scholar

WHO (2015). WHO estimates of the global burden of foodborne diseases: foodborne disease burden epidemiology reference group 2007−2015. Geneva: World Health Organization. www.who.int Search in Google Scholar

Yolmeh M., Khomeiri M., Ahmadi Z. (2017). Application of mixture design to introduce an optimum cell-free supernatant of multiple-strain mixture (MSM) for Lactobacillus against food-borne pathogens. LWT − Food Sci. Technol., 83: 298–304. Search in Google Scholar

Zalán Z., Hudáček J., Štětina J., Chumchalová J., Halász A. (2010). Production of organic acids by Lactobacillus strains in three different media. Eur. Food Res. Technol., 230: 395–404. Search in Google Scholar