Artículos de revistas
Review: Efficiency of physical and chemical treatments on the inactivation of dairy bacteriophages
Fecha
2012-01Registro en:
Guglielmotti, Daniela Marta; Mercanti, Diego Javier; Reinheimer, Jorge Alberto; Quiberoni, Andrea del Lujan; Review: Efficiency of physical and chemical treatments on the inactivation of dairy bacteriophages; Frontiers Research Foundation; Frontiers in Microbiology; 2; 282; 1-2012; 1-11
1664-302X
CONICET Digital
CONICET
Autor
Guglielmotti, Daniela Marta
Mercanti, Diego Javier
Reinheimer, Jorge Alberto
Quiberoni, Andrea del Lujan
Resumen
Bacteriophages can cause great economic losses due to fermentation failure in dairy plants. Hence, physical and chemical treatments of raw material and/or equipment are mandatory to maintain phage levels as low as possible. Regarding thermal treatments used to kill pathogenic bacteria or achieve longer shelf-life of dairy products, neither low temperature long time nor high temperature short time pasteurization were able to inactivate most lactic acid bacteria (LAB) phages. Even though most phages did not survive 90°C for 2 min, there were some that resisted 90°C for more than 15 min (conditions suggested by the International Dairy Federation, for complete phage destruction). Among biocides tested, ethanol showed variable effectiveness in phage inactivation, since only phages infecting dairy cocci and Lac-tobacillus helveticus were reasonably inactivated by this alcohol, whereas isopropanol was in all cases highly ineffective. In turn, peracetic acid has consistently proved to be very fast and efficient to inactivate dairy phages, whereas efficiency of sodium hypochlorite was variable, even among different phages infecting the same LAB species. Both alkaline chloride foam and ethoxylated non-ylphenol with phosphoric acid were remarkably efficient, trait probably related to their highly alkaline or acidic pH values in solution, respectively. Photocatalysis using UV light and TiO2 has been recently reported as a feasible option to industrially inactivate phages infecting diverse LAB species. Processes involving high pressure were barely used for phage inactivation, but until now most studied phages revealed high resistance to these treatments. To conclude, and given the great phage diversity found on dairies, it is always advisable to combine different anti-phage treatments (biocides, heat, high pressure, photocatalysis), rather than using them separately at extreme conditions.