ABSTRACT
The aim of this study was to investigate the effect of pulsed ultra-violet [UV] irradiation on inactivation of beer spoilage microorganisms. UV irradiation is nowadays cost effective enough to compete with traditional biological, physical, and chemical treatment technologies and has become an alternative to such methods. Photoinactivation effects of pulsed UV laser with the wavelengths of 355 and 266 nm, which inactivate typical prokaryotic [Escherichia coli] and eukaryotic [Saccharomyces cerevisiae] microorganisms, were examined with different doses and exposure times. A dose of 100 J/cm2 of the 355 nm pulsed UV laser was able to reduce about 1 to 2 log [88.75%] of E.coli with the population of 1.6x108 colony-forming units [CFU/ml], and 97% of 3.2x107, 3x106, 5.5x105, and 9x104 CFU/ml. In the case of 266 nm, more than 99% reduction in E. coli serial dilutions was inactivated, using 10 J/cm2 with exception of 7x104 CFU/ml which was not detected any bacterial growth using 5 J/cm2. In addition, 50, 40, and 20 J/cm2 energy were used successfully to inactivate S. cerevisiae at the populations of 5.4x106, 7x105, 5x104 and 4x103 CFU/ml, respectively. As a result, pulsed UV Laser with 266 nm was strong enough to inactivate a high titer of bacterial and yeast indicator standards suspended in non-alcoholic beer in comparison with 355nm doses. Results indicate that pulsed UV technology, in principle, is an attractive alternative to conventional methods for the inactivation of indicator microorganisms and has potential in irradiation of unpasteurized beer