4-fold as a result of this single pass. Our earlier study [12] also showed TiO2 coated glass plate was more effective than STI571 in vitro un-coated glass plate TFFBR in microbial inactivation. For
an aquaculture system, the system would operate in SGC-CBP30 manufacturer recirculation mode, with a continuous flowing TFFBR reactor treating an aquaculture pond under high sunlight condition. This should help to maintain the population of pathogens such as Aeromonas hydrophila population below the infective dose, thereby preventing the establishment of an infection. The minimum infectious dose of A. hydrophila varies from strain to strain – for example, a dose of 105 cfu of A. hydrophila AL0179 per fish (Nile tilapia) has been shown to cause 20% mortality [48]. As a whole, the use of TFFBR in aquaculture systems is a new technology that may be applicable to fresh water, brackish water or marine systems. From Figure 8, it was clearly seen that during the summer season the turbidity of aquaculture pond water was lower while in the winter it was high because of the weather conditions. Therefore, the TFFBR system will be more useful for treating aquaculture pathogens such as A. hydrophila when the water turbidity is lowest in the summer season, being likely to be less effective
in winter due to a combination of higher turbidity and lower solar irradiance. Above all, to get microbial inactivation in this study, both bacterial enumeration techniques (aerobic and ROS-neutralised) were important as ROS-neutralised conditions shows the number of damaged (ROS-sensitive) cells under Thiazovivin solubility dmso similar experimental conditions. Conclusion The results clearly show that turbidity has a significant influence on solar photocatalytic oxyclozanide inactivation of A. hydrophila using the TFFBR system with synthetic and natural waters. Humic acid added to water samples also caused a noticeable reduction in microbial inactivation. pH 5 decreases inactivation while salinity (0.00-3.50%) had no major effect on A. hydrophila inactivation. Finally, the observation that the turbidity of aquaculture
pond water had a substantial effect on microbial inactivation is likely to affect the operation of aquaculture systems, especially in winter months. Acknowledgements We are grateful to CQUniversity for the financial support for this project. SK thanks CPWS and Central Queensland University for providing funding to support this project. References 1. Cao J-P, Wang H: Environmental impact of aquaculture and countermeasures to aquaculture pollution in China. Environ Sci Pollut Res 2007,14(7):452–462.CrossRef 2. Gamage J, Zhang Z: Applications of Photocatalytic Disinfection. International Journal of Photoenergy 2010, 11. 3. Defoirdt T, Boon N, Sorgeloos P, Verstraete W, Bossier P: Alternatives to antibiotics to control bacterial infections: luminescent vibriosis in aquaculture as an example. Trends Biotechnol 2007,25(10):472–479.PubMedCrossRef 4.