Comparison of tissue culture and animal models for assessment of Cryptospridium parvum infection.

The current increased interest for using tissue culture as a surrogate for mouse infection to assess Cryptospridium viability suggests that a comparison of the two models is essential for data interpretation. Therefore, a need remains for a statistical comparison that can demonstrate if infection and inactivation predicted by new tissue culture models are comparable with those predicted by animal models. Data from a total of 31 dose-response trials using both tissue culture and mouse models to assess C. parvum infectivity were compared. The dose needed to infect 50% of the tissue cultures (ID(50)) was also compared to each ID(50) in mice. Average ID(50)s developed using the logit dose-response method for tissue culture and mice were 8 and 107, respectively, suggesting that tissue culture was more sensitive to infection. However, correlation (r) between tissue culture and mouse infectivity was statistically significant (0.9167 [95% CI=0.8428 to 0.9594, p<0.0001]). Comparison of oocyst disinfection by UV and chlorine dioxide showed no significant difference between inactivation predicted by tissue culture and mouse models (p=0.8893; t=0.0141; n=21). These results demonstrate that tissue culture can successfully be used to measure C. parvum infection and can be used for determining inactivation in disinfection studies.

Low- and medium-pressure UV inactivation of microsporidia Encephalitozoon intestinalis.

Newly recognized waterborne pathogens such as microsporidia are being detected in the world's water supplies with increasing frequency. Many of these organisms have been shown to cause negative health impacts for both immunocompetent as well as immunocompromised individuals. It is imperative that these emerging pathogens be investigated for their ability to resist both traditional and novel disinfection technologies that are currently in use or under consideration for drinking water treatment. Low- and medium pressure UV light is at the cutting edge of disinfection technologies for the drinking water industry. While previous UV disinfection studies have focused on the inactivation of Cryptosporidium and Giardia as well as viruses and common bacteria, this research reports the ability of low- and medium pressure UV light to inactivate > 3.6 log10 of microsporidia Encephalitozoon intestinalis spores at a dose of 6 mJ/cm2 or higher as determined using a cell culture approach.