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Wade, T. J., Calderon R. L., Sams E., Beach M., Brenner K. P., Williams A. H., et al. (2006).  Rapidly measured indicators of recreational water quality are predictive of swimming-associated gastrointestinal illness. Environmental Health Perspectives. 114,
Wade, T. J., Pai N., Eisenberg J. N. S., & Colford J. M. (2003).  Do US EPA water quality guidelines for recreational waters prevent gastrointestinal illness? A systematic review and meta-analysis. Environmental Health Perspectives. 111,
Wahi, S., & Bansal S. (2006).  Growth and Survival of Escherichia coli O157:H7 During Manufacture and Storage of Indian Cheese (Paneer).
Walker, D.. H. (1986).  Gastroenterology of Rocky Mountain spotted fever. Pract. Gastroenterol.. 10, 25-39.
Walker, F., & Stedinger J. (1999).  Fate and transport model of Cryptosporidium. Journal of Environmental Quality. 33,
Walker, D.. H., & Mattern W.. D. (1979).  Acute renal failure in Rocky Mountain spotted fever. Arch. Intern. Med.. 139, 443-448.
Walker, D.. H., Lesesne H.. R., Varma V.. A., & Thacker W.. C. (1985).  Rocky Mountain spotted fever mimicking acute cholecystitis. 2194-2196.
Walker, FR., & Stedinger JR. (1999).   Fate and transport model of Cryptosporidium.
Walker, D.. H., Henderson F.. W., & Hutchins G.. M. (1986).  Rocky Mountain spotted fever: mimicry of appendicitis or acute surgical abdomen?. Am. J. Dis. Child. 140, 742-744.
Walker, D.. (1989).  Rocky Mountain spotted fever: a disease in need of microbiological concern. Clinical microbiology reviews. 2, 227-240.
Wall, R., Dymond N., Bell A., & Thornley C. (2011).  Two New Zealand outbreaks of norovirus gastroenteritis linked to commercially farmed oysters..
Walters, S. P., Yamahara K. M., & Boehm A. B. (2009).  Persistence of nucleic acid markers of health-relevant organisms in seawater microcosms: implications for their use in assessing risk in recreational waters. Water Research. 43, 4929–4939.
Wang, J., & Deng Z. (2012).   Detection and forecasting of oyster norovirus outbreaks: Recent advances and future perspectives.
Wang, D., & Xu X. (2010).  Detection of Vibrio cholera by O1 and O139 in environmental water samples by an immunofluorescent-aggregation assay.
Ward, R.., Krugman S.., Giles J.. P., Jacobs A.. M., & Bodansky O.. (1958).  Infectious hepatitis; studies of its natural history and prevention. The New England journal of medicine. 258, 9.
Ward, R.. L., Bernstein D.. I., Young E.. C., Sherwood J.. R., Knowlton D.. R., & Schiff G.. M. (1986).  Human Rotavirus Studies in Volunteers: Determination of Infectious Dose and Serological Response to Infection. Journal of Infectious Diseases. 154, 5.
Ware, M. W., Augustine S. A., Erisman D. O., See M. J., Wymer L., Hayes S. L., et al. (2010).  Determining UV inactivation of Toxoplasma gondii oocysts by using cell culture and a mouse bioassay. Applied and Environmental Microbiology. 76,
Ware, M. W., Augustine S. A., Erisman D. O., See M. J., Wymer L., Hayes S. L., et al. (2010).  Determining UV inactivation of Toxoplasma gondii oocysts by using cell culture and a mouse bioassay. Applied and Environmental Microbiology. 76,
Washburn, J., & Jacobson JA. (1976).  Pseudomonas aeruginosa rash associated with a whirlpool.
Watanabe, T.., Bartrand T.. A., Weir M.. H., Omura T.., & Haas C.. N. (2010).  Development of a Dose-Response Model for SARS Coronavirus. Risk Analysis: An International Journal. 30(7), 1129–1138.
Watanabe, T.., Bartrand T.. A., Omura T.., & Haas C.. N. (2012).  Dose-Response Assessment for Influenza A Virus Based on Data Sets of Infection with its Live Attenuated Reassortants. Risk Analysis. 32, 555–565.
Weinberger, M., & Keller N. (2005).  Recent trends in the epidemiology of non-typhoid Salmonella and antimicrobial resistance: the Israeli experience and worldwide review. Current Opinion in Infectious Diseases. 18(6), 
Weir, M. H. (2009).  Development of physiologically based pathogen transport and kinetics model for inhalation of Bacillus anthracis spores.
Weir, M.. H., & Haas C.. N. (2011).  A Model for In-vivo Delivered Dose Estimation for Inhaled ''Bacillus anthracis'' Spores in Humans with Interspecies Extrapolations. Environmental Science and Technology. 45, 5828-5833.
Weir, M.. H. (2009).  Development of a Physiologically Based Pathogen Transport and Kinetics Model for the Inhalation of ''Bacillus anthracis'' Spores.