Cryptosporidiosis Associated with Ozonated Apple Cider
http://www.100md.com
《传染病的形成》
Centers for Disease Control and Prevention, Atlanta, Georgia, USA
Ohio Department of Health, Columbus, Ohio, USA
Atlanta Research and Education Foundation, Atlanta, Georgia, USA
Stark County Health Department, Canton, Ohio, USA
We linked an outbreak of cryptosporidiosis to ozonated apple cider by using molecular and epidemiologic methods. Because ozonation was insufficient in preventing this outbreak, its use in rendering apple cider safe for drinking is questioned.
Cryptosporidium spp. are protozoan parasites transmitted by the fecal-oral route that cause prolonged diarrhea. Only 2 reports describe outbreaks associated with apple cider (1,2), and none have been associated with ozonated cider. In October 2003, a northeast Ohio health department identified 12 local residents with laboratory-confirmed cryptosporidiosis; 11 had drunk a locally produced, ozonated apple cider (cider A) in the 2 weeks before illness. The cider was embargoed on October 24, and we initiated an investigation by using epidemiologic and molecular techniques to determine the cause and extent of the outbreak and the role played by the cider and ozonation.
The Study
We defined a probable case as a northeast Ohio resident with otherwise unexplained diarrhea for >3 days from September 1 to November 30, 2003, and a laboratory-confirmed case as a person with diarrhea and a positive Cryptosporidium laboratory result. Case finding encompassed interviewing persons with diarrhea who came to local health departments and emergency rooms and participants of school outings at which cider A was served. We then conducted 2 epidemiologic studies in which questionnaires showed exposures classically associated with Cryptosporidium transmission such as food, drinking and recreational water, person-to-person contact, animals, and travel.
Study 1 compared laboratory-confirmed case-patients and 2 controls (persons without diarrhea, abdominal pain, or vomiting) per case matched on age and county of residence and identified through random-digit dialing. Additionally, we conducted a retrospective cohort study of school children (study 2) who attended field trips at which cider A was served.
Stool samples from case-patients were screened by wet preparation and tested for Cryptosporidium by using an immunofluorescent assay (Meridian Merifluor Cryptosporidium/Giardia DFA kit, Meridian Bioscience, Cincinnati, OH, USA). Identification of Cryptosporidium in these samples was attempted by using 2 methods: 1) genotyping isolates by polymerase chain reaction–restriction fragment length polymorphism (PCR-RFLP) analysis of the small subunit (SSU) rRNA gene (3,4) with subtyping by DNA sequence analysis of the GP60 gene (5), and 2) amplification of the SSU rRNA gene with genotype differentiation by a microsatellite marker (ML-1) (6,7).
Cider samples were concentrated by centrifugation, and water samples were concentrated by Environmental Protection Agency method 1623 (8). Cryptosporidium genotyping was performed by using the same methods described for stool samples (4). Newly designed GP60 primers were used to subtype cider samples (9).
We identified 23 laboratory-confirmed and 121 probable case-patients with onset dates from September 3 to November 19, 2003 (Figure); the first cider-related case occurred September 22. The median patient age was 20 years (range 1–80). The median incubation period was 7 days (range 1–21), and median period of diarrhea was 7 days (range 3–52). Two patients were hospitalized and none died.
In study 1, we enrolled 19 laboratory-confirmed case-patients and 38 age-matched, community-based controls. Twelve of 19 case-patients, but 0 of 38 controls, had drunk cider A. Although the matched odds ratio (OR) for this association was incalculably high, the lower limit of the 95% confidence interval (CI) was 5.6. Although 3 other exposures were also associated with illness by univariate analysis (Table), only drinking cider A was associated with illness in a conditional logistic regression model that included all of these exposures (estimated OR 14.0, 95% CI 1.8–167).
In study 2, we enrolled 402 persons who participated in outings at which cider A was served. Thirty-three (10%) of the 329 persons who drank cider A became ill, while only 2 (3%) of 73 who did not drink cider A became ill (adjusted relative risk 4.7, 95% CI 1.2–18.1). Only drinking cider A remained significantly associated with illness in a multivariate logistic regression model that included 4 other exposures that increased risk in univariate analysis (estimated OR 5.7, 95% CI 1.2–26.6).
No employees from the orchard or the separate cider pressing facility reported diarrhea from September 1 to November 7, 2003 (date of interview). The water supply for both was negative for Cryptosporidium; employees used "few" dropped apples for cider production. During production, an ozonating apparatus (Golden Buffalo Company, Orange, CA, USA) was used to treat the cider, which was then stored in refrigerated tanks. Most cider was ozonated a second time, then sold in plastic jugs on-site and at nearby grocery stores. Remaining cider was sold through a tap in the orchard's store. In contrast to jugged cider, this cider was not reozonated.
We performed a Cryptosporidium PCR on all 14 available samples from the laboratory-confirmed case-patients. Twelve (85.7%) of these were PCR positive; 11 of these 12 samples were identified as Cryptosporidium parvum and 1 as the cervine Cryptosporidium genotype (W4). Subtype identification of stool samples yielded 2 closely related C. parvum subtypes (IIaA15G2R1 and IIaA17G2R1).
The remaining contents of a jug of cider A that a laboratory-confirmed case-patient had partially drunk were also positive by PCR for C. parvum subtype IIaA17G2R1. This case-patient's stool sample yielded the same subtype of C. parvum, as did 4 other case-patients' stool samples; all of these persons drank cider A in the 2 weeks before illness onset.
Conclusions
Our investigation strongly implicates cider A as the cause of this outbreak. The timing of cider A production closely paralleled the outbreak, and drinking cider A was the only predictor significantly associated with illness in both univariate and multivariate analyses of both epidemiologic studies. Furthermore, detection of C. parvum subtype IIaA17G2R1 from the sample of partially drunk cider A from a laboratory-confirmed case-patient provided further evidence of this link.
The 2 C. parvum subtypes found in this outbreak likely represent a common contamination source; both are common in cattle, and multiple subtypes are commonly found on farms (10). This outbreak highlights the need for continued development of molecular biologic methods because these techniques will be useful to identify and define future Cryptosporidium outbreaks and supplement epidemiologic associations.
An issue raised by this outbreak is the role of ozonation in the treatment of apple cider. New regulations (Hazard Analysis and Critical Control Point [HACCP] standards) enacted by the US Food and Drug Administration (FDA) in 2001 (11) require juice manufacturers to demonstrate a 5-log reduction of "the most resistant microorganism of public health significance" in their production process.
Because this is the third reported Cryptosporidium outbreak related to unpasteurized apple cider (1,2), whatever sterilization procedure is used must be effective against Cryptosporidium. Although pasteurization kills Cryptosporidium oocysts (12), no data exist on the use of ozonation against Cryptosporidium in food or juice products, where turbidity and low temperature render ozonation less effective (13,14). Furthermore, ozonation is difficult to standardize because effectiveness depends on contact time and concentration.
The consideration of ozonation is important because effective disinfection would have prevented the outbreak unless contamination occurred at the final step before distribution. Furthermore, of the 12 ill persons in the case-control study who drank cider A, 6 drank once-ozonated cider and 6 drank twice-ozonated cider, suggesting that even repeated ozonation was inadequate to kill Cryptosporidium. The failure of ozone could have been due to an inherent inadequacy for killing Cryptosporidium in apple cider or improper use; either possibility emphasizes the problems with ozonation in this setting and the need for further testing before its use is accepted.
Given the paucity of evidence supporting ozonation for apple cider disinfection or for killing Cryptosporidium in this product, and its apparent failure in this outbreak, the FDA issued an addendum to its HACCP rule (15). This addendum advises that juice makers should not use ozone in their manufacturing process unless they can prove a 5-log pathogen reduction through ozonation. To our knowledge, no studies have established this reduction to date.
Acknowledgments
We thank Ling Zhou and Jianlin Jiang for performing much of the molecular biological laboratory work and Paul DePasquale, Jane Dancy, Susan Kovach, Cheryl Long, Betty Matecheck, and Christina R. Henning for assisting with the epidemiologic and environmental investigation.
Dr Blackburn is currently a clinical assistant professor of infectious diseases at Stanford University. He performed this work while an Epidemic Intelligence Service officer in the Division of Parasitic Diseases at the Centers for Disease Control and Prevention. His research interests include cryptosporidiosis, schistosomiasis, and strongyloidiasis in refugee populations; angiostrongyliasis; and use of insecticide-treated bed nets to control malaria and lymphatic filariasis.
References
Millard PS, Gensheimer KF, Addiss DG, Sosin DM, Beckett GA, Houck-Jankoski A, et al. An outbreak of cryptosporidiosis from fresh-pressed apple cider. JAMA. 1994;272:1592–6.
Centers for Disease Control and Prevention. Outbreaks of Escherichia coli O157:H7 infection and cryptosporidiosis associated with drinking unpasteurized apple cider—Connecticut and New York, October 1996. JAMA. 1997;277:781–3.
Xiao L, Bern C, Limor J, Sulaiman I, Roberts J, Checkley W, et al. Identification of 5 types of Cryptosporidium parasites in children in Lima, Peru. J Infect Dis. 2001;183:492–7.
Xiao L, Singh A, Limor J, Graczyk TK, Gradus S, Lal A. 2001. Molecular characterization of Cryptosporidium oocysts in samples of raw surface water and wastewater. Appl Environ Microbiol. 2001;67:1097–101.
Glaberman S, Moore JE, Lowery CJ, Chalmers RM, Sulaiman I, Elwin K, et al. Three drinking-water-associated cryptosporidiosis outbreaks, Northern Ireland. Emerg Infect Dis. 2002;8:631–3.
Da Silva AJ, Bornay-Llinares FJ, Moura IN, Slemenda SB, Tuttle JL, Pieniazek NJ. Fast and reliable extraction of protozoan parasite DNA from fecal specimens. Mol Diagn. 1999;4:57–64.
Caccio S, Homan W, Camilli R, Traldi G, Kortbeek T, Pozio E. A microsatellite marker reveals population heterogeneity within human and animal genotypes of Cryptosporidium parvum. Parasitology. 2000;120:237–44.
US Environmental Protection Agency. Method 1623: Cryptosporidium and Giardia in water by filtration/IMS/FA. Publication no. EPA-821-R-99-006. Office of Water. Washington: The Agency; 1999.
Sulaiman IM, Hira PR, Zhou L, Al-Ali FM, Al-Shelahi FA, Shweiki HM, et al. Unique endemicity of cryptosporidiosis in children in Kuwait. J Clin Microbiol. 2005;43:2805–9.
Peng MM, Wilson ML, Holland RE, Meshnick SR, Lal AA, Xiao L. Genetic diversity of Cryptosporidium spp. in cattle in Michigan: implications for understanding the transmission dynamics. Parasitol Res. 2003;90:175–80.
US Food and Drug Administration. Hazard analysis and critical control point (HAACP); procedures for the safe and sanitary processing and importing of juice; final rule. Federal Register. 2001;66:6137–202.
Deng MQ, Cliver DO. Inactivation of Cryptosporidium parvum oocysts in cider by flash pasteurization. J Food Prot. 2001;64:523–7.
Korich DG, Mead JR, Madore MS, Sinclair NA, Sterling CR. Effects of ozone, chlorine dioxide, chlorine, and monochloramine on Cryptosporidium parvum oocyst viability. Appl Environ Microbiol. 1990;56:1423–8.
Driedger AM, Rennecker JL, Marinas BJ. Inactivation of Cryptosporidium parvum oocysts with ozone and monochloramine at low temperature. Water Res. 2001;35:41–8.
US Food and Drug Administration/CFSAN. Guidance for industry: recommendations to processors of apple juice or cider on the use of ozone for pathogen reduction purposes, 2004 Aug. [cited 2005 May 24]. Available from http://www.cfsan.fda.gov/~dms/juicgu12.html(Brian G. Blackburn, Jacek)
Ohio Department of Health, Columbus, Ohio, USA
Atlanta Research and Education Foundation, Atlanta, Georgia, USA
Stark County Health Department, Canton, Ohio, USA
We linked an outbreak of cryptosporidiosis to ozonated apple cider by using molecular and epidemiologic methods. Because ozonation was insufficient in preventing this outbreak, its use in rendering apple cider safe for drinking is questioned.
Cryptosporidium spp. are protozoan parasites transmitted by the fecal-oral route that cause prolonged diarrhea. Only 2 reports describe outbreaks associated with apple cider (1,2), and none have been associated with ozonated cider. In October 2003, a northeast Ohio health department identified 12 local residents with laboratory-confirmed cryptosporidiosis; 11 had drunk a locally produced, ozonated apple cider (cider A) in the 2 weeks before illness. The cider was embargoed on October 24, and we initiated an investigation by using epidemiologic and molecular techniques to determine the cause and extent of the outbreak and the role played by the cider and ozonation.
The Study
We defined a probable case as a northeast Ohio resident with otherwise unexplained diarrhea for >3 days from September 1 to November 30, 2003, and a laboratory-confirmed case as a person with diarrhea and a positive Cryptosporidium laboratory result. Case finding encompassed interviewing persons with diarrhea who came to local health departments and emergency rooms and participants of school outings at which cider A was served. We then conducted 2 epidemiologic studies in which questionnaires showed exposures classically associated with Cryptosporidium transmission such as food, drinking and recreational water, person-to-person contact, animals, and travel.
Study 1 compared laboratory-confirmed case-patients and 2 controls (persons without diarrhea, abdominal pain, or vomiting) per case matched on age and county of residence and identified through random-digit dialing. Additionally, we conducted a retrospective cohort study of school children (study 2) who attended field trips at which cider A was served.
Stool samples from case-patients were screened by wet preparation and tested for Cryptosporidium by using an immunofluorescent assay (Meridian Merifluor Cryptosporidium/Giardia DFA kit, Meridian Bioscience, Cincinnati, OH, USA). Identification of Cryptosporidium in these samples was attempted by using 2 methods: 1) genotyping isolates by polymerase chain reaction–restriction fragment length polymorphism (PCR-RFLP) analysis of the small subunit (SSU) rRNA gene (3,4) with subtyping by DNA sequence analysis of the GP60 gene (5), and 2) amplification of the SSU rRNA gene with genotype differentiation by a microsatellite marker (ML-1) (6,7).
Cider samples were concentrated by centrifugation, and water samples were concentrated by Environmental Protection Agency method 1623 (8). Cryptosporidium genotyping was performed by using the same methods described for stool samples (4). Newly designed GP60 primers were used to subtype cider samples (9).
We identified 23 laboratory-confirmed and 121 probable case-patients with onset dates from September 3 to November 19, 2003 (Figure); the first cider-related case occurred September 22. The median patient age was 20 years (range 1–80). The median incubation period was 7 days (range 1–21), and median period of diarrhea was 7 days (range 3–52). Two patients were hospitalized and none died.
In study 1, we enrolled 19 laboratory-confirmed case-patients and 38 age-matched, community-based controls. Twelve of 19 case-patients, but 0 of 38 controls, had drunk cider A. Although the matched odds ratio (OR) for this association was incalculably high, the lower limit of the 95% confidence interval (CI) was 5.6. Although 3 other exposures were also associated with illness by univariate analysis (Table), only drinking cider A was associated with illness in a conditional logistic regression model that included all of these exposures (estimated OR 14.0, 95% CI 1.8–167).
In study 2, we enrolled 402 persons who participated in outings at which cider A was served. Thirty-three (10%) of the 329 persons who drank cider A became ill, while only 2 (3%) of 73 who did not drink cider A became ill (adjusted relative risk 4.7, 95% CI 1.2–18.1). Only drinking cider A remained significantly associated with illness in a multivariate logistic regression model that included 4 other exposures that increased risk in univariate analysis (estimated OR 5.7, 95% CI 1.2–26.6).
No employees from the orchard or the separate cider pressing facility reported diarrhea from September 1 to November 7, 2003 (date of interview). The water supply for both was negative for Cryptosporidium; employees used "few" dropped apples for cider production. During production, an ozonating apparatus (Golden Buffalo Company, Orange, CA, USA) was used to treat the cider, which was then stored in refrigerated tanks. Most cider was ozonated a second time, then sold in plastic jugs on-site and at nearby grocery stores. Remaining cider was sold through a tap in the orchard's store. In contrast to jugged cider, this cider was not reozonated.
We performed a Cryptosporidium PCR on all 14 available samples from the laboratory-confirmed case-patients. Twelve (85.7%) of these were PCR positive; 11 of these 12 samples were identified as Cryptosporidium parvum and 1 as the cervine Cryptosporidium genotype (W4). Subtype identification of stool samples yielded 2 closely related C. parvum subtypes (IIaA15G2R1 and IIaA17G2R1).
The remaining contents of a jug of cider A that a laboratory-confirmed case-patient had partially drunk were also positive by PCR for C. parvum subtype IIaA17G2R1. This case-patient's stool sample yielded the same subtype of C. parvum, as did 4 other case-patients' stool samples; all of these persons drank cider A in the 2 weeks before illness onset.
Conclusions
Our investigation strongly implicates cider A as the cause of this outbreak. The timing of cider A production closely paralleled the outbreak, and drinking cider A was the only predictor significantly associated with illness in both univariate and multivariate analyses of both epidemiologic studies. Furthermore, detection of C. parvum subtype IIaA17G2R1 from the sample of partially drunk cider A from a laboratory-confirmed case-patient provided further evidence of this link.
The 2 C. parvum subtypes found in this outbreak likely represent a common contamination source; both are common in cattle, and multiple subtypes are commonly found on farms (10). This outbreak highlights the need for continued development of molecular biologic methods because these techniques will be useful to identify and define future Cryptosporidium outbreaks and supplement epidemiologic associations.
An issue raised by this outbreak is the role of ozonation in the treatment of apple cider. New regulations (Hazard Analysis and Critical Control Point [HACCP] standards) enacted by the US Food and Drug Administration (FDA) in 2001 (11) require juice manufacturers to demonstrate a 5-log reduction of "the most resistant microorganism of public health significance" in their production process.
Because this is the third reported Cryptosporidium outbreak related to unpasteurized apple cider (1,2), whatever sterilization procedure is used must be effective against Cryptosporidium. Although pasteurization kills Cryptosporidium oocysts (12), no data exist on the use of ozonation against Cryptosporidium in food or juice products, where turbidity and low temperature render ozonation less effective (13,14). Furthermore, ozonation is difficult to standardize because effectiveness depends on contact time and concentration.
The consideration of ozonation is important because effective disinfection would have prevented the outbreak unless contamination occurred at the final step before distribution. Furthermore, of the 12 ill persons in the case-control study who drank cider A, 6 drank once-ozonated cider and 6 drank twice-ozonated cider, suggesting that even repeated ozonation was inadequate to kill Cryptosporidium. The failure of ozone could have been due to an inherent inadequacy for killing Cryptosporidium in apple cider or improper use; either possibility emphasizes the problems with ozonation in this setting and the need for further testing before its use is accepted.
Given the paucity of evidence supporting ozonation for apple cider disinfection or for killing Cryptosporidium in this product, and its apparent failure in this outbreak, the FDA issued an addendum to its HACCP rule (15). This addendum advises that juice makers should not use ozone in their manufacturing process unless they can prove a 5-log pathogen reduction through ozonation. To our knowledge, no studies have established this reduction to date.
Acknowledgments
We thank Ling Zhou and Jianlin Jiang for performing much of the molecular biological laboratory work and Paul DePasquale, Jane Dancy, Susan Kovach, Cheryl Long, Betty Matecheck, and Christina R. Henning for assisting with the epidemiologic and environmental investigation.
Dr Blackburn is currently a clinical assistant professor of infectious diseases at Stanford University. He performed this work while an Epidemic Intelligence Service officer in the Division of Parasitic Diseases at the Centers for Disease Control and Prevention. His research interests include cryptosporidiosis, schistosomiasis, and strongyloidiasis in refugee populations; angiostrongyliasis; and use of insecticide-treated bed nets to control malaria and lymphatic filariasis.
References
Millard PS, Gensheimer KF, Addiss DG, Sosin DM, Beckett GA, Houck-Jankoski A, et al. An outbreak of cryptosporidiosis from fresh-pressed apple cider. JAMA. 1994;272:1592–6.
Centers for Disease Control and Prevention. Outbreaks of Escherichia coli O157:H7 infection and cryptosporidiosis associated with drinking unpasteurized apple cider—Connecticut and New York, October 1996. JAMA. 1997;277:781–3.
Xiao L, Bern C, Limor J, Sulaiman I, Roberts J, Checkley W, et al. Identification of 5 types of Cryptosporidium parasites in children in Lima, Peru. J Infect Dis. 2001;183:492–7.
Xiao L, Singh A, Limor J, Graczyk TK, Gradus S, Lal A. 2001. Molecular characterization of Cryptosporidium oocysts in samples of raw surface water and wastewater. Appl Environ Microbiol. 2001;67:1097–101.
Glaberman S, Moore JE, Lowery CJ, Chalmers RM, Sulaiman I, Elwin K, et al. Three drinking-water-associated cryptosporidiosis outbreaks, Northern Ireland. Emerg Infect Dis. 2002;8:631–3.
Da Silva AJ, Bornay-Llinares FJ, Moura IN, Slemenda SB, Tuttle JL, Pieniazek NJ. Fast and reliable extraction of protozoan parasite DNA from fecal specimens. Mol Diagn. 1999;4:57–64.
Caccio S, Homan W, Camilli R, Traldi G, Kortbeek T, Pozio E. A microsatellite marker reveals population heterogeneity within human and animal genotypes of Cryptosporidium parvum. Parasitology. 2000;120:237–44.
US Environmental Protection Agency. Method 1623: Cryptosporidium and Giardia in water by filtration/IMS/FA. Publication no. EPA-821-R-99-006. Office of Water. Washington: The Agency; 1999.
Sulaiman IM, Hira PR, Zhou L, Al-Ali FM, Al-Shelahi FA, Shweiki HM, et al. Unique endemicity of cryptosporidiosis in children in Kuwait. J Clin Microbiol. 2005;43:2805–9.
Peng MM, Wilson ML, Holland RE, Meshnick SR, Lal AA, Xiao L. Genetic diversity of Cryptosporidium spp. in cattle in Michigan: implications for understanding the transmission dynamics. Parasitol Res. 2003;90:175–80.
US Food and Drug Administration. Hazard analysis and critical control point (HAACP); procedures for the safe and sanitary processing and importing of juice; final rule. Federal Register. 2001;66:6137–202.
Deng MQ, Cliver DO. Inactivation of Cryptosporidium parvum oocysts in cider by flash pasteurization. J Food Prot. 2001;64:523–7.
Korich DG, Mead JR, Madore MS, Sinclair NA, Sterling CR. Effects of ozone, chlorine dioxide, chlorine, and monochloramine on Cryptosporidium parvum oocyst viability. Appl Environ Microbiol. 1990;56:1423–8.
Driedger AM, Rennecker JL, Marinas BJ. Inactivation of Cryptosporidium parvum oocysts with ozone and monochloramine at low temperature. Water Res. 2001;35:41–8.
US Food and Drug Administration/CFSAN. Guidance for industry: recommendations to processors of apple juice or cider on the use of ozone for pathogen reduction purposes, 2004 Aug. [cited 2005 May 24]. Available from http://www.cfsan.fda.gov/~dms/juicgu12.html(Brian G. Blackburn, Jacek)