Hostname: page-component-8448b6f56d-42gr6 Total loading time: 0 Render date: 2024-04-16T19:53:04.437Z Has data issue: false hasContentIssue false
  • English
  • Français

Verotoxigenic Escherichia coli transmission in Ireland: a review of notified outbreaks, 2004–2012

Published online by Cambridge University Press:  18 September 2015

P. GARVEY ,
A. CARROLL ,
E. McNAMARA  and
P. J. McKEOWN
P. GARVEY*
Affiliation:
Health Service Executive (HSE), Health Protection Surveillance Centre, Dublin, Ireland
A. CARROLL
Affiliation:
Health Service Executive Public Health Laboratory–Dublin Mid-Leinster, Cherry Orchard Hospital, Ballyfermot, Dublin, Ireland European Public Health Microbiology Training Programme (EUPHEM), European Centre for Disease Prevention and Control, Stockholm, Sweden
E. McNAMARA
Affiliation:
Health Service Executive Public Health Laboratory–Dublin Mid-Leinster, Cherry Orchard Hospital, Ballyfermot, Dublin, Ireland
P. J. McKEOWN
Affiliation:
Health Service Executive (HSE), Health Protection Surveillance Centre, Dublin, Ireland
*
*Author for correspondence: Dr P. Garvey, HSE, Health Protection Surveillance Centre, 25–27 Middle Gardiner Street, Dublin 1, Ireland. (Email: patricia.garvey@hse.ie)
Rights & Permissions [Opens in a new window]

Summary

Verotoxigenic Escherichia coli (VTEC) are significant for their low infectious dose, their potential clinical severity and the frequency with which they generate outbreaks. To describe the relative importance of different outbreak transmission routes for VTEC infection in Ireland, we reviewed outbreak notification data for the period 2004–2012, describing the burden and characteristics of foodborne, waterborne, animal contact and person-to-person outbreaks. Outbreaks where person-to-person spread was reported as the sole transmission route accounted for more than half of all outbreaks and outbreaks cases, most notably in childcare facilities. The next most significant transmission route was waterborne spread from untreated or poorly treated private water supplies. The focus for reducing incidence of VTEC should be on reducing waterborne and person-to-person transmission, by publicizing Health Service Executive materials developed for consumers on private well management, and for childcare facility managers and public health professionals on prevention of person-to-person spread.

Keywords

EpidemiologyShiga-like toxin-producing E. colitransmission
Type
Original Papers
Information
Epidemiology & Infection , Volume 144 , Issue 5 , April 2016 , pp. 917 - 926
Check for updates
Copyright
Copyright © Cambridge University Press 2015 

INTRODUCTION

Verotoxigenic Escherichia coli (VTEC) have emerged to become one of the most important gastrointestinal pathogens globally in the last few decades [Reference Pennington1]. They are significant for their low infectious dose, their potential clinical severity and the frequency with which they generate outbreaks. Data for the European Union indicate an overall crude incidence rate of 1·5 cases/100 000 population in 2012 [2]. Ireland has consistently reported one of the highest incidence rates among EU Member States rising from 1·6 to 12·07/100 000 population between 2004 and 2012 [3].

Unlike Campylobacter, Listeria and Salmonella, all of which are primarily foodborne, VTEC have been shown to be efficiently transmitted by a variety of routes, including food [Reference Buchholz46], water [7, Reference Swerdlow8], contact with infected animals or the environment [9], and person-to-person (P-P) spread [Reference Werber10, Reference Parry and Salmon11].

Understanding the relative importance of different modes of spread at a national level is important for the development of country-specific control and prevention policies which could lead to a meaningful reduction in disease incidence. Outbreak surveillance systems which focus solely on foodborne and waterborne outbreaks can underestimate the role of P-P spread and animal contact in disease transmission. Similarly, sporadic case-control studies, which usually exclude secondary cases, focus on primary transmission routes and are not designed to measure the relative importance of secondary transmission.

Outbreak surveillance systems such as the Irish system which capture information on all outbreaks regardless of transmission route provide an alternative source of information for learning about the epidemiology of VTEC disease. In this paper, we review Irish VTEC outbreak data for the period 2004–12, describing the burden and characteristics of foodborne, waterborne, animal contact and P-P outbreaks.

MATERIALS AND METHODS

In Ireland, since 2004 all outbreaks of infectious disease are notifiable under Infectious Disease Regulation SI707 (2003). This includes both family and general outbreaks. The system is considered very sensitive, particularly for the detection of VTEC family outbreaks, as there is active public health investigation of notified VTEC cases which frequently results in the discovery of additional VTEC cases either in household contacts or close contacts. Reported outbreaks must have at least one laboratory-confirmed VTEC case, with additional laboratory-confirmed cases and/or epidemiologically linked clinical cases.

The information collected on outbreaks includes number of cases and number hospitalized, suspected transmission route, location of outbreak, causative organism, source, evidence implicating source, and factors contributing to the outbreak. These data are maintained in the Computerized Infectious Disease Reporting (CIDR) System, a central data repository for all notifiable infectious disease data in Ireland.

Multiple transmission routes can be reported for a single outbreak. For simplicity in this report, outbreaks reported as ‘waterborne’ or ‘waterborne and P-P’ spread, for example, are grouped under the category waterborne ± P-P, etc., on the assumption that P-P spread was secondary to the other specified mode of transmission. Outbreak locations were grouped as follows: outbreaks confined to one household or outbreaks including more than one household but where the cases were closely related were included in the same category; outbreaks where the common point of exposure was a premises which included a commercial activity, e.g. hotel or other food service establishment were grouped; and outbreaks described as associated with a childcare facility or where the outbreak involved families and their childcare arrangements were grouped as childcare.

Population data from the Central Statistics Office Census 2006 Report was used as the population denominator for outbreak incidence rates per 100 000 population [12]. The Kruskal–Wallis test was used to test for the difference in medians, and the χ 2 test or Fisher's exact test to test the difference in proportions as appropriate. For the variable ‘Health Service Executive area’ (the Irish public health administrative districts), a comparison was made between the transmission route distribution for each individual area against that for all the other areas combined. Stata v. 11.2 (StataCorp, USA) was used for all statistical calculations.

RESULTS

Burden of illness in outbreaks of VTEC infection

Between 2004 and 2012, 355 VTEC outbreaks were notified, an average of 39 per year (range 8–97), including 1035 cases (mean 3·0 per outbreak). Family outbreaks accounted for 83% (296/616) of all outbreaks, but accounted for only 59·5% (616/1035) of outbreak cases (Table 1). The majority (89%) of family outbreaks were reported in private homes or in extended families; in general outbreaks, the most common setting was childcare (55·9%).

Table 1. VTEC outbreaks by location and type, Ireland 2004–2012

Table 2 shows a statistically significant difference in percentage of cases hospitalized by outbreak location. The lower hospitalization rates for childcare (12·2%) and commercial setting (4·5%) outbreaks are likely to reflect more active case finding that is possible within closed setting outbreaks. There was also a statistically significant difference in the number of persons laboratory investigated, laboratory confirmed, and the proportion of samples positive (yield) by outbreak location. Notably, the yield was lower for outbreaks in childcare facilities (10·5%) with 9·5 persons investigated on average per laboratory-confirmed case, reflecting to some extent the testing for clearance exclusion policy recommended during outbreaks in these settings.

Table 2. Number ill, hospitalized, laboratory-investigated and laboratory-confirmed by outbreak location, VTEC outbreaks Ireland 2004–2012

Hosp., Hospitalized; lab., laboratory; invest., investigations.

P values in bold denote significance at the 95% level

Organism

Sixty-six per cent of outbreaks were associated with VTEC O157, 25% with VTEC O26, with the remainder being due to other VTEC strains or a mixture of VTEC strains (Fig. 1). In tandem with increasing use of VTEC diagnostic methods which detect a broader range of VTEC serogroups (e.g. polymerase chain reaction, chromogenic agars, etc.), the number of outbreaks associated with non-O157 infections has increased over the study period. In 2004, all reported VTEC outbreaks were associated with serogroup O157, while in 2012, just under half of all reported outbreaks were associated with VTEC O157.

Fig. 1. Annual number of VTEC outbreaks by organism, Ireland 2004–2012.

Transmission routes

P-P spread accounted for 56% of outbreaks (123/219), waterborne transmission for 25%, foodborne for 10%, and animal contact/environmental exposure for 9% (Table 3). Waterborne outbreaks, however, were responsible for a higher proportion of outbreak cases at 34% (P = 0·043). P-P spread was the most common transmission route reported both in childcare (84%) and private house (59%) outbreaks. Waterborne and foodborne transmission were reported more frequently in community outbreaks and in outbreaks associated with commercial premises.

Table 3. Burden and characteristics of VTEC outbreaks by transmission route, Ireland 2004–2012

P-P, Person to person; env, environment; HSE, Health Service Executive; CI, confidence interval.

P values in bold denote significance at the 95% level

The overall 9-year outbreak incidence rate (number of outbreaks per 100 000 population) was 8·4 (95% confidence interval 7·5–9·2), being highest in the Health Service Executive-Midlands (HSE-M) and lowest in the largely urban HSE-East (HSE-E). This is consistent with national case-based VTEC notification data. Although the overall VTEC outbreak incidence was much lower than in all other HSE areas, foodborne transmission was the most common route reported in the HSE-E, whereas waterborne transmission was responsible for the highest proportion of outbreaks in the HSE-M.

Waterborne (±P-P) outbreaks

In the 55 waterborne VTEC outbreaks notified, 234 persons were reported ill. Household/extended family outbreaks predominated comprising 78% of waterborne outbreaks. Notably this was the most common reported transmission route for community outbreaks. Overall, the median number ill was 2 persons (range 1–42 persons).

Private wells were most commonly implicated (84%, n = 46 outbreaks). No waterborne outbreaks were identified which were associated with public water supplies. To assess the risk associated with home water supply, we have calculated the number of outbreak-associated illnesses associated with each supply type, and used this to estimate the risk of waterborne VTEC outbreak-associated disease by home drinking-water supply type. For this calculation, we have excluded one waterborne outbreak linked to a private well serving a commercial premises and an outbreak linked to exposure to a stream/river. The risk appears highest in private well users (Table 4).

Table 4. Risk of waterborne VTEC outbreak-associated disease by home drinking-water supply type, Ireland 2004–2012

* Assumes an average of 2·73 per household – based on census 2011 [13].

Includes private wells and the non-GWS private water scheme outbreak but excludes commercial premises outbreak (=148 + 27–42).

There was definitive/strong microbiological evidence for water as the source of illness for 22 outbreaks [i.e. isolates indistinguishable by pulsed-field gel electrophoresis (PFGE)], analytical epidemiological evidence alone for one further outbreak [Reference Mannix14], and both microbiological and analytical epidemiological evidence for one outbreak. In the remaining 31 (56%) outbreaks, descriptive epidemiological evidence alone was reported as implicating the water supply; in general with coliforms and/or E. coli detected, although in four of these outbreaks, VTEC was detected in the drinking water supply but the strain detected was not the same as that found in the human cases. While this did not provide definitive evidence implicating the drinking water source, it did provide circumstantial evidence that the water supply was either not adequately protected or treated against VTEC organisms.

The suspected source of contamination of the water supply was recorded for only two outbreaks; in both instances, animal faeces were reported as the source of contamination. The highest number of waterborne outbreaks notified was in 2012. Clustering of waterborne incidents in 2008 coincided with a period of exceptionally high rainfall [Reference O'Sullivan15]. Also of note were four community waterborne VTEC outbreaks in HSE-M during the summers of 2011 and 2012 [Reference Kelly16].

P-P outbreaks

The most common outbreak transmission route reported was P-P spread, with this being reported as the sole suspected transmission route for 55% of outbreaks. Eighty-two percent of P-P outbreaks occurred in private households, with a further 17% being associated with childcare – this was the most common reported transmission route for childcare outbreaks. Forty-eight percent of P-P outbreaks cases were aged <5 years, similar to the percentage for animal contact outbreaks, but higher than the percentage in waterborne outbreaks (38·9%), although this difference was not statistically significant (Table 3).

During the study period, there were 1925 laboratory-confirmed cases reported to the VTEC case notification system [3]. The number of laboratory-confirmed cases within 107 P-P outbreaks where this information was available was 389, suggesting that at a minimum, 389–107 = 282 of the laboratory-confirmed cases within these outbreaks were due to secondary transmission, or 14·6% (282/1925) of all laboratory-confirmed cases in Ireland. As many of the outbreaks where the primary route was reported as waterborne, foodborne or animal contact also had cases of secondary spread, this represents the minimum proportion of cases due to secondary transmission. The minimum number of laboratory-confirmed presumed primary cases which had secondary cases associated with them was 107/(1925–282) = 6·5%, and there were 2·6 secondary cases (282/107) for each primary case in P-P outbreaks.

P-P spread is particularly important in childcare outbreaks. Childcare outbreaks make up over half (56%) of all general VTEC outbreaks, and almost half (47%) of all general outbreak-associated cases. P-P spread was reported as the sole transmission route for 84% of childcare outbreaks and was responsible for 88% of all childcare outbreak cases. There were 5·8 secondary cases [(143–21)/21] for each of the primary cases in P-P childcare outbreaks.

Animal contact (±P-P) outbreaks

Between 2004 and 2012, animal contact or environmental exposure was reported as the suspected route of transmission for 9% of VTEC outbreaks, and just 7% of outbreak cases. The location was reported as private households for all outbreaks, with no pet farms or commercial animal venues implicated. The data collection on these outbreaks did not at the time systematically include information on the animal species or type of contact which was believed to have contributed to infection.

Foodborne (±P-P) outbreaks

Food was reported as a suspected transmission route for 10% of outbreaks, ranging in size from 1 to 7 persons ill (median 2 persons ill). Most (87%) were associated with private homes. No microbiological or analytical epidemiological evidence was reported implicating specific food items in any of these outbreaks. Suspected foods based on descriptive epidemiological evidence were reported for only four household outbreaks (minced beef for two outbreaks, and goat and lamb meat each for one outbreak), while a meal eaten out was suspected for one small travel-associated outbreak.

DISCUSSION

This is the first formal study in Ireland describing the relative importance of different outbreak transmission routes for VTEC infection. The data indicate that P-P transmission is a crucially important means of spread, both in private households and childcare settings. Outbreaks where P-P spread was reported as the sole transmission route accounted for more than half of all outbreaks and outbreak cases. When secondary transmission is ignored, the most significant primary transmission route was waterborne spread from untreated or poorly treated private water supplies.

This contrasts with the United States where foodborne transmission was reported as the most common means of spread for VTEC infection during outbreaks, with P-P spread as the second most common means of spread [Reference Rangel17, Reference Luna-Gierke18]. In addition, foodborne outbreaks constituted about one-third of VTEC outbreaks in the UK [Reference Gillespie19]. These differences almost certainly relate to variation in surveillance systems as well as true differences in risk.

The strengths of this study include first, unlike many outbreak surveillance systems, outbreaks are legally notifiable in Ireland, with a broad definition which includes household and general outbreaks. Second, the system includes outbreaks due to any transmission route, not just those transmitted by food and water. Third, thorough active case finding by public health personnel of VTEC cases increases the sensitivity of outbreak detection. Fourth, since 2010, all human VTEC isolates in Ireland have been typed not only by serotyping and verotoxin typing, but also by PFGE, ensuring that clusters not recognized by epidemiological investigations alone also come to the attention of authorities.

Potential limitations of the study include that the reported transmission routes were not always supported by strong evidence, many with descriptive epidemiological evidence only; this is particularly true for small household outbreaks where establishing strong evidence is often not possible. Second, certain desirable data are missing. For example, details on the animal species suspected as sources of infection for animal contact outbreaks were not systematically collected at the time of the study, although changes have been made to ensure that this information is collected routinely in future. Third, although considerably improved since then, laboratory diagnostic practice for non-O157 VTEC was variable during the period of the study, particularly in earlier years, resulting in probable under-diagnosis of non-O157 infections. This is a common feature of VTEC surveillance internationally. Therefore, it is not necessarily valid to compare the regional or temporal incidence of the reported VTEC outbreaks. Caution should also be exercised in interpreting the relative importance of different transmission routes temporally or geographically as it is possible VTEC O157 and non-O157 have different reservoirs and/or transmission routes. Fourth, it is likely that many P-P outbreaks were originally seeded by non-human sources of infection, although the sole transmission route reported was P-P.

In this study, P-P spread was most commonly identified in private household and childcare outbreaks, the latter also being the most common location reported for P-P outbreaks in the United States [Reference Rangel17]. P-P spread is well recognized as a transmission route for VTEC during outbreaks [Reference Fallon20Reference Weightman and Kirby23], and although known secondary cases are generally excluded from participation in most sporadic case-control study designs, contact with a person with diarrhoea was also recognized as a risk factor for VTEC infection and/or HUS in several risk factor studies [Reference Parry24Reference Rivas26].

At least 6·5% of VTEC cases resulted in onward transmission to others; this is slightly higher than the rate reported in a study by Parry et al. [Reference Parry24]. Our study does not examine the risk factors for secondary transmission, but the latter authors did find secondary transmission to be higher in households where the index case was not hospitalized, while Werber et al. showed the risk of secondary transmission in a household increased when the index case was aged <5 years, or when there was at least one sibling in the household [Reference Werber10].

In our study, waterborne transmission of VTEC infection was the most significant mode of primary VTEC transmission, being associated with several untreated or poorly treated private water supplies. Ireland's location in the west of Europe ensures it has a wet, maritime climate, making agricultural land well-suited to livestock farming. Ireland has the third highest cattle density among EU Member States [2]. Moreover, in Ireland, 10% of private homes are served by domestic wells [13]; in many instances these are untreated, and are outside the scope of water regulation as they serve fewer than 50 persons or produce <10 m3/day, and do not serve a commercial activity. A further 12% of private homes are served by small private water schemes managed by trustees, private individuals or companies. Many of these schemes also fall outside the scope of water regulations for the same reason, although all water supplies which serve a commercial use fall within the scope of the water regulations regardless of supply type (including private wells) or size. Even for private water supplies that are covered by water regulations, the quality is reported to be generally inferior to that of public water supplies [27].

Water is a particularly effective medium for dissemination of gastrointestinal pathogens [7], and has the potential to infect large numbers of people. Untreated or poorly managed water supplies, especially those drawing their source water from areas close to livestock farming, are likely to present significant risk. A combination of a high reliance on private domestic wells and a high cattle density is likely to have contributed to Ireland's high waterborne VTEC incidence.

Foodborne outbreaks were reported infrequently in the Irish dataset, but may be underestimated as evidence that an outbreak is foodborne can be difficult to establish. In addition to the 21 outbreaks suspected to be foodborne, there were at least four general VTEC outbreaks reported to be associated with commercial premises with unknown transmission route, and it is possible that some or all of these were foodborne although other transmission routes could not be ruled out by the outbreak investigation teams.

We acknowledge that the risk factors that lead to outbreaks may differ from sporadic cases. Food, in particular undercooked hamburger/minced beef and raw milk/milk products, were identified as key risk factors in case-control studies elsewhere [Reference Parry24, Reference Rivas26, Reference Voetsch28Reference Slutsker31]. Similarly, direct animal contact was a minor contributor to the burden of VTEC outbreaks in Ireland, although it is possible that it has a greater role in sporadic disease [Reference Parry24, Reference Rivas26, Reference Voetsch28, Reference Kassenborg29].

Recommendations

In the first instance, the focus for reducing incidence should be on reducing waterborne and P-P transmission (particularly in childcare facilities). Active follow-up of childcare facilities attended by VTEC cases should remain a key public health intervention given the potential for transmission in these settings, because of the less developed hygiene skills of small children and the higher vulnerability of this group to more severe disease such as haemolytic uraemic syndrome (HUS) (historically 5–8% of VTEC cases in Ireland have been reported as HUS). In Ireland, 42% of families in the general population use non-parental childcare [32]. The Health Protection Surveillance Centre has published national guidance for crèche owners, and management in the prevention of infectious disease spread in childcare facilities [33], and for public health professionals on the management of VTEC cases and outbreaks in childcare facilities [34] in 2012 and 2013, respectively.

The evidence here suggests that private sources of water present a risk to public health when they have not been designed and managed appropriately, and those responsible should be mindful of the requirements for their maintenance and protection. In 2013, the HSE published a leaflet for well owners outlining the infectious disease risks associated with drinking water from private wells, providing advice on actions that can be taken including: checking the supply, water testing and treatment, and what to do in the event the well water is found to be contaminated [35].

Efforts in Ireland should focus, initially, on publicizing these materials and ensuring that they are widely available. Given international evidence on the potential for outbreaks due to food and animal contact, advice should also continue to be provided to food businesses [36], open farms and farm families [37, 38, 45]. Longer term objectives could include strategies which reduce the VTEC prevalence in the farm animal population and in the environment, e.g. husbandry and hygiene practices proven to reduce carriage [Reference Ellis-Iversen39] or cattle vaccination [Reference Matthews40], as it is likely that these serve as an important reservoir for VTEC infection in Ireland.

ACKNOWLEDGEMENTS

The authors acknowledge the cooperation of clinicians, laboratory directors, microbiologists, medical scientists, specialists in public health medicine, senior medical officers, surveillance scientists, infection control nurses, and (principal) environmental health officers in providing the dataset on which this report is based.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. Pennington, H. Escherichia coli O157. Lancet 2010; 376: 14281435.Google Scholar
2. European Food Safety Authority and European Centre for Disease Control and Prevention. The European Union summary report on trends and sources of zoonoses, zoonotic agents and food-borne outbreaks in 2012 (http://www.efsa.europa.eu/en/efsajournal/doc/3547.pdf). Accessed 15 July 2014.Google Scholar
3. Health Protection Surveillance Centre. Annual Report 2012. December 2013 (http://www.hpsc.ie/AboutHPSC/AnnualReports/File,14421,en.pdf). Accessed 15 July 2014.Google Scholar
4. Buchholz, U, et al. German outbreak of Escherichia coli O104:H4 associated with sprouts. New England Journal of Medicine 2011; 365: 17631770.Google Scholar
5. Cowden, JM, et al. Epidemiological investigation of the central Scotland outbreak of Escherichia coli O157 infection, November to December 1996. Epidemiology and Infection 2001; 126: 335341.Google Scholar
6. Centers for Disease Control and Prevention (CDC). Ongoing multistate outbreak of Escherichia coli serotype O157:H7 infections associated with consumption of fresh spinach – United States, September 2006. Morbidity and Mortality Weekly Report 2006 55; 38: 10451046.Google Scholar
7. Bruce-Grey-Owen Sound Health Unit. The investigative report on the Walkerton outbreak of waterborne gastroenteritis. May-June, Owen Sound. October 2000 (http://www.publichealthgreybruce.on.ca/Water/Public_Drinking/Walkerton/Report/REPORT_Oct00.PDF). Accessed 15 July 2014.Google Scholar
8. Swerdlow, DL, et al. A waterborne outbreak in Missouri of Escherichia coli O157:H7 associated with bloody diarrhea and death. Annals of Internal Medicine 1992; 117: 812819.CrossRefGoogle ScholarPubMed
9. Health Protection Agency. Review of the major outbreak of E. coli O157 in Surrey, 2009 (http://www.hpa.org.uk/webw/HPAweb&HPAwebStandard/HPAweb_C/1317135574117). Accessed 15 July 2014.Google Scholar
10. Werber, D, et al. Preventing household transmission of Shiga toxin-producing Escherichia coli O157 infection: promptly separating siblings might be the key. Clinical Infectious Diseases 2008; 46: 11891196.Google Scholar
11. Parry, SM, Salmon, RL. Sporadic STEC O157 infection: secondary household transmission in Wales. Emerging Infectious Diseases 1998; 4: 657661.Google Scholar
12. Central Statistics Office. Census 2006 principal demographic results. (http://www.cso.ie/en/media/csoie/census/documents/Amended,Final,Principal,Demographic,Results,2006.pdf). Accessed 15 July 2014.Google Scholar
13. Central Statistics Office. Census 2011, Profile 4, The roof over our heads – housing in Ireland (http://www.cso.ie/en/media/csoie/census/documents/census2011profile4/Profile,4,The,Roof,over,our,Heads,Full,doc,sig,amended.pdf). Accessed 15 July 2014.Google Scholar
14. Mannix, M, et al. Large outbreak of E. coli O157 in 2005, Ireland. Eurosurveillance 2007; 12: 2 Google Scholar
15. O'Sullivan, MB, et al. Increase in VTEC cases in the south of Ireland: link to private wells? Eurosurveillance 2008; 13: pii:18991.Google ScholarPubMed
16. Kelly, I, et al. Waterborne verotoxin producing Escherichia coli outbreaks in the Irish Midlands 2011 and 2012. Abstracts of the Five Nations Health Protection Conference, 14 and 15 May 2013 Dublin. 2013. Abstract O5-1 (http://5nations.org.uk/wp-content/uploads/2013/06/5-Nations-Health-Protection-Conference-Final-Programme.pdf). Accessed 15 July 2014.Google Scholar
17. Rangel, JM, et al. Epidemiology of Escherichia coli O157:H7 Outbreaks, United States, 1982–2002. Emerging Infectious Diseases 2005; 11: 603609.Google Scholar
18. Luna-Gierke, RE, et al. Outbreaks of non-O157 Shiga toxin-producing Escherichia coli infection: USA. Epidemiology and Infection 2014: 142: 22702280.Google Scholar
19. Gillespie, IA, et al. Foodborne general outbreaks of Shiga toxin-producing Escherichia coli O157 in England and Wales 1992–2002: where are the risks? Epidemiology and Infection 2005; 133: 803808.Google Scholar
20. Fallon, U, et al. Verotoxin producing Escherichia coli O26 and Haemolytic Uraemic Syndrome in two child care facilities; a community outbreak in rural Ireland May 2012 Abstracts of the Five Nations Health Protection Conference, 14 and 15 May 2013, Dublin. 2013. Abstract O1-2 (http://5nations.org.uk/wp-content/uploads/2013/06/5-Nations-Health-Protection-Conference-Final-Programme.pdf). Accessed 15 July 2014.Google Scholar
21. Reiss, G, et al. Escherichia coli O157:H7 infection in nursing homes: review of literature and report of recent outbreak. Journal of the American Geriatric Society 2006; 54: 680684.Google Scholar
22. Pavia, AT, et al. Hemolytic-uremic syndrome during an outbreak of Escherichia coli O157:H7 infections in institutions for mentally retarded persons: clinical and epidemiologic observations. Journal of Pediatrics 1990: 116: 544551.Google Scholar
23. Weightman, NC, Kirby, PJG. Nosocomial Escherichia coli O157 infection. Journal of Hospital Infection 2000; 44: 107111.Google Scholar
24. Parry, SM, et al. Risk factors for and prevention of sporadic infections with vero cytotoxin (shiga toxin) producing Escherichia coli O157. Lancet 1998; 351: 10191022.Google Scholar
25. Rowe, PC, et al. Risk of hemolytic uremic syndrome after sporadic Escherichia coli O157:H7 infection: results of a Canadian collaborative study. Investigators of the Canadian Pediatric Kidney Disease Research Center. Journal of Pediatrics 1998; 132: 777782.Google Scholar
26. Rivas, M, et al. Risk factors for sporadic Shiga toxin-producing Escherichia coli infections in children, Argentina. Emerging Infectious Diseases 2008; 14: 763771.Google Scholar
27. Environmental Protection Agency. The provision and quality of drinking water in Ireland 2012 (http://www.epa.ie/pubs/reports/water/drinking/drinkingwaterreport2011.html). Accessed 15 July 2014.Google Scholar
28. Voetsch, AC, et al. Risk factors for sporadic Shiga toxin-producing Escherichia coli O157 infections in FoodNet sites, 1999–2000. Epidemiology and Infection 2007; 135: 9931000.Google Scholar
29. Kassenborg, HD, et al. Emerging Infections Program FoodNet Working Group. Farm visits and undercooked hamburgers as major risk factors for sporadic Escherichia coli O157:H7 infection: data from a case-control study in 5 FoodNet sites. Clinical Infectious Diseases 2004; 38 (Suppl. 3): S271278.Google Scholar
30. Mead, PS, et al. Risk factors for sporadic infection with Escherichia coli O157:H7. Archives of Internal Medicine 1997; 157: 204208.Google Scholar
31. Slutsker, L, et al. A nationwide case-control study of Escherichia coli O157:H7 infection in the United States. Journal of Infectious Diseases 1998; 177: 962966.Google Scholar
32. Central Statistics Office. 2009. Quarterly National Household Survey. Childcare. Quarter 4, 2007 (http://www.cso.ie/en/media/csoie/releasespublications/documents/labourmarket/2007/childcareq42007.pdf). Accessed 15 July 2014.Google Scholar
33. Health Protection Surveillance Centre. Preschool and Childcare Facility Subcommittee. 2012. Management of infectious disease in childcare facilities and other childcare settings (http://www.hpsc.ie/hpsc/A-Z/LifeStages/Childcare/). Accessed 15 July 2014.Google Scholar
34. Health Protection Surveillance Centre. VTEC (Verocytoxigenic E. coli) in childcare facilities: decision support tool for public health (http://www.hpsc.ie/hpsc/A-Z/Gastroenteric/VTEC/Guidance/ReportoftheHPSCSub-CommitteeonVerotoxigenicEcoli/File,4559,en.pdf). Accessed 15 July 2014.Google Scholar
35. Health Service Executive. Leaflet on the Risk of illness from well water (http://www.lenus.ie/hse/bitstream/10147/294332/1/Leaflet_Precautions%20and%20advice%20for%20reducing%20risk%20of%20illness%20from%20well%20water.pdf). Accessed 15 July 2014.Google Scholar
36. Food Safety Authority of Ireland. 2010. The Prevention of Verocytotoxigenic Escherichia coli (VTEC) Infection: A Shared Responsibility, 2nd edn. (http://hdl.handle.net/10147/132550). Accessed 15 July 2014.Google Scholar
37. Health Protection Surveillance Centre. Recommendations to prevent VTEC on open/pet farms and recommendations on the recreational use of farmland to reduce the Risk of VTEC (http://www.hpsc.ie/A-Z/Gastroenteric/VTEC/Guidance/). Accessed 15 July 2014.Google Scholar
38. Health Service Executive. South East Zoonoses Committee. Staying healthy on your farm (http://www.zoonoses.ie/public/publications/Staying_Healthy_on_your_Farm.pdf). Accessed 15 July 2014.Google Scholar
39. Ellis-Iversen, J, et al. Farm practices to control E. coli O157 in young cattle – a randomized controlled trial. Veterinary Research 2008; 39: 3.CrossRefGoogle Scholar
40. Matthews, L, et al. Predicting the public health benefit of vaccinating cattle against Escherichia coli O157′, Proceedings of the National Academy of Sciences USA 2013; 10: 1626516270.Google Scholar
Figure 0

Table 1. VTEC outbreaks by location and type, Ireland 2004–2012

Figure 1

Table 2. Number ill, hospitalized, laboratory-investigated and laboratory-confirmed by outbreak location, VTEC outbreaks Ireland 2004–2012

Figure 2

Fig. 1. Annual number of VTEC outbreaks by organism, Ireland 2004–2012.

Figure 3

Table 3. Burden and characteristics of VTEC outbreaks by transmission route, Ireland 2004–2012

Figure 4

Table 4. Risk of waterborne VTEC outbreak-associated disease by home drinking-water supply type, Ireland 2004–2012