Abstract
Norovirus (NoV) is the commonest cause of gastrointestinal disease in the United Kingdom and in many developed countries, causing diarrhea and vomiting in millions of cases worldwide annually. Transmission is most often mediated from person to person. NoV infection has, however, additionally been associated with the consumption of food, either through the consumption of food contaminated at source such as seafood, berries, and salad, or as a consequence of the foodstuff being contaminated in some way by a food handler during processing or serving. A systematic review of outbreaks attributed to NoV between January 2003 and July 2017 was conducted to assess the contribution of food handlers to the burden of NoV, and to identify foods commonly associated with NoV outbreaks. A total of 3021 articles were screened, of which 27 met the definition of confirmed foodborne outbreaks and 47 met the criteria for definite food-handler NoV outbreaks. Of all food types, shellfish were implicated in the greatest number of definite foodborne outbreaks. Food handlers contributed to definite food-handler outbreaks involving a diverse range of foodstuffs and in a wide variety of settings, including weddings and military establishments. More genotypes of NoV were found in people who were ill than in samples from food and food handlers. The potential for both food products and food handlers to contribute to the burden of NoV infection is demonstrated conclusively.
Keywords: : foodborne, food handler, norovirus, outbreaks
Background
Norovirus (NoV) is the leading cause of acute gastroenteritis worldwide (Scallan et al., 2011; Tam et al., 2012; Al-Thani et al., 2013) and leads to sudden onset vomiting and diarrhea. Symptoms usually last for 2 to 4 days (Graham et al., 1994; Rockx et al., 2002; Lopman et al., 2004) in healthy adults (Murata et al., 2007). Symptom duration can be longer in hospitalized patients (Lopman et al., 2004; Murata et al., 2007; O'Ryan et al., 2010). Asymptomatic and symptomatic individuals excrete NoV and can transmit it to other people (Akihara et al., 2005; Huynen et al., 2013; Krumkamp et al., 2015). Asymptomatic individuals tend to shed NoV in smaller amounts than symptomatic individuals (Bernstein et al., 2015). Viral shedding can occur for 3–14 h before symptom onset (Atmar et al., 2008). Cases who are immunocompromised, elderly, and newborn infants can shed virus longer than healthy adults (Atmar et al., 2008). Peak shedding is from 2 to 5 days postinfection (Graham et al., 1994; Atmar et al., 2008; Kirby et al., 2014). The virus survives on fomites, for example, in care homes (Wu et al., 2005) and hospitals (Nenonen et al., 2014). NoV has experimentally survived on surfaces for extended periods of time, enabling long periods of potential exposure (Lamhoujeb et al., 2009; Liu et al., 2009).
Infection with NoV occurs through ingestion, either through contact with NoV in the environment or directly from contaminated food or water. Water samples contaminated with NoV have caused illness in subjects up to 2 months postcontamination (Seitz et al., 2011). Sewage-contaminated water supplies containing NoV have been implicated in large outbreaks, for example, in Nokia, Finland (Rasanen et al., 2010). Food is contaminated indirectly, for example, through sewage being discharged in areas where seafood is farmed (Le Guyader et al., 2008) or from contaminated irrigation water (El-Senousy et al., 2013). It may also be contaminated directly through the hands of infected agricultural workers. For example, Leon-Felix et al. (2010) demonstrated contamination of peppers in the field and on the hands of pickers, classifiers, and packers. Furthermore, a food handler who returns to work after acute symptoms of NoV infection have subsided but before the infectious period has ended runs the risk of contaminating food products through unsterile practices during preparation (Parashar et al., 1998). The presence of NoV on the hands of food handlers means that it can easily be transferred to and between utensils, work surfaces, and food (Sharps et al., 2012; Stals et al., 2013a; Tuladhar et al., 2013; Verhaelen et al., 2013; Ronnqvist et al., 2014).
The aim of this review was to assess the contribution of particular foods to definitively foodborne outbreaks of NoV, and to describe the contribution of food handlers to NoV outbreaks.
Methods
Literature search
The search window was from January 2003 to July 2017. Databases and websites searched were as follows: Web of Science, Medline, Embase, Biosis previews, CABI (CAB Abstracts® and Global Health®), Scopus, Biomed Central, ScienceDirect, OpenSIGLE, Proquest Dissertations and Theses A&I, Foodbase website, Public Health England through www.gov.uk, Cefas through the Defra website, and the World Health Organization website.
The databases, dates of use, and number of articles retrieved are appended in Supplementary Table S1 (Supplementary Data are available online at www.liebertpub.com/fpd). The full list of search terms used for each database search is included in Supplementary Data S1 “Search strategies.” For example, the search terms used for Web of Science were as follows: TOPIC: (norovirus or norwalk or winter vomiting or noroviral) and TOPIC: (foodborne or food-borne or orofecal or orofaecal or sewage or irrigation or hand* or hotel or restaurant* or catering or cook* or waiter* or cruise or canteen or contaminat* or aerosol* or spray* or toilet* or latrine* or utensil* or kitchen* or shellfish or fish* or mussel* or oyster* or strawber* or raspberr* or lettuce or salad* or vegetable* or green* or fruit* or ice or blueberr* or onion* or tomato*).
Study inclusion criteria
All titles and abstracts were screened by at least two reviewers. Articles were assessed for inclusion by one reviewer. A subsample of titles was then selected at random, and the decision to include or exclude each article was cross-validated by two reviewers.
If an article describing a given outbreak provided formal evidence of laboratory confirmation of NoV infection in both human cases and foodstuffs, that outbreak was classed as definitely foodborne.
If a report describing a given outbreak included laboratory confirmation of infection in both patrons and food handlers, with either the same strain being identified in either handlers or cases, or in handlers and in foods consumed by cases, that outbreak was classified as definitively attributed to food handlers. Genotypes of strains found in food handlers and foods were reported where possible.
Data collection
Data from each article were collated into a single data abstraction sheet (Supplementary Data S2). In brief, for studies of foodborne infection, information was collected about foods implicated and number of samples taken. For food-handler studies, information was collected on settings, foods handled, and, where possible, number and types of samples tested from food handlers and NoV genotypes.
Analyses
We calculated the proportion of foodstuffs and people in which NoV was detected and described the genogroups and genotypes present, where recorded. The heterogeneity between articles in terms of study design, timeframes, and study populations prohibited a formal statistical meta-analysis; however, descriptive statistics (proportions, medians, and interquartile ranges) were calculated for data extracted from articles that met the inclusion criteria.
Results
Literature search
A total of 9880 articles were originally retrieved from the search strategies (Supplementary Table S1). A total of 6859 article duplicates were removed, leaving 3021 articles to screen. Of these 2933 (97%) did not meet the inclusion criteria and were excluded because they were review articles or they concentrated on diagnostics, artificial contamination, efficacy of decontamination, etiology, and outbreak control; 66 (2.2%) article were duplicates; 13 (0.4%) articles had information found in other articles; and 2 references (0.06%) were incorrect and the articles could not be found (Fig. 1).
FIG. 1.
Article selection process.
Twenty-seven articles met the criteria for inclusion as NoV -definite foodborne outbreaks document 36 separate incidents. The citations are included in Supplementary Data S3.
Outbreaks that met the definition for definite food-handler outbreaks of NoV were identified in 47 articles documenting 51 different outbreaks, the citations can be found in Supplementary Data S4. The Rasmussen 2016 article described an aggregated outbreak report from nine different venues but did not provide any further information that could individualize each outbreak, hence it is included as one aggregate outbreak.
One article had information that was relevant to both foodborne and food-handler outbreaks (Baker et al., 2011) (Fig. 1).
NoV foodborne outbreaks
NoV foodborne outbreaks were reported from around the globe; however, the largest proportion (57%) was reported in Europe. Of all studies, the most commonly implicated food vehicle in outbreaks was seafood (61%), of which 89% were oysters (Table 1).
Table 1.
Food Implicated in Foodborne Norovirus Outbreaks
Country/Food | Clams | Lettuce | Mussels | Oysters | Raspberries | Shellfish |
---|---|---|---|---|---|---|
Australia | 1 | |||||
Canada | 1 | |||||
Denmark | 1 | |||||
Finland | 1 | |||||
France | 3 | |||||
Italy | 1 | |||||
Italy and France | 1 | |||||
Japan | 1 | 1 | ||||
New Zealand | 2 | |||||
Singapore | 1 | |||||
Sweden | 1 | 1 | ||||
United Kingdom | 1 | |||||
United States | 2 | |||||
France, Italy | 1 | |||||
Denmark, France, and United Kingdom | 1 |
The number of people exposed to NoV in each outbreak ranged from 2 (Muller et al., 2016) to 1580 people (Simmons et al., 2007), with a median of 59 people. The number of people falling ill ranged between 2 (Muller et al., 2016) and 305 (Ng et al., 2005) (median = 23 people). The number of ill people providing samples for testing was between 1 (David et al., 2007; Fitzgerald et al., 2014) and 42 (Le Guyader et al., 2006) (median = 8 people). The median (interquartile range) for the proportion of NoV-positive samples was 79% (52–100%), with the median number of positive samples being 3 (range = 1–24) (Prato et al., 2004; David et al., 2007; Nenonen et al., 2009; Institute of Environmental Science and Research, 2011; Centers for Disease Control and Prevention, 2012; Fitzgerald et al., 2014; Muller et al., 2016).
Most commonly, the NoV genotypes found in food (Table 2) and patrons (Supplementary Table S2) were mixed. Supplementary Tables S2 and S3 indicate that a greater diversity of genotypes was recovered from people affected by the implicated foods than from the foods themselves. The most common genotypes include GII.4 recovered from food and GII.4, GI.4, GI.1, and GI.2 identified from people infected in foodborne outbreaks.
Table 2.
Settings and Foods Handled in Food Handler-Associated Norovirus Outbreaks
Food handled/setting | Bakery | Birthday party | Care home | Caterer | College | Healthcare facility | Hotel | Military base | Restaurant | School | Staff canteen | Tourists | Wedding |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Aemono sauce | 1 | ||||||||||||
Antipasti and garlic mashed potatoes | 1 | ||||||||||||
Bakery products | 1 | 1 | 1 | 1 | |||||||||
Cold sausage; meat dish with salad and a rolled spinach pancake | 1 | ||||||||||||
Cold shredded chicken set meal | 1 | ||||||||||||
Egg mayonnaise; sandwiches. | 1 | ||||||||||||
Mushroom dish | 1 | ||||||||||||
Paella and beef | 1 | ||||||||||||
Sandwiches | 1 | ||||||||||||
Sandwiches and vegetation | 1 | ||||||||||||
Seafood | 3 | ||||||||||||
Seafood, lamb, and crème brulee | 1 | ||||||||||||
Seafood, passion fruit, and lavender dish | 1 | ||||||||||||
Seafood, spiced chicken, and noodle salad | 1 | ||||||||||||
Standard hospital diet | 1 | ||||||||||||
Unknown | 1 | 1 | 1 | 1 | 3 | 2 | 2 | 1 | |||||
Vegetation | 1 | 1 | 1 | 3 | |||||||||
Vegetation, water fountain | 1 | ||||||||||||
Vegetation, Sara Udon noodles | 1 |
Many studies were outbreak reports and had used genotyping and attack rates to determine transmission route. However, 15 of 27 articles included the odds and risk ratios of foods implicated in associated outbreaks (Supplementary Table S3). The risk factors were predominantly seafood related.
NoV food-handler outbreaks
Food-handler outbreaks occurred in a wide variety of settings (Table 2). The most common setting was restaurants (12/51 outbreaks). In 33% of food-handler outbreaks, implicated food items were not categorized. When they were categorized, the most common, associated with 20% of outbreaks, were salad and vegetables, followed by dishes containing seafood (Supplementary Table S4). The number of patrons with NoV varied from 3 (Sala et al., 2009; Baker et al., 2011; Made et al., 2016) to 660 (Hirakata et al., 2005).
Food handling (mostly kitchen) staff were sampled for NoV in 44 of 51 (86%) outbreaks. The median proportion of positive samples obtained from food handlers was 46% (interquartile range of 25–76%).
The most common genotype recovered from food handlers (Supplementary Table S5) and people whose illness was associated with food handlers (Table 3) was GII.4.
Table 3.
The Odds and Risk Ratios Calculated in Studies Describing Foodborne Norovirus Outbreaks
Author | Year | Risk factor(s) | Odds ratio (95% confidence interval) |
---|---|---|---|
Doyle et al. | 2004 | Oysters | 55.3 (2.9–1058.7) |
Prato et al. | 2004 | Cooked mussels | 1.5 (1.05–2.23) |
Prato et al. | 2004 | Cooked mussels | 3.04 (1.26–7.30) |
Prato et al. | 2004 | Raw mussels | 1.38 (1–1.91) |
Prato et al. | 2004 | Raw musels | 1.5 (1.18–1.89) |
Ng et al. | 2005 | Oysters | 18.3 (9.9–33.2) |
Simmons et al. | 2007 | Oysters | 11.9 (3.9–36.1) |
Simmons et al. | 2007 | Salmon contaminated by oysters | 2.3 (1.2–4) |
Simmons et al. | 2007 | Tuatuas | 3 (1.7–5.6) |
Simmons et al. | 2007 | Seafood chowder | 2.5 (1–6.3) |
Webby et al. | 2007 | Grilled oysters | 17 (5–51) |
Webby et al. | 2007 | Oyster cocktails | 35 (5–243) |
Liko et al. | 2009 | Oysters | 11.8 (2–50) |
Maunula et al. | 2009 | Frozen raspberries | 3 |
Ethelberg et al. | 2010 | Lettuce | 6.2 (1–38) |
NZ public health surveillance | 2011 | Oysters at a wedding | 8.5 (2.3–31.3) |
Baker et al. | 2011 | Oysters | (11.7-inf) |
Baker et al. | 2011 | Lamb | (3.8-inf) |
Baker et al. | 2011 | Crème brulee | 16.8 (1.3–825.9) |
Viriot et al. | 2011 | Late cases—oysters | 32.22 (7.09–146.34) |
Viriot et al. | 2011 | Early cases—oysters | 2.68 (1.36–5.27) |
Viriot et al. | 2011 | Early cases—knuckle of ham | 3.75 (1.91–7.35) |
Muller et al. | 2016 | Salmon and leafy greens | 7.7 (2.2–27) |
Park et al. | 2015 | Raw seaweed with vinegar and radish | 7.9 (1.1–56.2) |
Park et al. | 2015 | Seasoned green seaweed with pears | 5.1 (1.1–24.8) |
Park et al. | 2015 | School A: cabbage kimchi (lunch) | 4.56 (2.96–7.02) |
Park et al. | 2015 | School A: spicy potato stew (lunch) | 1.78 (1.05–3.02) |
Park et al. | 2015 | School A: cabbage kimchi (dinner) | 1.9 (1.39–2.60) |
Park et al. | 2015 | School B: cabbage kimchi | 2.26 (1.24–4.15) |
Park et al. | 2015 | School C: kimchi | 2.10 (1.68–2.63) |
Park et al. | 2015 | School C: water | 1.56 (1.17–2.08) |
Park et al. | 2015 | School C: jajangbap, rice and Chinese bean sauce | 3 (1.48–6.09) |
Park et al. | 2015 | School C: bean paste soup with tofu | 1.23 (1.01–1.50) |
Park et al. | 2015 | School C: sweet and sour pork and salad | 3.08 (1.59–5.98) |
Park et al. | 2015 | School C: tangerine juice | 2.55 (1.37–4.74) |
Le Guyader et al. | 2008 | Oysters | 4.5 (1.6–13.3) |
Many food-handler outbreaks had more than one risk factor (Table 4); some focused on a time or place that an exposure occurred, whereas others implicated consumers' dishes that food handlers handled (Table 4).
Table 4.
The Odds and Risk Ratios Calculated in Studies About Food-Handler Norovirus Outbreaks
Author | Year | Risk factor(s) | Odds or risk ratio (95% confidence interval) |
---|---|---|---|
Wadl et al. | 2010 | Salad | 8.1 (1.5–45.4) |
Zomer et al. | 2010 | Eating tomatoes | 5.6 (3.2–9.6) |
Cai et al. | 2013 | Eating restaurant A | 3.46 (1.07–11.16) |
Cai et al. | 2013 | Cold shredded chicken set meal | 17.82 (4.46–78.17) |
Ruan et al. | 2013 | Unknown | 12 (5.4–28) |
Friedman et al. | 2005 | Wedding cake with strawberry filling | 9.3 (6.2–13.8) |
Baker et al. | 2011 | Oysters | (11.7-inf) |
Baker et al. | 2011 | Lamb | (3.8-inf) |
Baker et al. | 2011 | Crème brulee | 16.8 (1.3–825.9) |
Godoy et al. | 2016 | Eating in canteen | 5.8 (1.8–19.3) |
Lin et al. | 2015 | Eating a kebab | 6.7 (3.4–28) |
Sanchez et al. | 2017 | Cake | 10.1 (1.2–81.6) |
Sanchez et al. | 2017 | Pizza | 3.6 (1.1–11.9) |
Godoy et al. | 2005 | Sandwiches | 2.3 (1.1–5.1) |
DeWit et al. | 2007 | Bread rolls | 2 (1.6–2.4) |
Hirakata et al. | 2005 | Sara Udon | 3.1 (1.1–8.7) |
Hirakata et al. | 2005 | Spring roll | 2.3 (1.1–4.7) |
Hirakataet al. | 2005 | Broccoli | 2.4 (1.2–4.6) |
Centers for Disease Control | 2006 | Scalloped potatoes | 2.8 (1.1–6.9) |
Centers for Disease Control | 2006 | Chicken | 2.2 (1.0–4.8) |
Centers for Disease Control | 2006 | Self-reported direct contact ill people | 2.3 (1.0–5.0) |
Centers for Disease Control | 2007 | Antipasti platter | 2.96 (1.08–8.14) |
Centers for Disease Control | 2007 | Garlic mashed potatoes | 4.05 (1.37–11.99) |
Schmid et al. | 2007 | Food exposure Wednesday | 18.81 (11.82–29.96) |
Schmid et al. | 2007 | Food exposure Thursday | 2.14 (1.65–2.79) |
Schmid et al. | 2007 | Salad | 2.82 (1.0–7.94) |
Showell et al. | 2007 | Eating salad on day 1 | 74 (8–1685) |
Showell et al. | 2007 | Eating salad on day 2 | 27 (6–138) |
Ohwaki et al. | 2009 | Eating standard diet (workers) | 18.13 (5.76–57.03) |
Ohwaki et al. | 2009 | Eating standard diet (patients) | 2.12 (1.05–4.31) |
Nicolay et al. | 2011 | Egg mayonnaise sandwich | 2.3 (1.4–3.9) |
Nicolay et al. | 2011 | Turkey and stuffing sandwich | 1.9 (1.2–3.2) |
Nicolay et al. | 2011 | Chicken sandwich | 1.9 (1.1–3.1) |
Schmid et al. | 2011 | Sliced pork with salad | 1.8 (1.1–2.99) |
Schmid et al. | 2011 | Rolled pancake filled with spinach | 1.86 (1.19–2.93) |
Smith et al. | 2012 | Oyster, passion fruit, and lavender dish | 7 (1.1–45.2) |
Maritschnik et al. | 2013 | Females eating a mushroom dish | 2.3 (1.21–4.34) |
Ruan et al. | 2013 | Eating delicatessen food from a shop on 14 November | 9.7 (2.6–36) |
Ruan et al. | 2013 | Eating delicatessen food from a shop on 15 November | 8.8 (3.2–24) |
Thornley et al. | 2013 | Italian sushi | 3.4 (1.2–9.5) |
Thornley et al. | 2013 | Consuming food prepared manually | 6.6 (2.2–39.2) |
Thornley et al. | 2013 | Attending an event before 11.45 a.m. | 7.2 (24.–43.2) |
Kimura et al. | 2012 | Eating on 23 March | 18.1 (9.2–35.4) |
Liu et al. | 2015 | Roasted duck | 4.94 (2.01–12.35) |
Raj et al. | 2017 | Event two: prawn salad | 3.92 (1.39–11.08) |
Raj et al. | 2017 | Event two: chicken simmered in wine | 3.92 (1.39–11.08) |
Raj et al. | 2017 | Event three: spring rolls | 11.52 (4.31–30.79) |
Raj et al. | 2017 | Event six: prawn salad | 11.07 (1.33–92.46) |
Raj et al. | 2017 | Event six: spicy jelly fish | 15.58 (4.41–55.13 |
Raj et al. | 2017 | Event six: deep fried prawn | 5.45 (1.43–20.72) |
Smith et al. | 2017 | Ham hock | 6.62 (2.19–20.03) |
Watier-Grillot et al. | 2017 | Shrimp salad | 2.6 (1.2–6.0) |
Watier-Grillot et al. | 2017 | Pasta salad | 2.9 (1.3–6.4) |
Centers for Disease Control | 2007 | Mashed potatoes | 2.4 (1.0–5.4) |
Discussion
Findings
Oysters and other types of seafood dominated the list of foodstuffs tested for NoV after clinical illness, and it is not clear whether this is a genuine food-related effect, or a consequence of various factors. First, investigator bias may arise because of a long-established association between seafood (Murphy et al., 1979) and NoV. Second, seafood may additionally dominate food sources in our review because of the availability of oysters for testing from batches implicated in outbreaks. This is unlike salad and berries, which are likely to perish or be consumed in their entirety more quickly. Finally, the dominance of seafood may be because of virus particles attaching more easily to seafood than to salad and berries (Tian et al., 2011). Lettuce and raspberries are also implicated in a number of outbreaks, reflecting contamination of food through roots as a result of contaminated irrigation water (Dicaprio et al., 2012; Hirneisen, 2012), contamination by food handlers, or a combination of both.
European law states that food handlers should notify their employers if they are ill and that no toxins should be shed where food is present (European Union 2004). Current advice suggests that food handlers suffering from gastroenteritis should stay away from work for a further 48 h, once the symptoms have disappeared (Food Standards Agency, 2009). Despite this, because of prodromal, prolonged, and asymptomatic shedding, there is the potential for both symptomatic and asymptomatic individuals to contaminate the workplace. In a study by Sabria et al. (2016), food handlers and healthcare workers were sampled in workplaces where NoV outbreaks had occurred. In total, 59.1% of workers were found to be excreting NoV and around 70% of those NoV excreters were classed as asymptomatic (Sabria et al., 2016). Sabria et al. (2016) also demonstrated that both asymptomatic and symptomatic food workers shed virus for up to 3 weeks postoutbreak exposure (Sabria et al., 2016). Some articles in our review described workers becoming ill at work, resulting in workplace contamination (which could have made it easier to determine the cause of an outbreak) (Centers for Disease Control Prevention, 2007; Baker et al., 2011; Maritschnik et al., 2013; Thornley et al., 2013). Some food handlers, however, were not ill but were found to be shedding the virus (Ozawa et al., 2007) whereas others, who had been around ill people but had not exhibited symptoms themselves, may be asymptomatic shedders who run the same risk as symptomatic individuals of contaminating the workplace (Kuo et al., 2009; Lin et al., 2015).
A study by Verhoef et al. (2013) found that few food handlers in catering companies (20%, k = 600, n = 1023) had heard of NoV, compared with food handlers based in hospital (92%, k = 141, n = 154) and nonhospital (71%, k = 88, n = 101) institutions such as nursing homes and retirement homes. Knowledge may impact on a worker's likelihood of staying away from work in the event that they experience an active infection. Fewer facilities necessary for kitchen staff to maintain high standards of hygiene, for example, hand washing instructions for new staff and separate sinks for hand washing were found in catering companies than in hospital restaurants and nonhospital institutional catering (Verhoef et al., 2013). The differences in kitchen standards, training, and knowledge may help to explain why fewer food-handler outbreaks were attributed to hospitals than to restaurants and caterers.
Hedberg et al. (2006) found that in restaurants with managers who had undertaken training on food safety, outbreaks were less likely than in those without trained managers and staff. However, practices that reduced contamination such as using gloves and designated utensils on different products did not always occur, even if workers were aware that they should be doing this (Robertson et al., 2013). Hedberg et al. (2006) additionally found that outbreaks were less likely in restaurants where sick pay was provided and a staff reporting policy in the event of illness was in place. This is in accordance with a study by Carpenter et al. (2013), which found that people continued to work through diarrhea and vomiting for fear of losing their jobs and shifts if they were absent. It is difficult to make recommendations to stay at home in a culture in which many workers will not have regulated hours, and will not necessarily receive sick pay if they are absent from work.
Limitations
There are various limitations in the results of our review. For example, varying time lags between falling ill and fecal sampling in different studies were observed and this will have affected the likelihood of finding virus. This is noted in two studies as a possible explanation for heterogeneity in shedding periods (Murata et al., 2007; Atmar et al., 2008). The length of time from acquisition of the virus to genotyping may determine the strains found and will not necessarily capture chance-point mutations or gene transfer from other cocirculating strains. This might have resulted in identifying fewer food-handler outbreaks. Furthermore, food handlers will not necessarily admit to being ill (Carpenter et al., 2013; Verhoef et al., 2013), as they may lose work and may not want to leave the workplace understaffed. This will also lead to an underestimate of the frequency of food-handler outbreaks.
Further limitations include the fact that detection of NoV in food and environmental samples is not necessarily widely employed outside specialist laboratories at present (Stals et al., 2013b). There are standardized valid laboratory protocols for examination of hepatitis A virus and NoV in foods, but these are currently qualitative in nature (although ISO/TS 15216-2:2013 is being reviewed and will be replaced by a quantitative standard (ISO/DIS 15216-2)) (Stals et al., 2013b; Anonymous, 2017) and there are challenges in assessing whether or not the NoV detected in human or food samples has infectious potential (Knight et al., 2013).
The completeness of studies included in a systematic review was achieved through the use of a comprehensive search strategy from a wide range of sources. However, the timescale of the review was restricted to ensure comparability of laboratory methods, which will have resulted in the omission of studies before 2003.
Peer-reviewed publication usually requires reporting of novel findings (new virus type, new food vehicle, etc.) and so outbreaks that provide high-quality evidence of long-established causes and exposure routes may not reach the peer-reviewed literature. This means that the burden of illness associated with particular food sources and risky environments may be underrepresented in our systematic review.
The strict case definition resulted in comparatively few articles for which the quality of evidence confirming a food source or food-handler involvement was judged to be high. Relatively few studies had tested both cases and foods, or cases and handlers.
Finally, studies from wealthier countries comprised the majority of those appearing in the review, reflecting the greater technological development, public health infrastructure, and monetary resource required for the investigation of outbreaks and identification of causative microbiological agents. Furthermore, a short duration of illness with NoV may limit the number of outbreaks that are formally reported and investigated, for example, small foodborne outbreaks may be expected and, therefore, not reported in countries in which a lot of seafood, including oysters, is eaten, for example, Japan (Pers. Comm. Dr Yamanaka).
Conclusions
Food and food handlers both contribute to outbreaks of NoV. Some outbreaks were attributed to asymptomatic food handlers. Contaminated shellfish were implicated in the greatest number of definite foodborne outbreaks. Food handlers contributed to definite food-handler outbreaks involving a diverse range of foodstuffs and in a wide variety of settings, including weddings and military establishments. More genotypes of NoV were found in ill people than in samples from food and food handlers. The potential for both food products and food handlers to contribute to the burden of NoV infection was demonstrated conclusively.
Supplementary Material
Acknowledgments
This work was funded by the United Kingdom Food Standards Agency under project FS101040: “Assessing the contribution made by the food chain to the burden of UK-acquired norovirus infection (NoVAS).” The authors thank Dr. Tsuyuko Yamanaka for translating Japanese articles into English. The authors also thank the NoVAS Consortium for helpful comments. The NoVAS Consortium, in addition to the authors, comprises the University of Liverpool (Miren Iturriza-Gomara), the University of East Anglia (Paul Hunter and Jim Maas), Public Health England (David James Allen, Nicola Elviss, and Andrew Fox), Leatherhead Food Research (Angus Knight) and Fera Science Ltd. (Nigel Cook and Martin D'Agostino). S.J.O'B. and J.P.H. are affiliated to the National Institute for Health Research Health Protection Research Unit in Gastrointestinal Infections at University of Liverpool in partnership with Public Health England, in collaboration with University of East Anglia, University of Oxford, and the Quadram Institute. S.J.O'B. and J.P.H. are based at the University of Liverpool. The views expressed are those of the author(s) and not necessarily those of the NHS, the NIHR, the Department of Health, or Public Health England.
Disclosure Statement
No competing financial interests exist.
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