INTRODUCTION
Salmonella is a major bacterial pathogen that continues to pose a health and economic burden in Canada [Reference Thomas1]. The reservoirs of Salmonella include humans and a wide range of wild and domestic animals. Transmission occurs through ingestion of food derived from infected animals, food contaminated with animal or human faeces, or contact with infected animals, people, or their environment [Reference Heymann2].
Analysis of human laboratory isolates of Salmonella for surveillance purposes can facilitate the early detection of outbreaks; when combined with epidemiological data (e.g. age, sex, risk factor, and exposure information), such analyses can also identify emerging sources of infection to aid in the development and implementation of control measures. Many surveillance efforts focus solely on human Salmonella isolates [3–5]. However, there are initiatives using isolate data from non-human (e.g. animal, food) sources for surveillance, such as the World Health Organization's Global Foodborne Infections Network (GFN) [6], FoodNet Canada [7], the Canadian Integrated Program for Antimicrobial Resistance Surveillance (CIPARS) [8], and the Danish Programme for surveillance of antimicrobial consumption and resistance in bacteria from animals, food and humans (DANMAP) [9]. These preceding initiatives have largely focused on identifying trends, vs. outbreaks, in the non-human data to target and evaluate measures for reducing Salmonella incidence and/or antimicrobial resistance.
In British Columbia (BC), the Integrated Salmonella (IS) Surveillance programme compiles laboratory Salmonella data from three sectors – humans, animals and food. Data are analysed regularly by the IS epidemiology working group (IS WG), a subset of the larger British Columbia Integrated Surveillance of Foodborne Pathogens Working Group (see Appendix). The IS WG members consist of public health and animal health practitioners from provincial and federal levels. IS WG analyses consist of regular qualitative reviews of descriptive data from each sector and across sectors (e.g. monthly counts by animal species, commodity, serotype, subtype), as well as looking for matching strains, trends over time, and clusters (increased number of isolates higher than expected based on historical data) [Reference Galanis10].
Methods to analyse laboratory surveillance data to detect statistically significant clusters for further investigation include time-series analysis, regression-based methods, scan statistics, and cumulative sum statistics [Reference Sonesson and Bock11, Reference Hohle, Paul and Held12]. The use of statistical methods to identify clusters of Salmonella in people has become part of routine public health surveillance and the use of these methods has been suggested in animal surveillance [Reference Hohle, Paul and Held12]. Recent studies have successfully used statistical surveillance algorithms to detect clusters of Salmonella in animals [Reference Danan13, Reference Kosmider14]. However, these approaches have not been used to identify clusters spanning different sectors (animals, food, and humans) as part of an integrated surveillance system for public health.
The purpose of our study was to (1) assess whether human and non-human Salmonella data may be analysed using statistical surveillance algorithms to identify clusters across three sectors (animal, food, human), (2) assess the impact of adding travel history information to human isolate data, and (3) validate whether the algorithms identified the same clusters as those identified by the IS WG using a qualitative review.
METHODS
Data sources
This study used Salmonella serovars isolated from samples collected in BC between January 2008 and December 2010 from three sectors: human, animal, and food (meat). The data extracted from the BC IS database came from the following sources: (1) human laboratory diagnostic data from the BC Centre for Disease Control Public Health and Microbiology Reference Laboratory (BCCDC PHMRL) and the Public Health Agency of Canada National Microbiology Laboratory, (2) animal laboratory diagnostic data from the BC Ministry of Agriculture Animal Health Centre, and (3) retail meat (food) data from CIPARS, an integrated surveillance programme coordinated by the Public Health Agency of Canada that aims to monitor trends in antimicrobial use and resistance [8]. Details on these source data and their limitations have been published previously [Reference Galanis10].
Human data
All diagnostic Salmonella isolates sent to the BCCDC PHMRL were included in this study. Subtyping by pulse-field gel electrophoresis (PFGE) was done for all human isolates and phage typing was done on isolates received in the first 15 days of each month for certain serotypes [Reference Galanis10]. Travel history is not included in this laboratory-based dataset, and therefore is generally not available for prospective surveillance analyses (such as those in this study). However, since this study was conducted retrospectively, we were able to investigate the potential effect of including travel data history on a subset of Salmonella Enteritidis isolates. S. Enteritidis isolates were linked to information in the integrated Public Health Information System (iPHIS) to obtain travel exposure information (i.e. travel history, no travel history, and unknown travel history). S. Enteritidis cases with no travel history were classified as ‘domestic’ cases.
Animal data
Submissions from chicken, cattle, swine, and turkeys with a laboratory isolation of Salmonella were obtained from the provincial animal health diagnostic laboratory. Phage-type (PT) subtyping was done for certain serotypes [Reference Galanis10]. Isolates were stratified by type of submission: diagnostic (disease cases and investigations), monitoring (routine animal health programmes, chicken only), and special project investigations. Data for this study is primarily from diagnostic submissions. Although diagnostic isolates are often from animal necropsies, and ill animals are unlikely to enter the food chain, we assume that the farm and all animals on the farm are potentially contaminated/infected with Salmonella where there is a positive Salmonella test. In addition, since diagnostic samples can also include swabs, faeces, or other samples from the animal and/or farm, no animal may have been removed from the food chain.
Samples submitted for unknown reasons (i.e. not identified as diagnostic, monitoring, or project) were included in analyses. Data generated through targeted research projects were excluded from further analysis due to highly intermittent sampling. Monitoring data (available only for chicken) consisted of batched fluff samples from hatcheries; while sparse and intermittent, the data were included in analyses as a supplement to the constant diagnostic data.
For chicken, two time series were created for each serotype: ‘all chicken’ and ‘diagnostic chicken’, where ‘all chicken’ included diagnostic, monitoring, and samples submitted for unknown reasons. Since subclinical infection with Salmonella is common in many animals [Reference Humphrey, Threlfall, Cruikshank, Palmer, Soulsby and Simpson15], we assumed that inclusion of asymptomatic animal isolates could correlate better with human risk. Therefore, for chicken, ‘all chicken’ time series were chosen over ‘diagnostic chicken’ time series for examination of cross-sectoral signals.
Food data
Data about Salmonella identified in retail chicken and pork meat samples purchased at the point of sale in BC were extracted from the CIPARS system. Subtyping (PT) was done for certain serotypes [Reference Galanis10]. Retail sampling occurred approximately every 2 weeks, with eight samples of pork and eight samples of chicken collected in each sampling week [16]. Retail meat samples included both domestic and imported products. Data were stratified by meat type (chicken and pork).
Events identified by the IS WG
Information about events identified by the IS WG in 2010 was abstracted from IS WG meeting minutes and through supplemental interviews with the IS WG members. The IS WG met six times to review 2010 data: five times in 2010 [March (week 10), June (week 23), July (week 30), September (week 37), November (week 45)], and once in 2011 [March (week 11)]. The meeting minutes recorded information from the group's review of data from each sector that were then summarized in tables as monthly counts of all serotypes for each sector (and species) for the previous 3 months and previous years, matching serotypes (and PFGE/PT subtypes when available) spanning the sectors. Additionally, monthly graphs for the more common serotypes illustrating patterns (e.g. seasonality), increases above that expected, and trends across sectors were reviewed. No statistical tests were used by the IS WG to identify patterns, trends or clusters. Cross-sectoral events were defined as those where the group noted a pattern of interest (e.g. an increase) in a particular serotype in at least two of the three sectors.
Statistical signals across time series
Three algorithms were used in to identify a particular week of interest; this was done in order to increase the specificity of the signals in any particular week (i.e. all three algorithms had to agree a signal is present), while allowing for increased sensitivity in detecting smaller but more sustained increases (i.e. a signal identified in only one algorithm but in two consecutive weeks). The surveillance algorithms used to detect statistically significant signals in individual time series were: (1) the Farrington algorithm [Reference Farrington17] (also used by Kosmider et al. [Reference Kosmider18] for detection of Salmonella clusters in animal data), (2) a Bayesian algorithm, and (3) the Robert Koch Institute (RKI) algorithm (all algorithms in Hohle [Reference Hohle19]). These algorithms were chosen as they have been used previously to identify unusual agri-food chain contamination and the emergence of a serotype that correlated with an emergence of the same serotype in humans [Reference Kosmider14]. Weekly time series were created for each serotype for: humans, each animal species, and each meat type separately. An additional time series of ‘domestic human’ cases was created for S. Enteritidis. All time series with at least one submission in the ‘test year’ (2010) and two submissions in the 3-year time interval were included in the analyses. Since Salmonella infections are often found to be seasonal in both humans and animals, these algorithms obtain expected values in the form of ‘moving windows’ of pre-specified subsets of past counts (3-week windows were used in analyses) that form the baseline, thereby directly accounting for seasonality. The past counts in the years 2008 and 2009 were used to create the baseline, with statistical signals evaluated for weeks in 2010. Expected values consisted of counts from 6 weeks (three from each of the previous 2 years): the same week, the week before and week after were used.
All three algorithms assume that the past counts follow a Poisson distribution, a distribution used for modelling counts of (rare) events in a specific period of time. The Farrington method calculates an expected value by fitting a Poisson regression model to the past counts, creating 95% confidence intervals using a transformed Normal distribution. The Bayesian algorithm employs an empirical Bayes approach to Poisson-distributed reference values by defining a non-informative Gamma prior distribution on the Poisson rate parameter (i.e. observed counts), which leads to a negative binomial distribution for the posterior distribution (i.e. expected counts). The RKI algorithm sets the expected value to the mean of the reference distribution, calculates a 95% Poisson confidence interval around the mean, and compares whether the current value is within the interval. All analyses were performed in R [20], using the ‘surveillance’ package [Reference Hohle, Paul and Held12, Reference Hohle19].
The following assumptions were required for the analyses: Salmonella isolates are independent (i.e. one isolate does not affect the probability of another isolate), samples are submitted at a constant rate (hence denominators do not need to be included), and isolation counts follow Poisson distributions. The data from each of the three sectors used in this study (human, animal, food) may violate these assumptions for different reasons (see Table 1 for details).
iPHIS, Integrated public health information system.
Once algorithm analyses were conducted in each sector for each serotype, the weeks with important public health signals were those meeting the following criteria:
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(1) Weeks with statistically significant results (α = 0·01) for unique serotypes identified by all three algorithms (for higher specificity).
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(2) Weeks with statistically significant results (α = 0·01) for unique serotypes (using ⩾1 algorithm) persisting for ⩾2 consecutive weeks in humans or animals and either consecutive or alternating weeks for meat samples (due to bi-weekly sampling).
Serotypes with a public health signal in more than one sector (animal, food, human) for a week in 2010 were considered to be cross-sectoral signals, regardless of the time difference between significant weeks. For each serotype with a cross-sectoral signal, available subtyping (PT or PFGE patterns) as well as travel information for the human cases was extracted from the IS database and iPHIS, respectively.
RESULTS
Salmonella isolates and signals in individual time series
Over the 3-year study period there were a total of 3335 human isolates, with 150 serotypes observed overall. There were 1477 S. Enteritidis isolates, 68% (1007/1477) were linked to travel history data, and of these 69% (693/1007) were domestically exposed.
In 2010, the ‘test year’, 68% (67/99) of human serotype time series had at least one isolate and were therefore tested for signals. For the 67 time series, 66 had a signal using the Farrington algorithm, 63 using the Bayes, and seven using the RKI algorithm. There were 750 animal isolates representing 68 serotypes; 79% (595/750) of isolates were from chicken. In the ‘test year’ 2010, there were 31 time series created for serotypes with at least one positive isolate to test for signals: 15 ‘all chicken’, nine ‘diagnostic chicken’, three cattle, two swine, and two turkey. For each of the 31 time series, there was at least one corresponding signal in both the Bayes and Farrington algorithms; there were signals in four time series using the RKI algorithm.
There were 169 meat isolates representing 20 serotypes; 96% (162/169) from chicken and 4% (7/169) from pork. Six serotypes has positives isolates in the ‘test year’ 2010, and all six had at least one signal using the Farrington algorithm, five had signals using the Bayes algorithm, and none had signals using the RKI algorithm.
Eighteen Salmonella serotypes were present in at least two sectors; six serotypes were present in all three sectors: S. Enteritidis, S. Hadar, S. Heidelberg, S. Kentucky, S. Schwarzengrund, and S. Typhimurium.
Comparison of events identified by the IS WG with statistically significant algorithm signals across sectors
The IS WG identified four serotypes for investigation, S. Enteritidis, S. Heidelberg, S. Typhimurium, and S. I 4,[5],12:i:-, while the algorithms identified three cross-sectoral alerts among S. Enteritidis, S. Hadar, and S. Kentucky (Table 2).
H, Human; A, animal; F, food.
Identified by both methods: S. Enteritidis investigation by subtype and travel history
The IS WG and the statistical algorithms both identified S. Enteritidis; there were statistically significant signals in chicken (animal), chicken meat, humans (all), and ‘domestic humans’ (Fig. 1a , b ).
However, the algorithms and IS WG identified events with different subtypes: both methods identified PT8 and PT13a, the statistical algorithms identified PT13, and the IS WG identified PT51 and PT15a (Table 3). PT51 was identified by the IS WG because of a gradual increase of the subtype, particularly in animals. There were not enough isolates of PT15a to generate a statistically significant signal in animals.
PT, Phage type.
* Week data review occurred in 2010 (for data reviews 1–5), and 2011 (for data review 6).
† Cross-sectoral cluster: PT identified in at least two of three sectors (human, animal and food).
Figure 1( a , b ) shows the chicken (animal) time series and chicken meat time series for 2010, as well as weeks with statistically significant signals and the PT composition of isolates within the signals (for the top PTs of interest). Figure 1a shows weekly counts and signals for all human cases (domestic, travel, and unknown), while Figure 1b shows weekly counts and signals for domestic human cases only. Overlap of PTs (PT8, PT13a, PT13) within signals is present in the first third of the year (up to week 14), but not in the second two thirds of the year, where animal signals consisted of PT51 and PT13, while human signals consisted largely of PT8 and PT13a.
The analysis of all human isolates yielded one additional signal in week 49 (subsequent to signals in week 47 and 48) that was not identified in the domestic isolates (Fig. 1 a). Conversely, analysis of domestic human isolates alone yielded two additional signals in the first third of the year (weeks 10 and 14) that the analysis with all cases combined did not identify (Fig. 1 b).
The time difference from an initial animal signal and any subsequent human signal (with the same PT) ranged from 5 to 48 weeks (2–47 weeks for domestic cases); for food the time to the human signals with the same PT ranged from 3 to 46 weeks (3–45 weeks for domestic cases).
Identified by algorithms only: S. Hadar and S. Kentucky
The algorithms identified signals in S. Hadar in chicken meat and 36 weeks (over 8 months) later in humans. Of the five human isolates in the cluster, three had no travel information and two were travel related. The signals in S. Kentucky were in: ‘all chicken’ (weeks 35 and 43), chicken meat (weeks 12, 41, and 50), and humans (week 38). Of the five human isolates in the cluster in week 38, three had no travel information and two were travel related.
Identified by IS WG only: S. Heidelberg, S. Typhimurium and S. I 4,[5],12:i:-
An investigation into S. Heidelberg started at the beginning of 2010 based on observing similar PT/PFGE patterns in all three sectors (humans, chicken, and chicken meat), in late 2009 and early 2010. The IS WG observed another increase in S. Heidelberg in autumn 2010; however, they did not find common subtypes to warrant further investigation. S. Typhimurium was identified by the IS WG based on seasonality in animals and an increase in humans. While the increase in humans was also identified using the algorithms, there were no signals in the animal or meat sectors, hence no cross-sectoral signal was generated. The S. I 4,[5],12:i:- serotype was identified by the IS WG due to differences in seasonality patterns in humans and animals. While a significant signal in S. I 4,[5],12:i:- was identified in humans, no cross-sectoral signal for this serotype was generated because seasonal trends in animals were not identified as an alert by the algorithms (as seasonality is accounted for by the window-based sampling method of the algorithms).
DISCUSSION
Analysis of integrated Salmonella surveillance data from agricultural animals, meat, and humans using surveillance algorithms did not identify the same cross-sectoral clusters as the IS WG. This lack for agreement may be due to the IS WG using more diverse criteria to identify events of interest, animal data violating statistical assumptions required by the algorithms, and/or the lack of a defined time interval between statistically significant weeks across sectors.
The IS WG used descriptive analyses, such as graphs illustrating longer-term trends and seasonality, while the algorithms were designed to detect weeks with increases above expected based on baseline data. Tighter alignment of the objectives of surveillance and algorithm method selection may ensure a more prominent role for automated techniques [Reference Robertson21] in supplementing working group investigations. For example, in order to detect changes in trends and seasonality, integrated surveillance studies could try to identify potential clusters using correlation between smoothed counts and statistically significant linear and nonlinear trends, such as those done previously in animals and humans separately that identified common patterns [Reference Guerin, Martin and Darlington22, Reference Guerin23], or use time series methods to detect gradual increases or correlations in seasonality [Reference Allard24]. Examination of longer-term changes in Salmonella PT distribution has been instrumental in generating hypotheses to explain increases in human cases and in identifying an emergence, such as that of PT 51 in animals, food, and humans [Reference Galanis10]. Notably, however, the surveillance algorithms as defined and used in this study presented a new way to examine the same data, and provided targeted investigation opportunities for the IS WG, such as the identification of clusters of isolates to be examined in more detail using subtyping and/or epidemiological information.
Animal data likely violated the assumptions required for the algorithms (Table 1). Animal surveillance data (especially diagnostic data) are influenced by changing economic circumstances within the livestock industry, such as large outbreaks [Reference Kosmider18], with outbreaks potentially affecting independence as well as denominators (see Table 1). Further, while animal samples submitted for routine surveillance and monitoring to comply with various legislative or industry requirements (e.g. table egg production) could be a useful data source, the data are currently too sparse and intermittent (e.g. submitted to the laboratory in batches) for use in statistical algorithms. Future analyses could aggregate isolates into ‘epidemiological units’ and ‘incidents’ to address violations of the independence assumption in animal data streams whereby an ‘incident’ comprises the first isolation and all subsequent isolations of the same serotype (and PT) from the ‘epidemiological unit’ of animals (an individual animal or groups of animals in the same herd/flock) within a standard time period, such as 30 days [Reference Kosmider14]. Unfortunately, we did not have the necessary data (i.e. submitter information) to aggregate isolates into such units. Denominator data, such as the number of samples submitted for Salmonella testing [Reference Guerin23], would help interpret animal surveillance data, allow for the assessment of sample submission rate, and justify constant rate assumptions.
The surveillance algorithm methodology enabled identification of high weekly counts as well as smaller sustained increases (i.e. over a few weeks); this was especially important for identification of signals in low-count data streams. With more years of data, larger time aggregation units (and associated higher counts in the time units) may lead to better performance of surveillance algorithms with more robust calculations of expected counts and confidence intervals. Kosmider et al. [Reference Kosmider14] successfully applied the Farrington algorithm to monthly Salmonella time series in animals over 10 years, and statistically significant temporal clusters of monthly counts have been found in Salmonella in both humans [Reference Guerin, Martin and Darlington22] and animals [Reference Guerin23] using time scan statistics. Danan et al. combined all of the data from different species together, and were able to find statistically significant signals linked to contamination in the agri-food chain that were confirmed upon investigation [Reference Danan13].
The fact that we were limited to identifying statistically-significant weeks in Salmonella serotypes in more than one sector (animal, food, human), irrespective of the time difference between significant weeks (i.e. occurring within the same year) could be seen as a weakness of this study. However, as there was no defined time interval to determine the risk period to humans (or meat) following a signal in animals, we could at least investigate the possible correlations between these signals qualitatively.
At first sight, Figure 1 appears promising with signals in animals (and food in one instance) preceding human infections of S. Enteriditis. However, since we only had PT subtyping data to assess possible links between signals, the time lags between animal/food signals and human signals with the same PT ranged from 2 to 48 weeks. While the 48-week time lag may seem unreasonably long, a Canadian study found a 10-month temporal cluster in S. Typhimurium var. Copenhagen that ended in chickens 9 months prior to the start of a human temporal cluster, suggesting their results point to a possible association between human illness and exposure to chicken products [Reference Guerin, Martin and Darlington22].
A reasonable time interval between the two signals (animal and human, or animal and food, or food and human) is necessary to quantitatively test for correlation among the animal and human time series (i.e. positive predictive value of animal/food signals for human signals). Although the incubation period for salmonellosis is estimated to range between 12 and 36 h [Reference Heymann2], due to the complexity of Salmonella dynamics in the food chain, a reasonable time estimate requires either the results of previous outbreak investigations where human cases were linked to known food/animal contamination events; or, the collection of species-specific information that is currently lacking, such as the animal production type (e.g. egg vs. meat for chicken, milk vs. beef for cattle), and the age of the animal (e.g. to estimate time to slaughter). Salmonella contamination can also occur during transport, slaughter, or processing, whereby Salmonella is spread between infected and previously Salmonella-free animals resulting in Salmonella-contaminated meat cuts [Reference Heyndrickx25]. Additionally, salmonellosis has been associated with consumption of processed and frozen chicken products [Reference Currie26], adding to the potential shelf-life of such product. Finally, foods eaten in a jurisdiction are not necessarily produced in the same jurisdiction.
Our results suggest that a timely link between laboratory and epidemiological data would be beneficial for outbreak detection. There were differences in the signals generated by the time series for all S. Enteritidis human cases compared to the domestic human cases only. Both time series generated signals at the beginning and end of the test year. However, the domestic time series provided an extra two signals in the beginning of the year that the overall human time series did not. This suggests that inclusion of travel exposure information, especially if it is available for a substantial proportion of cases (68% of S. Enteritidis in this study), could result in generation of more meaningful alerts. The investigation of the two other cross-sectoral clusters identified by the algorithms (S. Hadar and S. Kentucky) support this, as both contained cases with travel history.
Further investigation into appropriate analytical methods for integrated surveillance programmes is needed. A review found that studies attempting an analytic linkage between animal and human health data (i.e. where animal data was used to quantitatively predict human risk), were limited largely to diseases that had a clear spatio-temporal component such as West Nile virus [Reference Scotch, Odofin and Rabinowitz27]. A pathogen such as Salmonella that is transmitted through a complex food production and distribution chain (as well as through other means, including direct contact and water) may only show a spatiotemporal association between human cases and the final products in the marketplace (e.g. meat on grocery store shelves), not throughout its entire production path. In general, a signal in meat should have a higher specificity than a signal in animals in terms of predicting risk of disease in humans, since meat is much closer to humans in the food chain than animals. Although limited, our results appear to support this: the only cross-sectoral signals with matching subtypes in S. Enteritidis were during the time interval that included a signal in meat (Fig. 1). An association with meat in our analyses is further supported by the knowledge that fresh chicken meat consumed in BC is largely produced locally within the province [Reference Galanis10]. It is important to stress that appropriate farm and/or abattoir monitoring programmes could also detect relevant contamination events and would enable a timelier response (e.g. prior to meat distribution). The difficulty in identifying clear actionable alerts is likely due to the complexity of Salmonella dynamics within the food chain, specifically quantifying the risk to human health from a live animal with Salmonella and the lack of specificity and quantity of data in certain sectors. Without additional contextual information, especially relevant epidemiological data, animal and food surveillance data of this type may be more amenable to generating hypotheses in epidemiological investigations and in helping evaluate programmes by examining longer-term trends. For example, an international investigation of a human outbreak of S. Typhimurium used national animal and meat Salmonella surveillance databases to supplement human surveillance data and identify pork meat as the source of infection [Reference Bruun28]. Moreover, animal surveillance data has been successfully linked with human data in source attribution studies, where various modeling approaches are used to make inferences about the relative importance of different food/animal sources for disease in the population [Reference Pires29].
While salmonellosis is generally considered to be a foodborne zoonosis acquired through the consumption of foods of animal origin, it can also be acquired thought the consumption of fruits and vegetables, as well as direct transmission from infected persons and animals [Reference Harker30]. Further, in previous investigations, Salmonella serotype distribution (number of specific serotypes and their frequencies) was different between animals at slaughter (chicken, cattle, and swine) and humans [Reference Sarwari31], and the distribution of S. Typhimurium DT104 (based on varying antimicrobial resistance patterns) was also found to be different between human and animal populations (primarily cattle) [Reference Mather32]. Such findings call into question links between agricultural animal and human isolates, especially causal links, even for the same subtype. As whole genome sequencing becomes more widely available and affordable, novel genotyping methods based on sequence-based identification will result in better resolution of subtypes [Reference Fournier, Drancourt and Raoult33]. This may allow for future cluster/outbreak investigations to better specify the sources of initial infection isolates in human and animal populations, despite issues with categorizing this vast amount of new information into epidemiologically meaningful categories.
Our results indicate if surveillance algorithms were used prospectively they could complement IS WG manual reviews by identifying different cross-sectoral clusters. Ongoing cluster and outbreak investigations, as well as better epidemiological information associated with surveillance data, are needed to evaluate a relevant lag time between related statistically significant animal, meat, and human signals, as well as the predictive value of cross-sectoral clusters identified using surveillance algorithms for integrated surveillance systems using animal, human and food data.
APPENDIX
British Columbia Integrated Surveillance of Foodborne Pathogens Working Group (in alphabetical order, affiliations at time of analysis)
Sean Byrne1, Nancy De With1, Joe Fung2, Eleni Galanis3,4, Linda Hoang2,3, Mira Leslie1, Min Li4, Sophie Li4, Laura MacDougall4, Lorraine McIntyre4, Muhammad Morshed2,3, Ana Paccagnella2, E. Jane Parmley5, Jane Pritchard1, Brian Radke4, Craig Stephen6,7 Jason Stone8, Marsha Taylor4, Julie Wong2, Erin Zabek1
1 British Columbia Ministry of Agriculture, Abbotsford, BC, Canada
2 British Columbia Centre for Disease Control Public Health Microbiology & Reference Laboratory, Vancouver, BC, Canada
3 University of British Columbia, Vancouver, BC, Canada
4 British Columbia Centre for Disease Control, Vancouver, BC, Canada
5 Public Health Agency of Canada, Guelph, ON, Canada
6 Centre for Coastal Health, Nanaimo, BC, Canada
7 University of Calgary, NW, Calgary, AB, Canada
8 Fraser Health Authority, Surrey, BC, Canada
ACKNOWLEDGEMENTS
The authors acknowledge David Graham of the Canadian Food Inspection Agency, Merv Wetzstein and Jaime Osei-Appiah of British Columbia (BC) Ministry of Agriculture, Loretta Janz of BC Centre for Disease Control (BCCDC) Public Health and Reference Microbiology Laboratory (PHMRL), BCCDC Environmental Microbiology PHMRL staff, BC Ministry of Agriculture Animal Health Centre staff, Public Health Agency of Canada (PHAC) Laboratory for Foodborne Zoonoses staff, PHAC National Microbiology Laboratory staff, and the Canadian Integrated Program for Antimicrobial Resistance Surveillance (CIPARS) BC field staff. This research received no specific grant from any funding agency, commercial, or not-for-profit sectors.
DECLARATION OF INTEREST
None.