Salmonellosis Outbreak Detected by Automated Spatiotemporal Analysis — New York City, May–June 2019
Weekly / July 3, 2020 / 69(26);815–819
Julia Latash, MPH1*; Sharon K. Greene, PhD1*; Faina Stavinsky, MS2; Sandy Li3; Jennifer A. McConnell, MS3; John Novak, PhD3; Teresa Rozza3; Jing Wu, PhD3; Enoma Omoregie, PhD3; Lan Li, MPH1; Eric R. Peterson, MPH1; Bruce Gutelius, MD1; Vasudha Reddy, MPH1 (View author affiliations)
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What is already known about this topic?
Whole genome sequencing (WGS) improves detection of foodborne outbreaks caused by contaminated products. However, detecting geographically focal outbreaks can be delayed pending WGS results, and public health laboratory capacity limitations might preclude sequencing of all Salmonella isolates.
What is added by this report?
Through daily automated spatiotemporal analysis of notifiable diseases, a salmonellosis outbreak in New York City was detected 9 days before availability of serotyping results. Early detection primed investigators to look for common exposures and facilitated rapid environmental assessments, leftover food collection, and prioritization of isolates for subtyping.
What are the implications for public health practice?
Along with laboratory subtyping results, public health officials can use spatiotemporal cluster detection analyses to prioritize investigations.
In May 2019, the New York City Department of Health and Mental Hygiene (NYCDOHMH) detected an unusual cluster of five salmonellosis patients via automated spatiotemporal analysis of notifiable diseases using free SaTScan software (1). Within 1 day of cluster detection, graduate student interviewers determined that three of the patients had eaten prepared food from the same grocery store (establishment A) located inside the cluster area. NYCDOHMH initiated an investigation to identify additional cases, establish the cause, and provide control recommendations. Overall, 15 New York City (NYC) residents with laboratory-diagnosed salmonellosis who reported eating food from establishment A were identified. The most commonly consumed food item was chicken, reported by 10 patients. All 11 clinical isolates available were serotyped as Salmonella Blockley, sequenced, and analyzed by core genome multilocus sequence typing; isolates had a median difference of zero alleles. Environmental assessments revealed food not held at the proper temperature, food not cooled properly, and potential cross-contamination during chicken preparation. Elevated fecal coliform counts were found in two of four ready-to-eat food samples collected from establishment A, and Bacillus cereus was detected in three. The outbreak strain of Salmonella was isolated from one patient’s leftover chicken. Establishing automated spatiotemporal cluster detection analyses for salmonellosis and other reportable diseases could aid in the detection of geographically focused, community-acquired outbreaks even before laboratory subtyping results become available.
Investigation and Results
On May 21, 2019, NYCDOHMH detected a spatiotemporal cluster of five salmonellosis patients reported through passive surveillance by electronic laboratory reporting (2). These patients resided within a 0.3-mile (0.48-km) radius and had “event dates” (illness onset dates if available, otherwise specimen collection dates) during May 11–17. The cluster’s recurrence interval (3) was 2.3 years, indicating that one would expect to see one cluster of that magnitude in any 2.3-year period. This cluster was detected because each weekday, using SaTScan, NYCDOHMH applies the prospective space-time permutation scan statistic (4,5) to scan for recent increases (parameter settings included maximum temporal cluster size of 60 days and maximum spatial size of 50% of observed events during a 1.5 year-study period) in the occurrence of salmonellosis cases based on patients’ event dates and geocoded home addresses.†
At NYCDOHMH, CDC FoodCORE–funded graduate student interns attempt to interview all reported salmonellosis patients as soon as feasible after initial report to collect possible exposure information with minimal recall bias (6); median time from report of salmonellosis to completion of interview is generally 2 days. At the time of cluster detection on May 21, interviews had not yet been completed with any cluster patients. The cluster notification prompted interviewers to be vigilant for any common food, grocery store, or restaurant exposures. Once interviews of patients in the initial cluster were completed, student interns immediately compared interviews to look for any common exposures. On May 22, interviewers determined that three of the five patients had eaten prepared food from establishment A.
On May 23, the New York State Department of Agriculture and Markets inspected establishment A to assess food handling practices. On the same day, the NYCDOHMH Office of Environmental Investigations distributed stool collection kits for Salmonella testing to 18 food handlers involved in food preparation at establishment A; the first food handler specimen was collected on May 25.
An outbreak-associated case was defined as a laboratory diagnosis of Salmonella infection in a NYC resident who reported eating food from establishment A in the 7 days preceding illness onset. Among 17 salmonellosis patients included in the SaTScan cluster during May 21–June 19, interviews were completed with 16 patients, 14 of whom had illnesses meeting the outbreak case definition (Figure). In addition, one food handler not included in the SaTScan cluster also had an illness that met the outbreak case definition but did not cause the outbreak, based on 10 outbreak patients having had symptom onset prior to the food handler. The 15 patients with outbreak-associated cases (14 patrons of establishment A and one food handler) reported eating food from establishment A during May 8–20 and had illness onset during May 14–21. None of the patients resided in the same household. Nine patients were female, and the median age was 42 years (range = 26–61 years). The most common food item consumed, reported by 10 patients, was chicken (rotisserie chicken, chicken salad, or chicken soup).
Outbreak-associated patient isolates were subtyped at the NYCDOHMH Public Health Laboratory and the New York State Department of Health Wadsworth Center. Eleven of the 15 patients had isolates available for subtyping. All were serotyped as S. Blockley, with a median difference by whole genome sequencing (WGS) of zero alleles (range = 0–1 alleles). Pulsed-field gel electrophoresis (PFGE) was performed on nine clinical isolates; all were indistinguishable from each other.
One patient had leftover rotisserie chicken from establishment A, which had not been handled after illness onset and was held under refrigeration until collected by NYCDOHMH on June 1 for testing. S. Blockley with an indistinguishable PFGE pattern and 0–1 alleles difference by WGS from the clinical isolates was isolated from the leftover chicken.
On June 5, a second environmental assessment of establishment A was conducted by the New York State Department of Agriculture and Markets jointly with the NYCDOHMH Office of Environmental Investigations. The establishment was immediately notified of violations revealed by this assessment, including ambient temperature of a walk-in refrigerator of 51°F (10.6°C) instead of ≤40°F (4.4°C); opportunities for potential cross-contamination, such as preparing raw chicken in the walk-in cooler and using gloved hands to open walk-in doors during food preparation; using an inadequately calibrated food thermometer; improper hot- and cold-holding of cooked foods; and inadequate cooling of cooked foods. Eight environmental sponge swabs and four ready-to-eat food samples were also collected for testing at NYCDOHMH Public Health Laboratory. The eight environmental swabs tested negative for Salmonella, but two ready-to-eat food samples had elevated fecal coliform counts (>1,100 most probable number/gram), and three food samples tested positive for Bacillus cereus (range per sample = 70–670 colony-forming units [CFU]/gram), although below the threshold required to cause illness (105–106 CFU/gram) (7); these findings were consistent with identified deficiencies in holding temperatures that could allow bacterial proliferation.
To evaluate whether spatiotemporal cluster detection analyses might have contributed to reducing typical delays in taking public health action, the investigation timeline of this outbreak was compared with timelines of previous investigations conducted by NYCDOHMH meeting the following three criteria: 1) the outbreak included at least three patients with a positive laboratory test result for Salmonella reported through passive surveillance, such that the outbreak might have been possible to detect via an automated analysis using SaTScan or another method; 2) the investigation occurred during September 2009–May 2019 when graduate student interviewers were in place, such that staffing levels were sufficient to feasibly collect and assess exposures reported by patients (6); and 3) the public health response included an environmental assessment of a restaurant or grocery store.
The outbreak described in this report was detected within 2 days of the third case being reported through passive surveillance, compared with a median of 13 days (range = 6–57 days) for five previous outbreaks (Table). An environmental assessment was performed within 2 days of outbreak detection, compared with a median of 21 days (range = 8–111 days) for six previous outbreaks.
Discussion
This investigation illustrates the utility of integrating automated spatiotemporal cluster detection analyses into applied public health practice. In a jurisdiction with approximately 1,000 salmonellosis cases diagnosed each year,§ a focal cluster consisting initially of just five cases was detected by NYCDOHMH before any patient interviews were completed, patient isolates were received at a public health laboratory, or laboratory subtyping results were available. Rapid detection, coupled with interviews conducted by experienced investigators, facilitated food handler testing, environmental assessments highlighting food handling deficiencies, prioritization of patient isolates for molecular subtyping, and collection of patient leftovers for testing before they were discarded. This local investigation, which confirmed chicken as the outbreak source, was later incorporated into a multistate investigation of S. Blockley associated with chicken.
It is uncommon for NYCDOHMH to detect a salmonellosis outbreak in the absence of any laboratory subtyping data (8) or any single report of multiple ill patients. As of July 15, 2019, CDC PulseNet transitioned its primary molecular subtyping tool from PFGE to WGS, which will improve foodborne outbreak detection through detailed pathogen characterization (9,10). However, the additional time required for WGS testing could result in a lag in identifying some outbreaks; and some outbreaks might be missed if isolates for subtyping are unavailable with use of culture-independent diagnostic tests, or if not all isolates can be tested, given public health laboratory capacity limitations. In February 2019, ahead of PulseNet’s transition to WGS, NYCDOHMH set up automated analyses using SaTScan to detect salmonellosis clusters without regard to laboratory subtyping results.
Rapid detection of this focal, community-based outbreak relied on critical public health infrastructure and informatics, including automated and timely electronic laboratory reporting, transfer of disease reports to a disease surveillance database, geocoding of patients’ residences, and analyses using SaTScan. Once detected, the rapid outbreak response relied on adequately resourced student interviewers, epidemiologists, environmental health inspectors, and laboratory personnel. Establishing automated spatiotemporal cluster detection analyses for salmonellosis and other reportable diseases could aid in the detection of geographically focused, community-acquired outbreaks.
Acknowledgments
David Nicholas, New York State Department of Health; Amal Gulaid, Amanda Howarth, Kian Williams, Kevin Lovingood, Jacob Sim, Joseph Real, Susan Lloyd, Aaron Olsen, Bun Tha, Tanya Geiz, Yelena Chekoff, New York City Department of Health and Mental Hygiene; New York State Department of Agriculture and Markets.
Corresponding author: Julia Latash, [email protected], 347-396-2790.
1Bureau of Communicable Disease, New York City Department of Health and Mental Hygiene; 2Office of Environmental Investigations, New York City Department of Health and Mental Hygiene; 3Public Health Laboratory, New York City Department of Health and Mental Hygiene.
All authors have completed and submitted the International Committee of Medical Journal Editors form for disclosure of potential conflicts of interest. No potential conflicts of interest were disclosed.
* These authors contributed equally to this report.
† https://github.com/CityOfNewYork/communicable-disease-surveillance-nycdohmh.
References
- Kulldorff M; Information Management Services, Inc. SaTScan: software for the spatial, temporal, and space-time scan statistics. Boston, MA: Information Management Services, Inc.; 2015. https://www.satscan.org/
- City of New York. New York City health code and rules [Articles 11 and 13]. New York, NY: City of New York; 2019. https://www1.nyc.gov/assets/doh/downloads/pdf/about/healthcode/health-code-article11.pdf; https://www1.nyc.gov/assets/doh/downloads/pdf/about/healthcode/health-code-article13.pdf
- Kleinman K, Lazarus R, Platt R. A generalized linear mixed models approach for detecting incident clusters of disease in small areas, with an application to biological terrorism. Am J Epidemiol 2004;159:217–24. CrossRef PubMed
- Kulldorff M, Heffernan R, Hartman J, Assunção R, Mostashari F. A space-time permutation scan statistic for disease outbreak detection. PLoS Med 2005;2:e59. CrossRef PubMed
- Greene SK, Peterson ER, Kapell D, Fine AD, Kulldorff M. Daily reportable disease spatiotemporal cluster detection, New York City, New York, USA, 2014–2015. Emerg Infect Dis 2016;22:1808–12. CrossRef PubMed
- Waechter H, Reddy V, Hanson H, Balter S. A successful approach to Salmonella surveillance: using student interviewers to improve foodborne disease outbreak response in New York City. Food Prot Trends 2013;33:300–6.
- Food-borne intoxications. In: Heymann D, ed. Control of communicable diseases manual. 19 ed. Washington, DC: American Public Health Association; 2019.
- Peterson ER, Reddy V, Waechter H, Li L, Forney K, Greene SK. Prospective spatio-temporal and temporal cluster detection by Salmonella serotype. Online J Public Health Inform 2016;8:e30. CrossRef
- Tolar B, Joseph LA, Schroeder MN, et al. An overview of PulseNet USA databases. Foodborne Pathog Dis 2019;16:457–62. CrossRef PubMed
- Ladd-Wilson SG, Morey K, Koske SE, et al. Notes from the field: multistate outbreak of Salmonella Agbeni associated with consumption of raw cake mix—five states, 2018. MMWR Morb Mortal Wkly Rep 2019;68:751–2. CrossRef PubMed
FIGURE. Cases of salmonellosis (N = 17) included in a SaTScan* spatiotemporal cluster, by date reported to health department — New York City, May–June 2019
Abbreviations: PFGE = pulsed-field gel electrophoresis; WGS = whole genome sequencing.
Suggested citation for this article: Latash J, Greene SK, Stavinsky F, et al. Salmonellosis Outbreak Detected by Automated Spatiotemporal Analysis — New York City, May–June 2019. MMWR Morb Mortal Wkly Rep 2020;69:815–819. DOI: http://dx.doi.org/10.15585/mmwr.mm6926a2.
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