Syndromic surveillance using veterinary laboratory data: data pre-processing and algorithm performance evaluation

doi:10.1098/rsif.2013.0114

. 2013 Apr 10;10(83):20130114.

doi: 10.1098/rsif.2013.0114. Print 2013 Jun 6.

Syndromic surveillance using veterinary laboratory data: data pre-processing and algorithm performance evaluation

Fernanda C Dórea¹, Beverly J McEwen, W Bruce McNab, Crawford W Revie, Javier Sanchez

Affiliations

Affiliation

¹ Department of Health Management, Atlantic Veterinary College, University of Prince Edward Island, Charlottetown, Prince Edward Island, Canada. fdorea@upei.ca

PMID: 23576782
PMCID: PMC3645420
DOI: 10.1098/rsif.2013.0114

Syndromic surveillance using veterinary laboratory data: data pre-processing and algorithm performance evaluation

Fernanda C Dórea et al. J R Soc Interface. 2013.

. 2013 Apr 10;10(83):20130114.

doi: 10.1098/rsif.2013.0114. Print 2013 Jun 6.

Authors

Fernanda C Dórea¹, Beverly J McEwen, W Bruce McNab, Crawford W Revie, Javier Sanchez

Affiliation

¹ Department of Health Management, Atlantic Veterinary College, University of Prince Edward Island, Charlottetown, Prince Edward Island, Canada. fdorea@upei.ca

PMID: 23576782
PMCID: PMC3645420
DOI: 10.1098/rsif.2013.0114

Abstract

Diagnostic test orders to an animal laboratory were explored as a data source for monitoring trends in the incidence of clinical syndromes in cattle. Four years of real data and over 200 simulated outbreak signals were used to compare pre-processing methods that could remove temporal effects in the data, as well as temporal aberration detection algorithms that provided high sensitivity and specificity. Weekly differencing demonstrated solid performance in removing day-of-week effects, even in series with low daily counts. For aberration detection, the results indicated that no single algorithm showed performance superior to all others across the range of outbreak scenarios simulated. Exponentially weighted moving average charts and Holt-Winters exponential smoothing demonstrated complementary performance, with the latter offering an automated method to adjust to changes in the time series that will likely occur in the future. Shewhart charts provided lower sensitivity but earlier detection in some scenarios. Cumulative sum charts did not appear to add value to the system; however, the poor performance of this algorithm was attributed to characteristics of the data monitored. These findings indicate that automated monitoring aimed at early detection of temporal aberrations will likely be most effective when a range of algorithms are implemented in parallel.

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Figures

**Figure 1.**
Syndromic groups used to exemplify the times series used in this study. Data from 2008 and 2009 have been analysed in order to remove temporal aberrations, constructing an outbreak-free baseline.

**Figure 2.**
Synthetic outbreak simulation process. Data with no outbreaks were simulated reproducing the temporal effects in the baseline data. The same process was used to construct series that were for outbreak simulation, but counts were amplified up to four times. Filters of different shape and duration were then multiplied to these outbreak series. The resulting outbreaks were added to the baseline data. (Online version in colour.)

**Figure 3.**
Comparative analysis of the autocorrelation function and normality plots for the BLV series (years 2010 and 2011) before and after pre-processing. (Online version in colour.)

**Figure 4.**
ROC curves representing median sensitivity of outbreak detection, plotted against number of daily false alarms, for four different algorithms evaluated (rows), applied to data simulating three different syndromes (columns), and using five different outbreak shapes. Detection limits for each plotted point are shown in table 1. Error bars show the 25% to 75% percentile of the point value over four different scenarios of outbreak magnitude (one to four times the baseline) and three different scenarios of outbreak duration (one to three weeks). (Online version in colour.)

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References

1. Bravata DM, McDonald KM, Smith WM, Rydzak C, Szeto H, Buckeridge DL, Haberland C, Owens DK. 2004. Systematic review: surveillance systems for early detection of bioterrorism-related diseases. Ann. Intern. Med. 140, 910–922 - PubMed
1. Shmueli G, Burkom H. 2010. Statistical challenges facing early outbreak detection in biosurveillance. Technometrics 52, 39–5110.1198/TECH.2010.06134 (doi:10.1198/TECH.2010.06134) - DOI - DOI
1. Centers for Disease Control and Prevention (CDC) 2006. Annotated bibliography for syndromic surveillance. See http://www.cdc.gov/ncphi/disss/nndss/syndromic.htm .
1. Benneyan JC. 1998. Statistical quality control methods in infection control and hospital epidemiology. I. Introduction and basic theory. Infect. Control Hospital Epidemiol. 19, 194–21410.1086/647795 (doi:10.1086/647795) - DOI - DOI - PubMed
1. Woodall WH. 2006. Use of control charts in health-care and public-health surveillance. J. Quality Technol. 38, 89–104

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[1] Bravata DM, McDonald KM, Smith WM, Rydzak C, Szeto H, Buckeridge DL, Haberland C, Owens DK. 2004. Systematic review: surveillance systems for early detection of bioterrorism-related diseases. Ann. Intern. Med. 140, 910–922 - PubMed

[2] Bravata DM, McDonald KM, Smith WM, Rydzak C, Szeto H, Buckeridge DL, Haberland C, Owens DK. 2004. Systematic review: surveillance systems for early detection of bioterrorism-related diseases. Ann. Intern. Med. 140, 910–922 - PubMed

[3] Shmueli G, Burkom H. 2010. Statistical challenges facing early outbreak detection in biosurveillance. Technometrics 52, 39–5110.1198/TECH.2010.06134 (doi:10.1198/TECH.2010.06134) - DOI - DOI

[4] Shmueli G, Burkom H. 2010. Statistical challenges facing early outbreak detection in biosurveillance. Technometrics 52, 39–5110.1198/TECH.2010.06134 (doi:10.1198/TECH.2010.06134) - DOI - DOI

[5] Centers for Disease Control and Prevention (CDC) 2006. Annotated bibliography for syndromic surveillance. See http://www.cdc.gov/ncphi/disss/nndss/syndromic.htm .

[6] Centers for Disease Control and Prevention (CDC) 2006. Annotated bibliography for syndromic surveillance. See http://www.cdc.gov/ncphi/disss/nndss/syndromic.htm .

[7] Benneyan JC. 1998. Statistical quality control methods in infection control and hospital epidemiology. I. Introduction and basic theory. Infect. Control Hospital Epidemiol. 19, 194–21410.1086/647795 (doi:10.1086/647795) - DOI - DOI - PubMed

[8] Benneyan JC. 1998. Statistical quality control methods in infection control and hospital epidemiology. I. Introduction and basic theory. Infect. Control Hospital Epidemiol. 19, 194–21410.1086/647795 (doi:10.1086/647795) - DOI - DOI - PubMed

[9] Woodall WH. 2006. Use of control charts in health-care and public-health surveillance. J. Quality Technol. 38, 89–104

[10] Woodall WH. 2006. Use of control charts in health-care and public-health surveillance. J. Quality Technol. 38, 89–104

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Syndromic surveillance using veterinary laboratory data: data pre-processing and algorithm performance evaluation

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Syndromic surveillance using veterinary laboratory data: data pre-processing and algorithm performance evaluation

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