Data sources

Swedish Health Care Direct 1177 is a 24-hour nurse-on-call service comprising healthcare advice by telephone (1177) and by a website (www.1177.se). The record created for each call includes a contact cause, i.e. the main symptom [Reference Ernesater, Holmstrom and Engstrom10]. For the purposes of this study, we extracted five data streams on the number of calls per day and municipality: (i) gastrointestinal illness across age groups, grouping the following symptoms: nausea, vomiting, diarrhoea, stomach pain and stomach illness; (ii) adult gastrointestinal illness, grouping the same symptoms, but excluding children (<18 years); (iii) diarrhoea in adults; (iv) nausea and vomiting in adults; and (v) stomach pain in adults. All data used in this study were anonymized.

For the investigated period, 2007–2011, web query data were obtained from ‘Vårdguiden’, the Stockholm County Council website providing information to the public on illnesses, health and healthcare. The Swedish Institute for Communicable Disease Control (SMI) has direct access to the data from the Vårdguiden website and produces regular analyses on selected queries submitted to the website [Reference Hulth, Rydevik and Linde11, Reference Hulth and Rydevik12]. For this study, we extracted the number of web queries per day on the following gastrointestinal symptoms: vomiting (kräkningar), diarrhoea (diarré), stomach pain (magont) and gastrointestinal illness (magsjuka). The data represented word stems, allowing for inflections and spelling variations.

Data on OTC sales of antidiarrhoea medication were purchased from Pharmacy Services Ltd (Apotekens Service AB). After consultation with Pharmacy Services Ltd, we included all OTC antidiarrhoea drugs with ATC codes A07B and A07D. The extracted data covered daily unit sales of antidiarrhoea medication in pharmacies per municipality between 2006 and 2011. All Swedish pharmacies report daily OTC sales.

A list of point-source outbreaks was made to establish a basis for comparison of data sources. The point of departure was official reports of waterborne and foodborne outbreaks issued by the National Food Agency in Sweden. We decided on three criteria for inclusion of outbreaks: First, we selected larger outbreaks, excluding outbreaks comprising fewer than 100 cases. Second, the time window was limited to 2007–2011 avoiding the first years of establishment of the telephone triage and web-based healthcare services. Third, the time of the outbreak had to be within the temporal limits of all data sources. In the following, we refer to an outbreak by the name of the municipality in question.

Methods of analysis

The evaluation of data sources consisted of three parts: (1) validation of outbreak signals, (2) estimation of signal rates and (3) signal detection analysis. The validation part contained visual inspection and statistical analysis of count data per day, i.e. number of 1177 calls, web queries and OTC units sold. The purpose was to identify true outbreak signals (deviations) as distinct from background noise (baseline variation). The estimation part consisted of calculating the magnitude of the outbreak signals to establish signal rates, i.e. the average number of signals per case. Finally, the detection part involved statistical analysis to identify abnormal signals before outbreak peaks, as well as calculations to assess the sensitivity and specificity of the data stream in question.

Signal validation

The validation process began by defining outbreak periods and midpoints. The midpoint was defined as the day when the local or regional authorities first issued public information about the outbreak. If public information was issued in the evening, the midpoint was taken as the date of the following day. Consequently, the outbreak midpoint divided the outbreak period into two phases: low and high public awareness, respectively. For outbreaks without any official public information, the midpoint was defined by the date of the first consumer complaint to the regional or local authorities.

For each outbreak, two outbreak periods were defined with respect to the midpoint, one narrow (±7 days, 15 days in total) and one wide (±14 days, 29 days in total). For each outbreak, two baseline periods were also defined, ±14 days and ±28 days, respectively, minus the corresponding outbreak period, creating baseline periods of 14 and 28 days. Daily count data were plotted and visually inspected for each combination of outbreak and source of data, and also extracted and summed for outbreak and baseline periods. The sums of signal counts for outbreak and baseline periods were compared using Pearson's χ ²:

$${\rm \chi}^2 = \displaystyle{{({\rm OS} - {\rm E}_{{\rm OS}} )^2} \over {{\rm E}_{{\rm OS}}}} + \displaystyle{{({\rm BS} - {\rm E}_{{\rm BS}} )^2} \over {{\rm E}_{{\rm BS}}}},$$

where OS is sum of outbreak signal counts, E_OS is expected outbreak signal counts, BS is the sum of baseline signal counts, and E_BS is the expected baseline signal counts.

Furthermore:

$${\rm E}_{{\rm OS}} = \displaystyle{{{\rm OD}} \over {{\rm OD} + {\rm BD}}} \times {\rm TSC},$$

$${\rm E}_{{\rm BS}} = \displaystyle{{{\rm BD}} \over {{\rm OD} + {\rm BD}}} \times {\rm TSC},$$

where OD is number of days of the outbreak period, BD is number of days of the baseline period and TSC is total signal count (i.e. OS + BS).

The STN ratio was calculated by dividing the difference in means between signal counts for outbreak baseline periods by the standard deviation of the baseline counts:

$${\rm STN} = \displaystyle{{{\rm mean}({\rm OSC}) - {\rm mean}({\rm BSC})} \over {{\rm SD}({\rm BSC})}},$$

where OSC is daily signal counts during the outbreak period, BSC is the daily signal counts during the baseline period and SD(BSC) is standard deviation of daily signal counts during the baseline period.

Outbreak signals were considered validated if the following criteria were met: (1) positive visual inspection; (2) STN > 1; and (3) χ ² > 6·635 (upper limit for 99% confidence) for at least one time period (2 or 4 weeks).

Signal estimation

For the validated outbreak signals, the signal rates, i.e. the signal-to-case ratios, were estimated. This was done by calculating the deviation of signal counts from their expected values for observed outbreak periods, and then relating the magnitude of deviation to the number of cases in the outbreak:

$${\rm SR} = \displaystyle{{{\rm SC}_{\rm O} - {\rm SC}_{\rm E}} \over {{\rm NC}}},$$

where SR is signal rate (signal-to-case ratio), SC_O is signal count for the observed outbreak period, SC_E is expected signal count for the observed outbreak period and NC is total number of outbreak cases, according to epidemiological studies or official outbreak reports.

The observed outbreak periods should not be confused with the fixed outbreak periods defined for signal validation. The observed periods were defined by pooling existing information on the outbreaks, including epidemiological studies, outbreak investigations and the syndromic data sources in question. The criterion was to define periods broad enough to cover real outbreak durations, while as narrow as possible to minimize signal noise. Small variations in observed outbreak periods were not critical for the point estimations of signal rates, although they influenced the confidence intervals.

Regression analysis of signal counts on municipality population size, excluding the targeted municipality, was used to estimate the expected (predicted) signal count and the prediction interval for the targeted municipality. Linear regression was used when the mean signal counts for the observed outbreak periods were >25. For mean signal counts <25, Poisson regression analysis was used. The linear regression model was as follows:

$${\rm SC}_{\rm E} = \beta _1 \times {\rm population}\;{\rm size} + \beta _0,$$

$${\rm SC}_{\rm O} = \beta _1 \times {\rm population}\;{\rm size} + \beta _0 + {\rm residual},$$

$${\rm SR} = \displaystyle{{{\rm SC}_{\rm O} - {\rm SC}_{\rm E}} \over {{\rm NC}}},$$

$${\rm SC}_{{\rm E,High}} = {\rm SC}_{\rm E} + 2 \times {\rm PE},$$

$${\rm SC}_{{\rm E,Low}} = {\rm SC}_{\rm E} - 2 \times {\rm PE},$$

$${\rm PI}:\left[ {\displaystyle{{{\rm SC}_{\rm O} - {\rm SC}_{{\rm E,High}}} \over {{\rm NC}}},\displaystyle{{{\rm SC}_{\rm O} - {\rm SC}_{{\rm E,Low}}} \over {{\rm NC}}}} \right],$$

where PE is the prediction error in the regression model for the targeted municipality, SC_E,Low(High) is the low(high) limit of expected signal count for the outbreak period and PI is the prediction interval.

Signal detection

For the largest outbreaks and the data source with the largest STN and highest SR values, a signal detection analysis was carried out to evaluate the potential of different data streams for EED, i.e. outbreak signal detection before the outbreak midpoint. For the observed outbreak periods before the outbreak midpoints, a binomial distribution was applied and expected values and standard deviations of daily signal counts were calculated. The signal count at day t for municipality i (C _t,i ) was classified as an outbreak signal if it exceeded a threshold T _t,i :

$$ {\rm T}_{t,i} = \max ( L, V),$$

$$L = [0,1,2,3, \ldots ],$$

$$V = ({\rm E}[{\rm C}_{t,i} ] + L \times {\rm SD}({\rm C}_{t,i} )),$$

$$L = [0,1,2,3, \ldots ]{\rm E}\left[ {{\rm C}_{t,i}} \right] = p_{t,i} \times N_i ,$$

$${\rm SD}({\rm C}_{t,i} ) = \sqrt {N_i \times p_{t,i} \times (1 - p_{t,i} )},$$

$$\eqalign{ p_{t,i} = &{\displaystyle{{\sum\nolimits_{j = 1,j \ne i}^{n_i} {\sum\nolimits_{\tau} {{\rm C}_{\tau, j}}}} \over {4 \times \sum\nolimits_{j = 1, j \ne i}^{n_i} {N_j}}},} \cr &{\tau \in \{ t - 14,t - 21,t - 28,t - 35\}},$$

where L is the minimum number of signal counts for a positive outbreak signal, V is the threshold for a positive outbreak signal based on binomial distribution, C _t,i is the daily signal count of municipality i at time t, N _i is the population size of municipality i, p _t,i is the probability of a single 1177 call at time t from municipality i and n _i is the number of municipalities in the county where municipality i is located.

The threshold T _t,i was taken as the maximum of the fixed value L and the varying value V, defined by the number L of standard deviations above the expected value. The level L set the minimum number of signal counts that the daily count needed to exceed to qualify as a positive outbreak signal. Daily counts exceeding level 3 (low) were described as weak signals and daily counts exceeding level 5 (high) as strong signals. The probability p _t,i was calculated on the basis of the sum of signal counts in a county for four weekdays, 2–5 weeks back in time, divided by four times the population size of the county.

To evaluate the sensitivity and specificity of the signal detection during observed outbreak periods, the target municipality defined the outbreak condition. The control condition was defined by non-neighbouring municipalities in the same county. Daily signal counts C _t,i above and below T _t,i in the outbreak condition defined hits and misses, respectively, whereas C _t,i above and below T _t,i in the control condition defined false alarms (FA) and correct rejections (CR), respectively.

$${\rm Sensitivity} = \displaystyle{{{\rm Hits}} \over {{\rm Hits} + {\rm Misses}}},$$

$${\rm Specificity} = \displaystyle{{{\rm CR}} \over {{\rm CR} + {\rm FA}}}.$$