key: cord-0050198-4zyar6ix authors: Chen, Hsinchun; Zeng, Daniel; Yan, Ping title: New York City Syndromic Surveillance Systems date: 2009-07-14 journal: Infectious Disease Informatics DOI: 10.1007/978-1-4419-1278-7_11 sha: 66967ecdfceffebd44aefc2e11b948f2a451b0fb doc_id: 50198 cord_uid: 4zyar6ix The New York City (NYC) Department of Health and Mental Hygiene (DOHMH) has conducted prospective surveillance of nonspecific health indicators (syndromes) since 1995 (Heffernan et al., 2004a). The DOHMH syndromic surveillance system consists of (ED)-visits-based surveillance system and a few other complementary surveillance systems for Emergency Medical Services (EMS) ambulance dispatch calls, retail pharmacy sales, and work absenteeism data. These systems started operating separately, and different analytical methods are being employed by each of them. A “drop-in” syndromic surveillance system that deployed CDC field-staff to conduct 24 hours surveillance for bioterrorism related illness was implemented following the September 11th 2001 attack (Das et al., 2003; CDC, 2002). We use Table 11-1 to summarize these systems that comprise the syndromic surveillance activities in New York City. However, in the following text, the case study will focus around the ED visits based syndromic surveillance system in NYC. . Data files are transmitted to DOHMH daily, either as email attachments or through FTP. Half of the participating hospitals have already automated the transmission process. Files can be in several formats, most commonly as fixed-column or delimited ASCII text. "Data are read and translated into a standard format, concatenated into a single SAS dataset, verified for completeness and accuracy, and appended to a master archive." (Heffernan et al., 2004a (Heffernan et al., , 2004b . The NYC ED syndromic surveillance system uses an adaption of Kulldorff and Mostashari's one-dimensional temporal to evaluate citywide trends in syndrome visits and spatial scan statistic (Kulldorff, 1997 (Kulldorff, , 2001 to evaluate clustering in ED visits by hospital address and patient home zip code. The temporal scan statistic is a special case of the prospective space-time scan statistic. The analysis is conducted in a prospective setting with daily runs and a variable-length window consisting of the last 1, 2, or 3 days. In particular, the ratio of syndrome visits to nonsyndrome (other) visits during the most recent 1, 2, or 3 days is compared with a 2-week baseline. The spatial scan statistic approach requires comparing the observed to the expected number of cases in each geographic area. To control for purely spatial differences, expected counts of syndrome visits are derived from each area's history, rather than from the underlying census population. To detect rapidly emerging outbreaks, the approach takes the data from the observed cases from the last day and compares them with data from a 14-day baseline period, with a 1-day gap between the baseline and the date on which spatial clustering is being evaluated. The chief complaints captured by the ED visit records are classified into eight exclusive syndrome categories (Table 11 -2) with an SAS algorithm developed in-house. This algorithm scans the chief complaint field for character strings assigned to a syndrome. The coding algorithm is designed to capture a wide variety of common misspellings and abbreviations. If the chief complaints contain words or phrases from multiple categories, it will be coded according to the following priority-based assignment scheme: common cold > sepsis/dead on arrival > respiratory > diarrhea > fever > rash > asthma > vomiting > other visits. This scheme attempts to place each chief complaint into a single, specific syndrome. The two syndromes of particular interest for bioterrorism surveillance are the respiratory and fever syndromes in persons older than 13 years of age (Heffernan et al., 2004b) . The surveillance signals produced by the system are first reviewed by medical epidemiologists on a daily basis. A report consisting of graphs and a brief summary is distributed by electronic mail to program staff. Further validations are conducted through field investigations. Detailed field investigations of syndromic signals are meant to (1) identify the etiology of signals; (2) determine why a given syndromic surveillance system failed to detect an outbreak captured through traditional surveillance; (3) validate the utility of Spatial syndromic signals are followed up by reviewing the descriptive summary of the emergency department visits included in the signal. Hospital(s) contributing the largest number of excess cases are paid particular attention, by examining the specific syndromes triggering the signal and the line list of patients with their chief complaints produced, along with summary statistics for age, sex, and zip code. Syndromic signals are communicated to other hospital ED staff through phone calls to alert them of unusual disease patterns and to ask whether they have noted an increase in the frequency of syndrome visits or admission of seriously ill patients. Signals of elevated concern are further investigated by conducting field investigations including chart reviews, patient interviews, and onsite discussions with clinicians. Some sample graphs from the presentations of DOHMH syndromic surveillance made at the National Syndromic Surveillance Conference (Mostashari, 2002) are as shown in Figures 11-1 to 11-3. syndromic surveillance for early infectious disease outbreak detection. Daily analyses are reviewed with a medical epidemiologist, and a report containing detailed graphs and a brief summary is distributed by email to related program staff. If a signal investigation is performed, a more detailed report will be prepared and made available by the next day. "An external report summarizing citywide public health trends is also distributed daily to state and regional health officials, the New York City Office of Emergency Management, police departments, and fire departments. Hospital-specific, confidential reports are shared quarterly with participating emergency departments, comparing their facility to overall citywide trends" (Heffernan et al., 2004a (Heffernan et al., , 2004b . Community-wide increases in respiratory illness detected through syndromic surveillance are usually difficult to interpret. Syndromic surveillance analysts hypothesize that multiple data streams can help distinguish whether increases in several syndromic surveillance data sources daily, including ambulance from emergency rooms, and over-the-counter medication sales (data samples are shown in Figure 11-4) . Daily citywide ratio of ED respiratory over other visits was adjusted for day-of-week and holiday effects using linear regression. Volume spikes in the daily adjusted ratio were identified using the EARS CUSUM C3 method with a 14-day baseline. During the study period, five sustained, citywide spikes in ED respiratory illness were observed. Figure 11 -5 shows the plot of ED respiratory illness ratio over other visits adjusted day-of-week and holiday effects, with CUSUM signals marked and the corresponding areas shaded in gray. To investigate whether the signals are related to influenza or allergy season, the adjusted daily citywide ratios of OTC allergy over analgesics sales (gray), ED asthma over other visits (green), and ED fever-flu over other visits (blue) were also plotted (see Figure 11 -6). Comparing two sets of plots, i.e., the adjusted ratios of ED respiratory/ other visits (Figure 11 -5) and ratios of OTC, ED asthma, and ED-fever-flu ( Figure 11-6) , six signals of ED respiratory illness over a 15-day period in September and October were preceded by a spike in OTC allergy sales, and so were nine signals in May. These signals also coincided with increasing ED asthma visits while ED fever-flu visits remained constant. Instead, three consecutive signals in late November, 16 signals in December and 7 signals in February coincided with increasing ED fever-flu visits, while these periods showed minimal to no increases in ED asthma visits or OTC allergy sales. The signal patterns in the multiple data streams suggested that respiratory illness increases in Fall and Spring could be attributed to allergy or asthma, whereas the Winter increase in respiratory illness is more likely to be attributed to influenza (Das, 2005) . The respiratory illness syndromic surveillance practice at New York City demonstrated how multiple syndromic data streams can be helpful for characterizing ED respiratory syndrome signals. Syndromic surveillance in public health practice Use of ambulance dispatch data as an early warning system for community-wide influenza-like illness We provide the following key readings for the readers who might be interested in learning more details about the New York Syndromic Surveillance Weiss System Descriptions Monitoring Over-The-Counter Medication Sales Surveillance Systems for Early Detection of Disease of Disease Outbreaks