key: cord-0702929-xusaegg0 authors: Dirlikov, Emilio; Zhou, Suizan; Han, Lifeng; Li, Zhijun; Hao, Ling; Millman, Alexander J.; Marston, Barbara title: Use of public data to describe COVID-19 contact tracing in Hubei Province and non-Hubei provinces in China between 20 January and 29 February 2020 date: 2019-08-12 journal: Western Pac Surveill Response J DOI: 10.5365/wpsar.2021.12.3.808 sha: 4940f6fc95ab84605b1b1141ea3e38129f75e5f3 doc_id: 702929 cord_uid: xusaegg0 OBJECTIVE: Contact tracing has been used in China and several other countries in the WHO Western Pacific Region as part of the COVID-19 response. We describe COVID-19 cases and the number of contacts traced and quarantined per case as part of COVID-19 emergency public health response activities in China. METHODS: We abstracted publicly available, online aggregated data published in daily COVID-19 situational reports by China’s National Health Commission and provincial health commissions between 20 January and 29 February 2020. The number of new contacts traced by report date was computed as the difference between total contacts traced in consecutive reports. A proxy for the number of contacts traced per case was computed as the number of new contacts traced divided by the number of new cases. RESULTS: During the study period, China reported 80 968 new COVID-19 cases and 659 899 contacts. In Hubei Province, there were 67 608 cases and 264 878 contacts, representing 83% and 40% of the total, respectively. Non-Hubei provinces reported tracing 1.5 times more contacts than Hubei Province; the weekly number of contacts traced per case was also higher in non-Hubei provinces than in Hubei Province and increased from 17.2 in epidemiological week 4 to 115.7 in epidemiological week 9. DISCUSSION: More contacts per case were reported from areas and periods with lower COVID-19 case counts. With other non-pharmaceutical interventions used in China, contact tracing and quarantining large numbers of potentially infected contacts probably contributed to reducing SARS-CoV-2 transmission. C oronavirus disease 2019 (COVID-19) is a respiratory illness caused by infection with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), first identified in December 2019 in Hubei Province, China. 1 By 31 January 2020, at least one case had been reported from each of mainland China's 31 provincial-level administrative units, and by 29 February, a total of 80 968 cases had been reported. 2 On 30 January 2020, WHO declared COVID-19 a public health emergency of international concern, and on 11 March 2020, WHO declared the outbreak a global pandemic. Non-pharmaceutical interventions (NPIs) for respiratory virus outbreaks are used to prevent exposures and reduce transmission through individual or community action. 3, 4 With several other countries in the Western Pacific Region, 5-7 China implemented COVID-19 contact tracing with quarantine as part of a comprehensive COVID-19 prevention and control strategy, which also included mask use, emphasis on hand hygiene, enforced physical distancing and movement restrictions within and between provinces. 8,9 China's contact-tracing strategy was to identify and quarantine exposed individuals to prevent additional disease transmission. On 20 January 2020, China designated COVID-19 a notifiable disease and updated the "Frontier Health and Quarantine Law" to allow quarantine of contacts. 10 National guidelines on epidemiological This activity was deemed not to be research as defined in United States Government 45 CFR 46.102(l), and institutional review board approval was not required. Non-research determination was provided by the US CDC Center for Global Health in May 2020. In addition to national and Hubei Province data, complete data were available for 22 of 30 non-Hubei provincial-level administrative units: Anhui, Chongqing Municipality, Gansu, Guangxi Autonomous Region, Guizhou, Hainan, Hebei, Heilongjiang, Henan, Hunan, Inner Mongolia Autonomous Region, Jiangsu, Jiangxi, Jilin, Liaoning, Qinghai, Shaanxi, Shandong, Shanxi, Tianjin Municipality, Tibet Autonomous Region and Zhejiang (Fig. 1) . Eight provinces, comprising 26% of the total population, were excluded from the analysis because of no or insufficient reported data (Beijing Municipality, Fujian, Guangdong, Ningxia Autonomous Region, Shanghai Municipality, Sichuan, Xinjiang Autonomous Region and Yunnan). During epidemiological weeks 4-9, the NHC reported 80 968 new COVID-19 cases and 659 899 contacts traced. These included 67 608 cases (83% of total cases reported) and 264 878 contacts (40% of total reported contacts traced) in Hubei Province. During the same period, non-Hubei provinces reported an aggregate total of 13 The weekly number of contacts traced per case remained <10 in Hubei Province throughout the study period (median = 6.45; range = 2.0 in epidemiological week 7 to 8.5 in epidemiological week 4); the lowest value occurred when 18 453 clinically diagnosed cases were reported as part of the case counts for 12-15 February (epidemiological week 7), which increased the investigations and management of contacts were issued and updated several times, and responsibility for contact tracing was delegated to the local level. 11, 12 The national guidelines defined contacts as: "anyone who may have had contact with a case through a range of circumstances or activities including being family members, relatives, friends, colleagues, classmates, health care workers, and services personnel". 12 The national guidelines further detailed eight categories of close contacts (e.g. family members living together, direct caregivers or providers of medical treatment or care services and other people considered by onsite investigators to meet the criteria for a close contact). To describe the number of contacts traced and quarantined per case as part of COVID-19 emergency public health response activities, we compared data from Hubei Province with those from the 30 other mainland provinces (non-Hubei provinces) reported between 20 January and 29 February 2020. We compared the numbers in Hubei Province with those in non-Hubei provinces because the majority of reported cases occurred in Hubei Province. We abstracted publicly available, online aggregated data reported in daily situational reports at the national level by the NHC and provincial level by provincial health commissions (see Appendix: data sources). For epidemiological weeks 4-9 (weeks ending on Saturdays), we collected daily reported data on newly reported cases and total contacts traced and placed under medical observation. Data were reviewed for abstraction errors, including data entry errors and data completeness. Provincial data that were >95% complete (i.e. reporting for >95% of days between 20 January and 29 February) were included. When situational reports included corrections to reported data, the corrected data were used for the day reported. The number of new contacts traced by report date was computed as the difference between the total number of contacts traced on consecutive reports. A proxy for the number of contacts traced per case was computed as the number of new contacts traced divided by the number of new cases. Calculations were performed by epidemiological week. Data were analysed at national and provincial levels (in the included provinces) and for the 30 non-Hubei provinces combined, calculated Contact tracing and data reporting varied by province, with non-Hubei provinces reporting more contacts traced per case, and the number of contacts traced per case in these provinces increasing during the study period. In Hubei Province, the average number of contacts traced per case remained <10 during this period, and the number of contacts traced decreased with increasing numbers of reported cases. Although non-Hubei provinces reported only 17% of total cases, 1.5 times more contacts were traced than in Hubei Province. The differences between provinces may reflect local capacity for contact tracing, differences in local disease transmission, evolving guidelines and implementation of other NPIs. For example, a lockdown in Wuhan City began on 23 January 2020, followed by widespread movement restrictions within and between provinces 1 to mitigate transmission; national travel restrictions began to be lifted on 17 February 2020, although movement restrictions continued. Implementation differed among provinces. 9 denominator substantially and consequently reduced the number of contacts traced per case ( Fig. 2 and Table 1 ). The weekly number of contacts traced per case was higher in non-Hubei provinces than in Hubei Province and increased from 17.2 in epidemiological week 4 to 115.7 in epidemiological week 9 ( Fig. 2 and Table 1 ). Data from the 22 non-Hubei provinces indicated that the number of contacts traced per case generally increased as case counts declined, while the reported number of contacts traced either remained high or increased over time. For example, Anhui Province reported 60 cases and 1023 contacts traced during epidemiological week 4 (17.1 contacts traced per case) and 1 case and 915 reported contacts traced during epidemiological week 9 (915 contacts traced per case). With other NPIs used in China, contact tracing and quarantining of a large number of potentially infected contacts probably contributed to reducing SARS-CoV-2 transmission. 10 Contact tracing with quarantine potentially helped to mitigate the risk of transmission by Contact tracing with quarantine is resource intensive. For example, in Wuhan City, contact tracing was conducted by 1800 epidemiologists working in teams of five. 8 Data on provincial contact-tracing resources were not available. Geographical and temporal differences may have affected the availability of resources, including trained staff for contact tracing and medical The weekly number of contacts traced per case was calculated as the number of new contacts traced in an epidemiological week divided by the number of new cases reported in that week. Data for the 30 non-Hubei provinces were calculated as the difference between national totals and totals for Hubei Province. In Hubei Province, the lowest value occurred when 18 453 clinically diagnosed cases were reported in case counts for 12-15 February (epidemiological week 7), which increased the denominator substantially and consequently lowered the number of contacts traced per case. Future investigations should better define the role of COVID-19 contact tracing and quarantine, including timeliness, prioritization of contacts who are more likely to be associated with transmission and the effectiveness of contact tracing in contexts that differ epidemiologically, socially and with respect to resource availability. We thank RJ Simonds for administrative and technical support. None of the authors has a conflict of interest. No funding was given for this activity. The conclusions, findings and opinions expressed by authors contributing to this journal do not necessarily reflect the official position of the US Department of Health and Human Services, the US Public Health Service or the US Centers for Disease Control and Prevention. This report has several limitations. First, the public data did not include contact-by-exposure type, and it is likely that the actual number of contacts traced differed by type of exposure (e.g. family, shopping centre, public transport). Therefore, the number of "contacts traced per case" may be overestimated when large numbers of contacts are linked to a single case (e.g. attending a public gathering with a confirmed case). Second, without data on individual patients, our analysis is based on aggregated data and subject to ecological fallacy. For example, contacts traced reported in one week could have been those of cases reported in the previous week. Third, data on contact-tracing outcomes and resources were not available for analysis. All contacts were assumed to have been quarantined according to the national guidelines, and provinces were assumed to have implemented contact-tracing guidelines uniformly, although inter-provincial differences may have affected the comparability of the reported data. The data could not be verified externally, the data collection methods were unknown, and it was not known whether all reported contacts traced were linked to reported cases. Finally, reported data on contact tracing were missing or incomplete for eight provinces, which were excluded from the analysis. Despite these limitations, our findings describe contact tracing in China during the COVID-19 response and differences between Hubei Province and non-Hubei provinces based on publicly available data. We found higher rates of contacts traced and quarantined in areas with lower numbers of reported COVID-19 cases, suggesting that contract tracing may have been more Association of public health interventions with the epidemiology of the COVID-19 outbreak in Wuhan Chinese Center for Disease Control and Prevention. Tracking the epidemic. 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