key: cord-0723081-cg6w1045
authors: Dawood, Fatimah S; Ricks, Philip; Njie, Gibril J; Daugherty, Michael; Davis, William; Fuller, James A; Winstead, Alison; McCarron, Margaret; Scott, Lia C; Chen, Diana; Blain, Amy E; Moolenaar, Ron; Li, Chaoyang; Popoola, Adebola; Jones, Cynthia; Anantharam, Puneet; Olson, Natalie; Marston, Barbara J; Bennett, Sarah D
title: Observations of the global epidemiology of COVID-19 from the prepandemic period using web-based surveillance: a cross-sectional analysis
date: 2020-07-29
journal: Lancet Infect Dis
DOI: 10.1016/s1473-3099(20)30581-8
sha: bce3935001770ff0c03acd056ee763ce4d210f1e
doc_id: 723081
cord_uid: cg6w1045

Background Scant data are available about global patterns of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) spread and global epidemiology of early confirmed cases of COVID-19 outside mainland China. We describe the global spread of SARS-CoV-2 and characteristics of COVID-19 cases and clusters before the characterisation of COVID-19 as a pandemic. METHODS: Cases of COVID-19 reported between Dec 31, 2019, and March 10, 2020 (ie, the prepandemic period), were identified daily from official websites, press releases, press conference transcripts, and social media feeds of national ministries of health or other government agencies. Case characteristics, travel history, and exposures to other cases were abstracted. Countries with at least one case were classified as affected. Early cases were defined as those among the first 100 cases reported from each country. Later cases were defined as those after the first 100 cases. We analysed reported travel to affected countries among the first case reported from each country outside mainland China, demographic and exposure characteristics among cases with age or sex information, and cluster frequencies and sizes by transmission settings. FINDINGS: Among the first case reported from each of 99 affected countries outside of mainland China, 75 (76%) had recent travel to affected countries; 60 (61%) had travelled to China, Italy, or Iran. Among 1200 cases with age or sex information, 874 (73%) were early cases. Among 762 early cases with age information, the median age was 51 years (IQR 35–63); 25 (3%) of 762 early cases occurred in children younger than 18 years. Overall, 21 (2%) of 1200 cases were in health-care workers and none were in pregnant women. 101 clusters were identified, of which the most commonly identified transmission setting was households (76 [75%]; mean 2·6 cases per cluster [range 2–7]), followed by non-health-care occupational settings (14 [14%]; mean 4·3 cases per cluster [2–14]), and community gatherings (11 [11%]; mean 14·2 cases per cluster [4–36]). INTERPRETATION: Cases with travel links to China, Italy, or Iran accounted for almost two-thirds of the first reported COVID-19 cases from affected countries. Among cases with age information available, most were among adults aged 18 years and older. Although there were many clusters of household transmission among early cases, clusters in occupational or community settings tended to be larger, supporting a possible role for physical distancing to slow the progression of SARS-CoV-2 spread. FUNDING: None.

Before 2019, novel coronaviruses had resulted in two major respiratory illness outbreaks during the 21st century: severe acute respiratory syndrome (SARS), which occurred during 2002-04; and Middle East respiratory syndrome (MERS), which began in 2012. As of July 8, 2020, infection with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has resulted in more than 11 million laboratory-confirmed cases of COVID-19 and 530 000 confirmed deaths. 1 A cluster of pneumonia cases of unknown cause was reported in the city of Wuhan, China, by health officials on Dec 31, 2019. 2 By Jan 7, 2020, the China National Institute of Viral Disease Control and Prevention had confirmed the genetic sequence of SARS-CoV-2 and that the virus was associated with the previously reported pneumonia cluster in Wuhan. 3 On Jan 20, 2020, the US Centers for Disease Control and Prevention (CDC) activated its emergency operations centre in response to the emerging public health threat of COVID-19. On Jan 30, 2020, WHO declared the COVID-19 outbreak a Public Health Emergency of International Concern, and 6 weeks later, WHO characterised the COVID-19 epidemic as a pandemic. 4 Collection of data about cases of COVID-19 from publicly available official reports has been done by other groups for rapid analyses to inform public health response measures, an approach sometimes referred to as infodemiology. [5] [6] [7] [8] Using data obtained from web-based surveillance done as part of CDC's emergency response, we aimed to describe the global spread of SARS-CoV-2 and characteristics of cases and clusters in affected countries during the prepandemic period (ie, from Dec 31, 2019, to March 10, 2020).

On Jan 20, 2020, the US CDC began web-based surveillance to identify newly confirmed cases of COVID-19 outside of mainland China, to inform CDC's global and domestic emergency response. This data collection was done to monitor and assess the COVID-19 outbreak to provide situational awareness and priority setting during an ongoing pandemic. As such, this work was deemed by CDC to be non-research public health surveillance, as defined in title 45 of the electronic Code of Federal Regulations, part 46.102 (L) (2) .

To identify new cases of COVID-19, a team of epidemiologists screened the following data sources on a daily basis: national ministry of health or other government websites, press releases, press con ference transcripts, and social media feeds (ie, Facebook, Twitter, Instagram); situation reports from national ministries of health and CDC offices in other countries; and media reports. Reports of confirmed cases of COVID-19 from nonpublicly available (ie, situation reports) or unofficial (ie, media reports) sources were verified with publicly available information from ministries of health or other government websites, and these electronic source documents were downloaded and archived locally. Data from publicly available official sources were then abstr acted and entered into a standardised electronic line list, in which each row represents a case and each column represents a variable. Variables abstracted included report date, illness onset date, country, patient's age and sex, whether the case occurred in a health-care worker or a pregnant woman, travel history, exposure to a previously confirmed case of COVID-19, links to known COVID-19 clusters, and exposure setting (family or household, occupational, community gathering, transport, or other). The appendix (pp 2-3) provides additional surveillance details. A com par i son of weekly case counts detected through CDC's web-based surveillance platform compared with case counts pub lished in WHO situation reports showed high concordance (unpublished data).

Countries with at least one confirmed case of COVID-19 identified through web-based surveillance were classified as affected. Information from an infected individual about recent travel to a country with confirmed cases of COVID-19, and about any contact with a previously confirmed case of COVID-19, was abstracted from publicly available case descriptions. Cases were cate gorised as having no epidemiological link to an affected country or to a previously confirmed case if source documents confirmed that there were no such links; otherwise, cases were categorised as having insufficient information to make this assessment.

A cluster was defined as two or more cases with an epidemiological link based on contact history and could entail multiple generations of infection (ie, cases might not all be directly linked to the primary case in the cluster). The primary case in a cluster was defined as the individual with the earliest illness onset date. For every cluster, transmission settings were categorised as family or household, occupational, community gathering, close contact not otherwise specified, or other; categor isation was based on narrative descriptions of See Online for appendix

Evidence before this study We searched PubMed between Dec 31, 2019, and April 14, 2020, with the terms "coronavirus" AND "travel" AND "global". Our search identified 49 publications. To date, scant data are available about global patterns of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) spread. Five publications described studies that modelled the effect of global travel on SARS-CoV-2 spread, but no studies used global case data to describe travel exposures among early COVID-19 cases in different countries. We also searched PubMed between Dec 31, 2019, and April 14, 2020, with the terms "coronavirus" AND "cluster". Our search identified 86 publications, of which 25 described individual clusters or small numbers of clusters (fewer than ten in each publication) from individual countries, but no studies summarised cluster characteristics from a global perspective.

Our analysis uses global epidemiological data from reported cases of COVID-19 to characterise the early spread of the disease and characteristics of cases and clusters of cases. Using publicly available data from national ministries of health and other government official websites and press releases, our analysis provides insights about routes of spread, the age and sex distribution of early confirmed cases and deaths, and commonly identified early transmission patterns.

Our findings show the possible contribution of travel from a few countries to the global spread of SARS-CoV-2, confirm age and sex characteristics of early cases of COVID-19 reported from mainland China and several other countries to date, and identify transmission settings that played a role in early SARS-CoV-2 spread. Our analysis also highlights the relatively late detection of SARS-CoV-2 in the WHO African region and remaining knowledge gaps, including the paucity of case data from low-income countries.

cases (appendix pp 2-3). One cluster could contribute case counts to more than one trans mission setting since transmission settings could vary by generation of spread.

For this analysis, the prepandemic period of COVID-19 was defined as Dec 31, 2019, to March 10, 2020, based on characterisation of COVID-19 as a pandemic by WHO on March 11, 2020 . Analytical populations are shown in figure 1. Countries and locations were defined as WHO Member States (n=194) plus the locations Hong Kong, Liechtenstein, Macau, Palestine, and Taiwan. To characterise the global spread of SARS-CoV-2 by region during this period, we calculated the number of countries and locations reporting at least one COVID-19 case by WHO region (ie, African, Americas, Eastern Mediterranean, European, South-East Asian, and Western Pacific) and epidemiological week, with week 1 corresponding to Dec 29, 2019, to Jan 4, 2020. We also analysed the frequency of travel exposures from previously affected countries among the first case reported in each country and location.

To characterise cases of COVID-19 in affected countries, we restricted the analysis to cases with information available about the patient's age or sex, and we used availability of this information as an indicator of overall data completeness. We calculated frequencies of patients' baseline cha racteristics, exposure histories, and death as an outcome. Frequency of hospitalisation was not analysed because data were not available to differentiate hospitalisation for isolation alone versus clinical care. We also calculated the frequency of cases by the World Bank 2020 income classification category 9 of reporting countries.

To assess changes in the epidemiology of COVID-19 in countries as outbreaks within countries progressed, the analysis was stratified by early cases (defined as up to the first 100 cases reported from each country) and later cases (defined as cases reported after the first 100 from each country). Characteristics of early and later cases were compared using the χ² test for categorical variables or t test for continuous variables; a p value of less than 0·05 was considered statistically significant.

To characterise COVID-19 clusters, we calculated the frequency of clusters by transmission setting and the average number of cases associated with each cluster type. Clusters were first identified from among cases with data for age or sex. Then, to identify the total number of cases and transmission settings associated with each cluster, data were analysed from the full line list dataset, regardless of whether age, sex, or both were known. We used SAS version 9.4 (SAS Institute, Cary, NC, USA) for statistical analyses.

No external funding was received for this analysis. The corresponding author had full access to all data in the study and had final responsibility for the decision to submit for publication.

From Dec 31, 2019, to March 10, 2020 (corresponding to epidemiological weeks 1-11 of the COVID-19 outbreak), 100 (50%) of 199 countries and locations (including mainland China) reported cases of COVID-19 (table 1; figure 2 ). During the first 3 weeks of the COVID-19 outbreak, cases were reported from only two countries outside of mainland China: Japan and Thailand. During weeks 4 and 5, 24 additional countries reported cases, including the first confirmed cases of COVID-19 from countries in the Americas region (first affected country, the USA), the European region (first affected country, Germany), and the Eastern Mediterranean region (first affected country, United Arab Emirates). Subsequently, the number of affected count r ies plateaued until week 9, when the number of countries in the Eastern Mediterranean region reporting cases of COVID-19 increased from four (17% of countries in the region) to 11 (48%). During weeks 9-11, the proportion of countries and locations with confirmed cases of COVID-19 increased from 32% to 50%, and the first cases were reported from the African region (first affected country, Algeria). By March 10, 2020, just before WHO characterised the COVID-19 outbreak as a pandemic, 45 (83%) of 54 countries and locations in the European region, 16 (70%) of 23 in the Eastern Mediterranean region, and seven (64%) of 11 in the South-East Asian region had reported COVID-19 cases, whereas only 13 (37%) of 35 countries in the Americas region and six (13%) of 46 countries in the African region had reported cases. Although only 13 (43%) of 30 countries in the Western Pacific region had reported cases by week 11, most countries without cases were remote island states with relatively small population sizes.

As of March 10, 2020, 99 countries and locations outside of mainland China had reported cases of COVID-19, of which 75 (76%) identified their first-reported case in an Week 2 (Jan 5 to Jan 11, 2020)

Week 3 (Jan 12 to Jan 18, 2020)

Week 4 (Jan 19 to Jan 25, 2020)

Week 5 (Jan 26 to Feb 1, 2020)

Week 6 (Feb 2 to Feb 8, 2020)

Week Of 1200 cases with age or sex information, 874 (73%) were early cases and 326 (27%) were later cases. Among the 874 early cases, 690 (79%) were from high-income countries, whereas two (<1%) were from low-income countries (table 2). The median age of 762 early cases with age information was 51 years (IQR 35-63); 25 (3%) of 762 cases with age information were in children younger than 18 years. 460 (56%) of 826 early cases with sex information were in males. 375 (43%) of 874 early cases reported travel from an affected country, 244 (28%) reported contact with a previously confirmed COVID-19 case, and 130 (15%) had no reported epide miological link to travel to an affected country or a previously confirmed case. Compared with 874 early cases, the 326 later cases were more likely to have no reported epidemiological link to travel or a previously confirmed case or insuffi cient information about exposure history (255 [29%] vs 282 [87%]; p<0·0001). Most cases in children with exposure history (20 of 23 [87%]), regardless of whether they were early or later cases, were associated with travel from an affected country, contact with a previously confirmed case, or both.

Overall, 52 deaths were identified among the 1200 cases with data available for age or sex. Cases with a reported outcome of death were older (median age 72 years [IQR 62-82]) than were those who did not die (55 years ; p<0·0001); the age range of cases who died was 35-94 years, and no deaths were reported in children. Dates of symptom onset and death were available for 12 cases; among these, the median time from symptom onset to death was 18 days (IQR 10-23).

Among the 1200 cases with data for age or sex, 21 (2%) were reported among health-care workers. Of these 21 cases, seven (33%) had clear reports of exposure to other cases among health-care workers or patients, six (29%) had other exposures that were not related to health-care settings, including three that had a history of recent travel to an affected country, and eight (38%) had inadequate information about exposures to ascertain exposure setting. Although 184 (15%) of 1200 cases were reported in women aged 18-49 years, none of these women were known to be pregnant. 386 (32%) of 1200 cases with data for age or sex were linked to 101 known clusters from 29 countries (Algeria, Australia, Austria, Bulgaria, Canada, Chile, Croatia, Czech Republic, France, Germany, Greece, Hong Kong, India, Israel, Italy, Japan, Lebanon, Macau, Malaysia, Philippines, Romania, Senegal, Singapore, South Korea, Spain, Taiwan, Thailand, United Arab Emirates, and Vietnam; table 3; figure 2 ). All identified primary cases were in adults aged 18 years and older. 44 (44%) of 101 clusters were described as occurring among close contacts without additional information about trans mission setting. The most commonly identified transmission setting among clusters was households (76 [75%]), followed by non-health-care occupational settings (14 [14%] ), and community gatherings (11 [11%] ). Although household transmission was noted in three-quarters of clusters, fewer cases per cluster were recorded (mean 2·6 [range 2-7]) than in other transmission settings. By contrast, community gatherings accounted for roughly a tenth of clusters but were associated with the highest mean number of cases per cluster (14·2, range 4-36). Clusters associated with community gatherings included transmission among tour groups (n=4), faith-based events (n=4), and dinner parties (n=3). Nine clusters involved transmission associated with transport, including taxis (n=4), flights (n=3), a train (n=1), and a cruise ship (n=1).

During the first 11 weeks of the COVID-19 outbreak outside mainland China, cases were detected in half of all countries and locations globally, with an acceleration in case detection during weeks 9-11 of the outbreak. Although most countries and locations in the WHO European, Eastern 11, 12 almost all cases in this analysis occurred among adults (aged ≥18 years), with only 3% occurring among children (aged <18 years). Death related to COVID-19 was associated with older age, although the role of underlying conditions could not be assessed, and data were too sparse to stratify cases and deaths by country to account for variation in population age structure. Although there were many clusters of house hold transmission among early cases, clusters in occupational or community settings tended to be larger, supporting a possible role for physical distancing to slow the spread of SARS-CoV-2. SARS-CoV-2 is the first coronavirus outbreak to be characterised as a pandemic by WHO. Compared with the coronaviruses that caused SARS (SARS-CoV) and MERS (MERS-CoV), SARS-CoV-2 spread more rapidly in the early weeks of the global outbreak. For example, by approximately 11 weeks after SARS-CoV and MERS-CoV were detected outside China and Saudi Arabia, respectively, 27 countries had reported 6500 cases of SARS and three countries had reported nine cases of MERS. 13, 14 By comparison, at the comparable timepoint in the SARS-CoV-2 outbreak, 99 countries had collectively reported more than 100 000 cases of COVID-19. The factors contributing to the more rapid spread of SARS-CoV-2 compared with other novel coronaviruses are unclear. Estimates of the basic reproductive number (R 0 ) of SARS-CoV-2 have varied widely, but a pooled estimate using data from multiple models (R 0 2·9, 95% CI 2·1-4·5) 15 was similar to the estimated R 0 of SARS-CoV (consensus estimate, R 0 of 3) 16 but lower than some estimates for MERS-CoV (estimated range, R 0 of 2-7). 17, 18 However, some case series and preliminary transmission modelling studies suggest a larger role for asymptomatic or presymptomatic transmission for SARS-CoV-2 compared with SARS-CoV, 19 and perhaps MERS-CoV. 20 Moreover, although many early affected countries implemented quarantine, contact tracing, and isolation efforts to contain the spread of SARS-CoV-2, variation in these efforts and early case underdetection 6,21 might have facilitated the early spread of SARS-CoV-2. Case detection in the WHO African region occurred late in the prepandemic period, possibly reflecting differences in global case finding, surveillance, Data are n (%) or mean (range). A cluster was defined as two or more cases with an epidemiological link. *Total cases from among 1200 cases with information about age or sex that were associated with clusters and transmission settings. An additional 137 cases associated with the 101 clusters shown here were identified from among cases without information about age or sex and are included in cluster size counts. †Case narrative stated that cases in the cluster had close contact but did not provide additional information about transmission setting. Some clusters involving close contact might have occurred in the other transmission settings listed in this table. 24, 25 Multiple factors could have contributed to the early predominance of adults among confirmed cases, including early transmission linked to travel and occupational exposures, and that case finding and testing efforts focused on individuals meeting early case definitions for COVID-19, which included a limited range of symptoms, focused on travel exposures, or both of these. Multiple early reports have suggested that asymptomatic or mild illness might be more common among children. 26, 27 Studies that use prospective syste matic case identification, testing, and data collection are needed to estimate the prevalence of infection in children, to ascertain how prevalence could evolve with time and with varying community mitigation measures (eg, school closures) and to characterise the full spectrum of SARS-CoV-2 infection and outcomes among children.

Transmission settings of early COVID-19 clusters could provide insights into potential drivers of community transmission and can inform ongoing community mitigation efforts. In our analysis, SARS-CoV-2 infection was transmitted in various settings. Multiple large clusters in our analysis, and large outbreaks reported elsewhere, 28 have been associated with transmission in faith-based settings, highlighting the need to partner with faith-based organisations when designing and implementing community mitigation efforts. Health-care-associated clusters were also identified from early case reports, highlighting the need for early recognition of suspected cases, strict infection prevention and control practices, and health-care worker surveillance for illness detection. Consistent with data from other respiratory disease outbreaks including SARS, MERS, and previous influenza pandemics, [29] [30] [31] household transmission of SARS-CoV-2 was common. In the early period of the outbreak, household intro duction occurred through adult household members rather than through children, who have been identified as important drivers of transmission in previous influenza pandemics. 32 House hold transmission patterns might change as more widespread community transmission occurs and com mu nity mitigation strategies (eg, school closures) change over time.

Our analysis was possible because of publicly available data shared by national ministries of health early in the SARS-CoV-2 outbreak. However, several limitations should be considered when interpreting findings. First, the analysis of case characteristics was limited to 4% of global confirmed cases that had publicly available information at least about a case's age or sex. Public reporting of case characteristics was inversely related to case reporting burden, as shown by the fact that more than three-quarters of cases without information about age or sex were from the three countries with the highest case counts (ie, Iran, Italy, and South Korea). Second, publicly available data varied in completeness, which could have resulted in underascertainment of some case characteristics, and typically did not include information about clinical complications. Thus, frequencies of selected variables (eg, health-care worker, pregnancy status, and death) and clusters should be interpreted as minimum estimates. Further, the proportion of patients who were reported to have died should not be interpreted as a case-fatality ratio, because early reporting of deaths could be biased because of delays from symptom onset to death, increased probability of detection of more severe cases, or both of these. 33 Although the extent of ascertainment bias in our analysis is not known, the age and sex distribution of cases is similar to reports of early confirmed cases from mainland China and else where. 11, 12, 34, 35 Third, the first confirmed case from each country might not have been the first true case of infection in some countries, since early global case detection efforts varied substantially. Finally, almost all cases in our analysis were reported from middle-income and high-income countries from Asia and Europe, driven primarily by late detection in other regions and in part by differences in the level of detail reported for confirmed cases from countries in other regions. The epidemiology of COVID-19 in low-income countries and in Africa could differ, as reported in previous influenza pandemics, 22 and data representative of these settings will be needed to assess the full global effect of the COVID-19 pandemic.

To validate findings from our analysis, we compared case characteristics from our dataset with those reported up to March 9, 2020, from the Open COVID-19 Data Working Group dataset, 36 an aggregation of data from official government sources, peer-reviewed scientific papers, and media websites. Among 3039 cases (9% of 31 765 cases) with available data for age or sex through the Open COVID-19 dataset (as of June 18, 2020), the country income level, age, and sex distribution of cases was generally consistent with findings from our analysis, except that the proportion of cases among adults aged 50 years or older was higher in our analysis (appendix p 5). Fewer deaths (n=24) were reported through the Open COVID-19 dataset, and data for special populations or clusters were not available. The proportion of cases with information about age or sex could be higher in the Open COVID-19 Data Working Group dataset compared with our dataset, because the Open COVID-19 dataset is continuously updated and includes data from unofficial sources (eg, media reports).

Much remains unknown about COVID-19, including how its epidemiology will evolve in the context of more widespread community transmission, the effect of community mitigation measures on spread, risk factors for severe disease, how risk factors and severe outcomes might vary between low-resource and high-resource settings, the effect of COVID-19 on vulnerable popu lations, and the economic and social effects of the virus. Additional studies with detailed epidemiological and clinical data, and ideally with systematic testing of suspected cases, including among special populations (eg, health-care workers, children, and pregnant women), could further our understanding of COVID-19 and inform preparedness and response measures for the current pandemic.

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FSD and PR led the analysis design, with inputs from all other authors. PR led the data collection process. FSD, PR, GJN, MD, JAF, AW, LCS, DC, AEB, CL, AP, CJ, PA, and NO obtained data for the analysis. FSD, JAF, and MD analysed the data. FSD wrote the first draft of the report. All authors contributed to data interpretation and revision of the report.

We declare no competing interests.

No funding was received for this analysis. The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the US Centers for Disease Control and Prevention.Editorial note: The Lancet Group takes a neutral position with respect to territorial claims in published text, figures, and tables.