key: cord-0892219-9i1m3u6r authors: Maani, Amal Al; Wahaibi, Adil Al; Nazer, Weam; Al-Zadjali, Najla; Rawahi, Jokha Al; Al-Beloushi, Iman; Al-Sooti, Jabir; Alqayoudhi, Abdullah; Al-Abri, Seif title: The utilization of HCWs surveillance as an early warning of COVID-19 epidemic activity in the community date: 2021-12-23 journal: J Infect DOI: 10.1016/j.jinf.2021.12.024 sha: 4a13caedc8b2f8640c04ebc5f5a66f38acd2e5d0 doc_id: 892219 cord_uid: 9i1m3u6r nan In a recent issue of this journal, Brown and colleagues reported data relating to pointprevalence PCR surveillance of COVID-19 infection in health care workers (HCWs) in England (1) . Their snapshot study results showed higher prevalence of SARS-CoV-2 infection in HCWs compared to the general population. This resembles earlier data that portrayed health care settings as high-risk areas in that they combine community and health care sources (2) . In this letter, we report the utility of COVID-19 surveillance in HCWs for indicating community spread and hospitalization due to disease. The ministry of health in the Sultanate of Oman developed Tarassud, an electronic surveillance system, for reporting and follow-up of PCR-confirmed COVID-19 cases in the population (characteristics, admission, mortality) and a national database for disease surveillance in HCWs, specifically. The first imported cases of COVID-19 in Oman were diagnosed on 24 February 2020 in two citizens traveling back from Iran (3). Implementing public health and social measures, particularly mobility restrictions at different stages of the pandemic, was effective in breaking the chain of disease transmission. However, lifting the measures was associated with resurgences resulting in multiple waves noticed in the country's disease epidemiological curve (4) . In this retrospective cross-sectional study, we describe the characteristics of HCWs with PCR-confirmed COVID-19 during the first wave of the pandemic in Oman (February to July 2020) and the relation between the epidemiological curve of the disease in HCWs and that of community and hospitalization stratified by different phases of epidemic activities in the community. The study combines data from the national database of COVID-19 in HCWs and Tarassud for the disease in community and admissions. The data from the first wave was selected as it represented an immunologically naive population from natural infection and occurred before the vaccination campaign began for both HCWs and the community. Analyses was done using Pearson correlation between daily numbers of infected HCWs with community cases and admission for the same period. The admission and community data were stratified according to percentage from peak activity into three strata, '<33% of peak activity of community cases', '33-66% of peak activity community cases' and '>66% of peak activity community cases'. A total of 136,792 PCR-confirmed cases of COVID-19 were diagnosed during the study period where 1721 (1.26%) of them were HCWs and 2660 (1.2%) were admitted. For the infected HCWs, 58% were female, 78% non-national, and 49% were from the age category (30-39).The infection was highest among nurses (48%) followed by physicians (17%) and other HCWs constituted remaining (35%). Regarding the working areas, 30% of the infected HCWs were working in inpatient, 26% were outpatient, and only 7% of the infected HCWs were working exclusively in COVID units. The remaining were in non-clinical areas (20%), supporting clinical services (12%), and in the emergency department (5%). Forty-two percent of infections were labeled as community acquired, 19% as health care associated infections, and 39% remained with no identified source. Most of the infections in HCWs were mild (97%), 6 required admissions to intensive care and one HCW unfortunately died. (Supplementary Table 1) The epidemiological curve of the community confirmed cases, the admission curve, and the confirmed HCWs cases curve is shown in Figure 1 . It shows that the cases within the community and HCWs started and peaked around the same time; however, the peak of hospitalization came later. A high positive correlation was found between daily infected HCWs and community cases (0.86, P-value <0.005) and a moderate positive correlation was noticed between daily infected HCWs and admissions (0.62, P-value <0.005); this was all noted during the <33% of peak activity. We did not capture any significant correlation between daily infected HCWs and admissions or community cases during the >33% of peak activity of disease ( Figure 2 ). This study shows that monitoring the cases of infected HCWs can be used as an early warning system for community spread and for COVID-19 admission surge. HCWs infection with SARS-CoV-2 focused interventions in minimizing health care exposure risk while the exposure in the community was proven to be more significant in driving the epidemiology of COVID-19 in health care (5, 6) . The vulnerabilities identified in the response to the epidemics and pandemics resulted in straining health care facilities and amplifying the spread of disease from the facility to the communities and vice versa (7). Our analysis has proven that reporting and monitoring COVID-19 in HCWs is a useful tool in predicting the spread in the community during the early phases of the disease waves, especially in settings where community testing is limited. This can be utilized to help health care facilities prepare for potential surges in COVID-19 cases and admissions. Identifying SARS-CoV-2 infected HCWs early in the disease course will prevent spread to co-workers and patients contributing significantly to prevention and control measures within the facility (8) . Thus, enhancing disease surveillance in HCWs thereby utilizing the ready access of this category of population to testing facilities can serve the purpose of preventing nosocomial infection and early preparedness for disease surge. This study's results may not be applicable in populations with heterogeneous immunity to the virus from natural exposure or immunization unless the emerging new variants might escape the natural or vaccination immunity. The ongoing COVID-19 pandemic is not expected to abate soon and the investment in building robust surveillance systems and infection prevention and control will stand as safeguard for transmission in health care and an extension of the disease spread in the community (9,10). Amal Al Maani: Supervision of investigation, analysis, writingreview & editing. Adil Al Wahaibi: investigation, formal analysis, data curation, writingreview & editing. Snapshot PCR surveillance for SARS-CoV-2 in hospital staff in England Seroprevalence of SARS-CoV-2 antibodies and associated factors in healthcare workers: a systematic review and meta-analysis The impact of mobility restriction strategies in the control of the COVID-19 pandemic: modelling the relation between COVID-19 health and community mobility data COVID-19 in health-care workers in three hospitals in the south of the Netherlands: a cross-sectional study The role of supporting services in driving SARS-CoV-2 transmission within healthcare settings: A multicenter seroprevalence study US hospital capacity managers' experiences and concerns regarding preparedness for seasonal influenza and influenza-like illness Epidemiology of COVID-19 in a long-term care facility in King County, Washington Dancing with COVID-19 after the hammer is lifted: enhancing healthcare worker surveillance COVID-19 in healthcare workers and serving safe healthcare during the pandemic Epidemiologic curves of community COVID-19 cases, admissions, and infected HCWs