key: cord-1004879-of8xngjw authors: Dahlgren, F. Scott; Rossen, Lauren M.; Fry, Alicia M.; Reed, Carrie title: Severity of the COVID‐19 pandemic assessed with all‐cause mortality in the United States during 2020 date: 2022-01-19 journal: Influenza Other Respir Viruses DOI: 10.1111/irv.12923 sha: 3d1f8683012fe7c2eec19330e7d365f2fffb76e1 doc_id: 1004879 cord_uid: of8xngjw BACKGROUND: In the United States, infection with SARS‐CoV‐2 caused 380,000 reported deaths from March to December 2020. METHODS: We adapted the Moving Epidemic Method to all‐cause mortality data from the United States to assess the severity of the COVID‐19 pandemic across age groups and all 50 states. By comparing all‐cause mortality during the pandemic with intensity thresholds derived from recent, historical all‐cause mortality, we categorized each week from March to December 2020 as either low severity, moderate severity, high severity, or very high severity. RESULTS: Nationally for all ages combined, all‐cause mortality was in the very high severity category for 9 weeks. Among people 18 to 49 years of age, there were 29 weeks of consecutive very high severity mortality. Forty‐seven states, the District of Columbia, and New York City each experienced at least 1 week of very high severity mortality for all ages combined. CONCLUSIONS: These periods of very high severity of mortality during March through December 2020 are likely directly or indirectly attributable to the COVID‐19 pandemic. This method for standardized comparison of severity over time across different geographies and demographic groups provides valuable information to understand the impact of the COVID‐19 pandemic and to identify specific locations or subgroups for deeper investigations into differences in severity. In the United States, infection with SARS-CoV-2 caused 380,000 reported deaths from March to December 2020. 1 Reported deaths likely underestimate the true number of COVID-19 deaths for a variety of reasons. 2 To better reflect the mortality burden of the COVID-19 pandemic, various estimates of excess deaths have been made, where excess deaths are defined as the difference between the observed numbers of deaths in a specific time period and expected numbers of deaths in the same time period based on mortality during prior years. These analyses of all-cause mortality data found large relative increases in mortality during the pandemic among all age groups, 3 but particularly people 25 to 44 years of age. 4 In the United States and other temperate countries, overall mortality rates are generally highest during the winter months, with peak weekly mortality rates usually coinciding temporally with influenza virus activity. 5 Vega and colleagues developed the Moving Epidemic Method (MEM), a useful analytical tool to compare the severity of influenza seasons over time, across countries, and across age groups that may have different baseline levels of morbidity. 6, 7 The method sets standardized intensity thresholds based on the highest values of a surveillance indicator observed within recent, prior seasons. In this way, even though particular age groups or geographic areas have different baseline levels of mortality, the interpretations of the thresholds would be similar. We adapted the MEM to all-cause mortality data from the United States to assess the severity of the COVID-19 pandemic across age groups and states. Because case ascertainment, definitions, testing practices, care seeking behavior, and clinical behavior have all changed in response to the pandemic, 8-10 many of the available data sources with historical data for estimating severity, such as syndromic surveillance, 6 are complicated by such pandemic-influenced changes. Additionally, as SARS-COV-2 is novel, historical cause-specific data are not available for comparison as they would be for influenza. Recent reports have documented that COVID-19 was the third leading cause of death in 2020, accounting for more than two thirds of the increase in all-cause mortality. 4, [11] [12] [13] Overall death recording is unlikely to be affected by factors that have changed during the pandemic (e.g., changes in testing, case ascertainment, or care seeking behavior); these data may provide valuable information about the severity of the ongoing COVID-19 pandemic. The purpose of this study was to set intensity thresholds in all-cause death data from past years with the MEM and use those thresholds to describe the severity of the COVID-19 pandemic in the United States over time and by age and by geography. Because of population growth and aging, it is important to account for long-term trends in the numbers of deaths occurring in the United States. Because our methods relied on comparing recent data to historical data, we needed to adjust for any secular trends in allcause mortality. First, we truncated the original time series by removing weeks after September 28, 2019 to exclude both the 2019-2020 pneumonia and influenza season as well as the COVID-19 pandemic. We decomposed these historical data into three components using local regression (LOESS): (1) a seasonal pattern, (2) a secular trend, and (3) the residuals. 14 When added together, the three components of the decomposition are exactly the original data. Taken one at a F I G U R E 1 (A) A weekly time series of allcause mortality from January 6, 2013, through January 2, 2021. (B) The adjusted time series used to calculate the intensity thresholds (ITs), with the study period beginning at the vertical gray line on March 1, 2020. The difference between the two time series is the linear adjustment for secular trend time, the seasonal pattern is exactly the same each year; the secular trend slowly moves the seasonal pattern up and down; and the residuals are the unexplained variation in weekly mortality. Because the secular trend from this decomposition was defined only on the historical data, we needed to extrapolate the secular trend to the end of 2020. So, we fit a line to the secular trend from the decomposition using ordinary least squares and extrapolated this line to the end of the original time series. Next, we shifted this fitted line vertically such that its minimum was zero on the domain of the original time series to prevent taking the logarithm of a negative value later in our analysis. Finally, we added this line to the original time series to adjust for the secular trend over the entire study period. We used the adjusted time series for the severity assessment. We adapted methods from Vega and colleagues to calculate intensity thresholds, a part of their MEM. 6, 7 Because mortality in the United States usually is at its highest during the fall and winter respiratory virus season, we considered the historical data by season (October to September), rather than calendar year. We used the 2013-2014 through the 2018-2019 seasons and identified the 3 largest values of weekly all-cause deaths from each season. Then, we assumed these values followed a log-normal distribution. We calculated three intensity thresholds corresponding to the 50th, 95th, and 99.5th percentiles of this distribution: the median, 1.6 standard deviations above the median, and 2.6 standard deviations above the median. We denoted the intensity thresholds as IT500, IT950, and IT995. These three thresholds defined the four severity categories: "low severity," "moderate severity," "high severity," and "very high severity." So, the peak weekly mortality has a 50% a priori probability of being low severity, 45% of being moderate severity, 4.5% of being high severity, and 0.5% of being very high severity. We used the intensity thresholds to assign severity of each week from week 10 through week 53 (March 1, 2020, through January 2, 2021) to one of the four severity categories. Compared with the original MEM, we used fewer peak weeks from each season and higher quantiles to F I G U R E 2 A plot of severity by state and by week from March 1, 2020, to January 2, 2021, assessed using weekly all-cause mortality define our ITs, resulting in universally higher ITs than the original MEM while preserving the original, relative spacing of ITs. 6, 7 These changes reflect the unusually high severity of the pandemic and allow for distinguishing relatively unusually high severity in the setting of the pandemic. We repeated this analysis for the data stratified on age group and stratified on state of residence. Because data stratified on both age group and place of residence are often small and therefore redacted, we did not apply our methods to age groups within a jurisdiction. We used "R: a language and environment for statistical computing" for all computations. 15 We also used the R package "MMWRweek: convert dates to MMWR day, week and year" to manage data. 16 All-cause mortality during the COVID-19 pandemic was unusually high compared with recent, historical all-cause mortality. We attribute the very high severity of mortality during the study period to the COVID-19 pandemic, though not all of the increase in all-cause mortality may be directly attributable to infection with SARS-CoV-2; other causes may have been indirectly affected by the pandemic, including addiction-related deaths and motor-vehicle fatalities. [17] [18] [19] Cause-specific mortality data are not yet available by age and state, but in the future the MEM could be applied to specific categories of causes of death (e.g., respiratory, circulatory, injury, etc.) to observe which causes were more or less affected by the COVID-19 pandemic and among which age groups and states. This method is especially useful for comparing across geographies or age groups that have very different baseline levels of mortality. While weekly all-cause mortality was highest among adults at least 65 years of age ( Figure S1 -S4), when comparing age groups to their own historical peak mortality rates, we noted a lengthy period of sustained very high mortality among younger adults, 18-49 years of age, with 29 consecutive weeks of all-cause mortality in the very high severity level. As cause-specific mortality rates become available, further investigation of cause-specific mortality rates may help explain how this age group was impacted by the pandemic. During the COVID-19 pandemic, or future public health emergencies, this method flags potential trends that would benefit from further exploration. We also noted substantial geographic heterogeneity. The three periods of very high mortality across the states in the spring, summer, and fall/winter coincide generally with increases in reported COVID-19 cases and deaths nationally. 20 This method does have some limitations. While all-cause mortality among adults at least 50 years of age in the historical seasons had a strong seasonal pattern, mortality among children and adults 18 to 49 years of age did not. Because of the lack of seasonality, the highest mortality weeks may be spaced throughout the annual season instead of close together. However, the interpretation remains valid, in the sense that all-cause mortality during the study period was unlikely to be highly elevated for several weeks, much less for 29 consecutive weeks. Our results rely on extrapolation of the secular trend from March 2020 to December 2020, and interpretation of our results should be more qualitative as the study period progresses. For future use of the MEM to analyze all-cause mortality data, the inclusion of March to December 2020 in the historical data will increase both the mean and the variance of peak weekly mortality, resulting in ITs which are both higher and further spaced. Depending on the desired interpretation, adjustments to the MEM may be helpful when investigating particular counterfactuals and hypotheses. It is perhaps not surprising, given the high number of reported COVID-19 deaths, that unusually high mortality rates were observed in the United States during the COVID-19 pandemic. By setting standardized statistical thresholds in the mortality data, however, this method allows for easy comparison across age groups, geography, and over time, even when the baseline mortality rates differ, to identify the time periods, subpopulations, and places that experienced the greatest standardized increases in deaths as a result of the pandemic. Furthermore, because this analysis relies on all-cause mortality, a metric that is widely monitored and less likely affected by misclassification or reporting changes during the pandemic, similar comparisons could be made across countries if death registration data during 2020 and prior years were available. This method for standardized comparison of pandemic severity over time across different geographies and demographic groups provides valuable information to better understand the differential impact of the COVID-19 pandemic across locations or subgroups. Results can inform future investigations into the factors that may have contributed to differences in the severity of the pandemic across populations in terms of relative increases in all-cause mortality. 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Progress in Neuro-Psychopharmacology and Biological Psychiatry COVID-19 and substance use disorders: syndemic responses to a global pandemic Early provisional estimates of drug overdose, suicide, and transportationrelated deaths: Nowcasting methods to account for reporting lags. Vital Statistics Rapid Release SUPPORTING INFORMATION Additional supporting information may be found in the online version of the article at the publisher's website. How to cite this article: Dahlgren FS, Rossen LM, Fry AM, Reed C. Severity of the COVID-19 pandemic assessed with all-cause mortality in the United States during 2020 We thank the vital statistics jurisdictions for their continued efforts, without which our work would not be possible. We also thank members of the Council of State and Territorial Epidemiologists for approving our presentation of results at the state level.This research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors. Conceptualization; writing-review and editing. The authors have no conflict of interest to disclose. The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the Centers for Disease Control and Prevention. The peer review history for this article is available at https://publons. com/publon/10.1111/irv.12923. The data are not publicly available due to privacy or ethical restrictions. https://orcid.org/0000-0003-1790-2804