Your search keyword '"Gregory L. Watson"' showing total 12 results

1. Associations between respiratory health and ozone and fine particulate matter during a wildfire event

Author

Colleen E. Reid, Ellen M. Considine, Gregory L. Watson, Donatello Telesca, Gabriele G. Pfister, and Michael Jerrett

Subjects

Environmental sciences, GE1-350

Abstract

Wildfires have been increasing in frequency in the western United States (US) with the 2017 and 2018 fire seasons experiencing some of the worst wildfires in terms of suppression costs and air pollution that the western US has seen. Although growing evidence suggests respiratory exacerbations from elevated fine particulate matter (PM2.5) during wildfires, significantly less is known about the impacts on human health of ozone (O3) that may also be increased due to wildfires. Using machine learning, we created daily surface concentration maps for PM2.5 and O3 during an intense wildfire in California in 2008. We then linked these daily exposures to counts of respiratory hospitalizations and emergency department visits at the ZIP code level. We calculated relative risks of respiratory health outcomes using Poisson generalized estimating equations models for each exposure in separate and mutually-adjusted models, additionally adjusted for pertinent covariates. During the active fire periods, PM2.5 was significantly associated with exacerbations of asthma and chronic obstructive pulmonary disease (COPD) and these effects remained after controlling for O3. Effect estimates of O3 during the fire period were non-significant for respiratory hospitalizations but were significant for ED visits for asthma (RR = 1.05 and 95% CI = (1.022, 1.078) for a 10 ppb increase in O3). In mutually-adjusted models, the significant findings for PM2.5 remained whereas the associations with O3 were confounded. Adjusted for O3, the RR for asthma ED visits associated with a 10 μg/m3 increase in PM2.5 was 1.112 and 95% CI = (1.087, 1.138). The significant findings for PM2.5 but not for O3 in mutually-adjusted models is likely due to the fact that PM2.5 levels during these fires exceeded the 24-hour National Ambient Air Quality Standard (NAAQS) of 35 μg/m3 for 4976 ZIP-code days and reached levels up to 6.073 times the NAAQS, whereas our estimated O3 levels during the fire period only occasionally exceeded the NAAQS of 70 ppb with low exceedance levels. Future studies should continue to investigate the combined role of O3 and PM2.5 during wildfires to get a more comprehensive assessment of the cumulative burden on health from wildfire smoke. Keywords: Wildfires, Ozone, Particulate matter, Respiratory disease

Published

2019

2. Pseudo-likelihood based logistic regression for estimating COVID-19 infection and case fatality rates by gender, race, and age in California

Author

Di Xiong, Lu Zhang, Gregory L. Watson, Phillip Sundin, Teresa Bufford, Joseph A. Zoller, John Shamshoian, Marc A. Suchard, and Christina M. Ramirez

Subjects

COVID-19, Infection rate, Case fatality rate, California Health Interview Survey, Logistic regression, Infectious and parasitic diseases, RC109-216

Abstract

In emerging epidemics, early estimates of key epidemiological characteristics of the disease are critical for guiding public policy. In particular, identifying high-risk population subgroups aids policymakers and health officials in combating the epidemic. This has been challenging during the coronavirus disease 2019 (COVID-19) pandemic because governmental agencies typically release aggregate COVID-19 data as summary statistics of patient demographics. These data may identify disparities in COVID-19 outcomes between broad population subgroups, but do not provide comparisons between more granular population subgroups defined by combinations of multiple demographics.We introduce a method that helps to overcome the limitations of aggregated summary statistics and yields estimates of COVID-19 infection and case fatality rates — key quantities for guiding public policy related to the control and prevention of COVID-19 — for population subgroups across combinations of demographic characteristics. Our approach uses pseudo-likelihood based logistic regression to combine aggregate COVID-19 case and fatality data with population-level demographic survey data to estimate infection and case fatality rates for population subgroups across combinations of demographic characteristics.We illustrate our method on California COVID-19 data to estimate test-based infection and case fatality rates for population subgroups defined by gender, age, and race/ethnicity. Our analysis indicates that in California, males have higher test-based infection rates and test-based case fatality rates across age and race/ethnicity groups, with the gender gap widening with increasing age. Although elderly infected with COVID-19 are at an elevated risk of mortality, the test-based infection rates do not increase monotonically with age. The workforce population, especially, has a higher test-based infection rate than children, adolescents, and other elderly people in their 60–80. LatinX and African Americans have higher test-based infection rates than other race/ethnicity groups. The subgroups with the highest 5 test-based case fatality rates are all-male groups with race as African American, Asian, Multi-race, LatinX, and White, followed by African American females, indicating that African Americans are an especially vulnerable California subpopulation.

Published

2020

3. Machine Learning in Environmental Exposure Assessment

Author

Gregory L. Watson

Published

2022

4. Associations between respiratory health and ozone and fine particulate matter during a wildfire event

Author

Gabriele Pfister, Michael Jerrett, Colleen E. Reid, Gregory L. Watson, Donatello Telesca, and Ellen M. Considine

Subjects

Risk, 010504 meteorology & atmospheric sciences, Air pollution, 010501 environmental sciences, medicine.disease_cause, 01 natural sciences, California, Wildfires, Ozone, Air Pollution, Environmental health, medicine, Humans, Generalized estimating equation, lcsh:Environmental sciences, 0105 earth and related environmental sciences, General Environmental Science, Asthma, lcsh:GE1-350, Smoke, COPD, business.industry, Respiration, Respiratory disease, Emergency department, medicine.disease, Hospitalization, Relative risk, Particulate Matter, Seasons, Emergency Service, Hospital, business

Abstract

Wildfires have been increasing in frequency in the western United States (US) with the 2017 and 2018 fire seasons experiencing some of the worst wildfires in terms of suppression costs and air pollution that the western US has seen. Although growing evidence suggests respiratory exacerbations from elevated fine particulate matter (PM2.5) during wildfires, significantly less is known about the impacts on human health of ozone (O3) that may also be increased due to wildfires. Using machine learning, we created daily surface concentration maps for PM2.5 and O3 during an intense wildfire in California in 2008. We then linked these daily exposures to counts of respiratory hospitalizations and emergency department visits at the ZIP code level. We calculated relative risks of respiratory health outcomes using Poisson generalized estimating equations models for each exposure in separate and mutually-adjusted models, additionally adjusted for pertinent covariates. During the active fire periods, PM2.5 was significantly associated with exacerbations of asthma and chronic obstructive pulmonary disease (COPD) and these effects remained after controlling for O3. Effect estimates of O3 during the fire period were non-significant for respiratory hospitalizations but were significant for ED visits for asthma (RR = 1.05 and 95% CI = (1.022, 1.078) for a 10 ppb increase in O3). In mutually-adjusted models, the significant findings for PM2.5 remained whereas the associations with O3 were confounded. Adjusted for O3, the RR for asthma ED visits associated with a 10 μg/m3 increase in PM2.5 was 1.112 and 95% CI = (1.087, 1.138). The significant findings for PM2.5 but not for O3 in mutually-adjusted models is likely due to the fact that PM2.5 levels during these fires exceeded the 24-hour National Ambient Air Quality Standard (NAAQS) of 35 μg/m3 for 4976 ZIP-code days and reached levels up to 6.073 times the NAAQS, whereas our estimated O3 levels during the fire period only occasionally exceeded the NAAQS of 70 ppb with low exceedance levels. Future studies should continue to investigate the combined role of O3 and PM2.5 during wildfires to get a more comprehensive assessment of the cumulative burden on health from wildfire smoke. Keywords: Wildfires, Ozone, Particulate matter, Respiratory disease

Published

2019

5. Pandemic velocity: Forecasting COVID-19 in the US with a machine learning & Bayesian time series compartmental model

Author

Phillip Sundin, Marc A. Suchard, Joseph A. Zoller, Gregory L. Watson, Lu Zhang, Teresa Bufford, Di Xiong, John Shamshoian, Anne W. Rimoin, Christina M. Ramirez, and Pitzer, Virginia E

Subjects

0301 basic medicine, Viral Diseases, Computer science, Epidemiology, Interval (mathematics), Variation (game tree), Mathematical Sciences, Geographical locations, Machine Learning, Bayes' theorem, 0302 clinical medicine, Medical Conditions, Mathematical and Statistical Techniques, Models, Econometrics, Medicine and Health Sciences, 030212 general & internal medicine, Biology (General), Virus Testing, Ecology, Applied Mathematics, Simulation and Modeling, Statistics, Statistical, Biological Sciences, Random forest, Infectious Diseases, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Trajectory, Algorithms, Research Article, Computer and Information Sciences, QH301-705.5, Bioinformatics, Posterior probability, Bayesian probability, New York, Research and Analysis Methods, Infectious Disease Epidemiology, 03 medical and health sciences, Cellular and Molecular Neuroscience, Machine Learning Algorithms, Artificial Intelligence, Diagnostic Medicine, Information and Computing Sciences, Genetics, Humans, Time series, Statistical Methods, Molecular Biology, Pandemics, Ecology, Evolution, Behavior and Systematics, Models, Statistical, SARS-CoV-2, COVID-19, Computational Biology, Covid 19, Bayes Theorem, United States, 030104 developmental biology, North America, Generic health relevance, People and places, Mathematics, Forecasting

Abstract

Predictions of COVID-19 case growth and mortality are critical to the decisions of political leaders, businesses, and individuals grappling with the pandemic. This predictive task is challenging due to the novelty of the virus, limited data, and dynamic political and societal responses. We embed a Bayesian time series model and a random forest algorithm within an epidemiological compartmental model for empirically grounded COVID-19 predictions. The Bayesian case model fits a location-specific curve to the velocity (first derivative) of the log transformed cumulative case count, borrowing strength across geographic locations and incorporating prior information to obtain a posterior distribution for case trajectories. The compartmental model uses this distribution and predicts deaths using a random forest algorithm trained on COVID-19 data and population-level characteristics, yielding daily projections and interval estimates for cases and deaths in U.S. states. We evaluated the model by training it on progressively longer periods of the pandemic and computing its predictive accuracy over 21-day forecasts. The substantial variation in predicted trajectories and associated uncertainty between states is illustrated by comparing three unique locations: New York, Colorado, and West Virginia. The sophistication and accuracy of this COVID-19 model offer reliable predictions and uncertainty estimates for the current trajectory of the pandemic in the U.S. and provide a platform for future predictions as shifting political and societal responses alter its course., Author summary COVID-19 models can be roughly classified as mathematical models that simulate disease within a population, including epidemiological compartmental models, or statistical curve-fitting models that fit a function to observed data and extrapolate forward into the future. Bridging this divide, we combine the strengths of curve-fitting statistical models and the structure of epidemiological models, by embedding a Bayesian velocity model and a machine learning algorithm (random forest) into the framework of a compartmental model. Fusing these models together exploits the particular strengths of each to glean as much information as possible from the currently available data. We identify the velocity of log cumulative cases as an excellent target for modeling and extrapolating COVID-19 case trajectories. We empirically evaluate the predictive performance of the model and provide predicted trajectories with credible intervals for cumulative confirmed case count, active confirmed infections and COVID-19 deaths for each of the 50 U.S. states. Combining sophisticated data analytic methods with proven epidemiological models offers an empirically grounded strategy for making realistic predictions and quantifying their uncertainty. These predictions indicate substantial variation in the COVID-19 trajectories of U.S. states.

Published

2021

6. An evidence review of face masks against COVID-19

Author

Amy Price, Jeremy Howard, Gregory L. Watson, Zeynep Tufekci, Danny Hernandez, Zhiyuan Li, Reshama Shaikh, Christina E. Bax, Arne von Delft, Lei-Han Tang, Viola Tang, Helene-Mari van der Westhuizen, Lex Fridman, Larry F. Chu, Christina M. Ramirez, Anne W. Rimoin, Frederik Questier, Vladimir Zdimal, Austin Huang, Multidisciplinair Inst. Lerarenopleiding, Educational Science, EU-China Higher Education Research Center, Brussels research center for Innovation in Learning and Diversity, and Teacher Education

Subjects

masks, Coronavirus disease 2019 (COVID-19), Distancing, Population impact, Internet privacy, contact tracing, law.invention, 03 medical and health sciences, 0302 clinical medicine, law, Health care, Humans, 030212 general & internal medicine, COVID-19/epidemiology, 030304 developmental biology, 0303 health sciences, Multidisciplinary, business.industry, SARS-CoV-2, pandemic, Masks, COVID-19, Face masks, Transmission (mechanics), Good Health and Well Being, Narrative review, Contact Tracing, business, Contact tracing

Abstract

The science around the use of masks by the public to impede COVID-19 transmission is advancing rapidly. In this narrative review, we develop an analytical framework to examine mask usage, synthesizing the relevant literature to inform multiple areas: population impact, transmission characteristics, source control, wearer protection, sociological considerations, and implementation considerations. A primary route of transmission of COVID-19 is via respiratory particles, and it is known to be transmissible from presymptomatic, paucisymptomatic, and asymptomatic individuals. Reducing disease spread requires two things: limiting contacts of infected individuals via physical distancing and other measures and reducing the transmission probability per contact. The preponderance of evidence indicates that mask wearing reduces transmissibility per contact by reducing transmission of infected respiratory particles in both laboratory and clinical contexts. Public mask wearing is most effective at reducing spread of the virus when compliance is high. Given the current shortages of medical masks, we recommend the adoption of public cloth mask wearing, as an effective form of source control, in conjunction with existing hygiene, distancing, and contact tracing strategies. Because many respiratory particles become smaller due to evaporation, we recommend increasing focus on a previously overlooked aspect of mask usage: mask wearing by infectious people (“source control”) with benefits at the population level, rather than only mask wearing by susceptible people, such as health care workers, with focus on individual outcomes. We recommend that public officials and governments strongly encourage the use of widespread face masks in public, including the use of appropriate regulation.

Published

2021

7. Face Masks Against COVID-19: An Evidence Review

Author

Zhiyuan Li, Reshama Shaikh, Tang L-H., Danny Hernandez, Zeynep Tufekci, Lex Fridman, Christina M. Ramirez, Larry F. Chu, Vladimir Zdimal, Anne W. Rimoin, Viola Tang, Jeremy Howard, Frederik Questier, van der Westhuizen H-M., A von Delft, Christina E. Bax, Austin Huang, Gregory L. Watson, and Amy Price

Subjects

education.field_of_study, Coronavirus disease 2019 (COVID-19), business.industry, Distancing, allergology, Population, Internet privacy, law.invention, Intervention (law), general_medical_research, Transmission (mechanics), law, Pandemic, Economic impact analysis, education, business, Contact tracing

Abstract

The science around the use of masks by the general public to impede COVID-19 transmission is advancing rapidly. Policymakers need guidance on how masks should be used by the general population to combat the COVID-19 pandemic. In this narrative review, we develop an analytical framework to examine mask usage, considering and synthesizing the relevant literature to inform multiple areas: population impact; transmission characteristics; source control; PPE; sociological considerations; and implementation considerations. A primary route of transmission of COVID-19 is via respiratory droplets, and is known to be transmissible from presymptomatic and asymptomatic individuals. Reducing disease spread requires two things: first, limit contacts of infected individuals via physical distancing and other measures, and second, reduce the transmission probability per contact. The preponderance of evidence indicates that mask wearing reduces the transmissibility per contact by reducing transmission of infected droplets in both laboratory and clinical contexts. Public mask wearing is most effective at reducing spread of the virus when compliance is high. The decreased transmissibility could substantially reduce the death toll and economic impact while the cost of the intervention is low. Given the current shortages of medical masks we recommend the adoption of public cloth mask wearing, as an effective form of source control, in conjunction with existing hygiene, distancing, and contact tracing strategies. Because many respiratory droplets become smaller due to evaporation, we recommend increasing focus on a previously overlooked aspect of mask usage: mask-wearing by infectious people ("source control") with benefits at the population-level, rather than mask-wearing by susceptible people, such as health-care workers, with focus on individual outcomes. We recommend that public officials and governments strongly encourage the use of widespread face masks in public, including the use of appropriate regulation.

Published

2020

8. Pseudo-Likelihood Based Logistic Regression for Estimating COVID-19 Infection and Case Fatality Rates by Gender, Race, and Age in California

Author

Christina M. Ramirez, Phillip Sundin, Lu Zhang, Gregory L. Watson, Joseph A. Zoller, Di Xiong, Marc A. Suchard, John Shamshoian, and Teresa Bufford

Subjects

medicine.medical_specialty, education.field_of_study, business.industry, Population, Ethnic group, Logistic regression, medicine.disease, Acquired immunodeficiency syndrome (AIDS), Case fatality rate, Epidemiology, Pandemic, Risk of mortality, Medicine, business, education, Demography

Abstract

In emerging epidemics, early estimates of key epidemiological characteristics of the disease are critical for guiding public policy. In particular, identifying high risk population subgroups aids policymakers and health officials in combatting the epidemic. This has been challenging during the coronavirus disease 2019 (COVID-19) pandemic, because governmental agencies typically release aggregate COVID-19 data as marginal summary statistics of patient demographics. These data may identify disparities in COVID-19 outcomes between broad population subgroups, but do not provide comparisons between more granular population subgroups defined by combinations of multiple demographics.We introduce a method that overcomes the limitations of aggregated summary statistics and yields estimates of COVID-19 infection and case fatality rates — key quantities for guiding public policy related to the control and prevention of COVID-19 — for population subgroups across combinations of demographic characteristics. Our approach uses pseudo-likelihood based logistic regression to combine aggregate COVID-19 case and fatality data with population-level demographic survey data to estimate infection and case fatality rates for population subgroups across combinations of demographic characteristics.We illustrate our method on California COVID-19 data to estimate test-based infection and case fatality rates for population subgroups defined by gender, age, and race and ethnicity. Our analysis indicates that in California, males have higher test-based infection rates and test-based case fatality rates across age and race/ethnicity groups, with the gender gap widening with increasing age. Although elderly infected with COVID-19 are at an elevated risk of mortality, the test-based infection rates do not increase monotonically with age. LatinX and African Americans have higher test-based infection rates than other race/ethnicity groups. The subgroups with the highest 5 test-based case fatality rates are African American male, Multi-race male, Asian male, African American female, and American Indian or Alaska Native male, indicating that African Americans are an especially vulnerable California subpopulation.

Published

2020

9. Fusing a Bayesian case velocity model with random forest for predicting COVID-19 in the U.S

Author

Christina M. Ramirez, Phillip Sundin, Joseph A. Zoller, Di Xiong, Anne W. Rimoin, John Shamshoian, Teresa Bufford, Gregory L. Watson, Lu Zhang, and Marc A. Suchard

Subjects

Mixed model, education.field_of_study, Health management system, Mathematical model, business.industry, Computer science, media_common.quotation_subject, Bayesian probability, Population, Posterior probability, Distribution (economics), Statistical model, Interval (mathematics), Random forest, Econometrics, business, education, Sophistication, media_common

Abstract

Predictions of COVID-19 case growth and mortality are critical to the decisions of political leaders, businesses, and individuals grappling with the pandemic. This predictive task is challenging due to the novelty of the virus, limited data, and dynamic political and societal responses. We embed a Bayesian nonlinear mixed model and a random forest algorithm within an epidemiological compartmental model for empirically grounded COVID-19 predictions. The Bayesian case model fits a location-specific curve to the velocity (first derivative) of the transformed cumulative case count, borrowing strength across geographic locations and incorporating prior information to obtain a posterior distribution for case trajectory. The compartmental model uses this distribution and predicts deaths using a random forest algorithm trained on COVID-19 data and population-level characteristics, yielding daily projections and interval estimates for infections and deaths in U.S. states. We evaluate forecasting accuracy on a two-week holdout set, finding that the model predicts COVID-19 cases and deaths well, with a mean absolute scaled error of 0.40 for cases and 0.32 for deaths throughout the two-week evaluation period. The substantial variation in predicted trajectories and associated uncertainty between states is illustrated by comparing three unique locations: New York, Ohio, and Mississippi. The sophistication and accuracy of this COVID-19 model offer reliable predictions and uncertainty estimates for the current trajectory of the pandemic in the U.S. and provide a platform for future predictions as shifting political and societal responses alter its course. Author summary COVID-19 models can be roughly classified as mathematical models that simulate disease within a population, including epidemiological compartmental models, or statistical curve-fitting models that fit a function to observed data and extrapolate forward into the future. Bridging this divide, we combine the strengths of curve-fitting statistical models and the structure of epidemiological models, by embedding a Bayesian nonlinear mixed model for case velocity and a machine learning algorithm (random forest) into the framework of a compartmental model. Fusing these models together exploits the particular strengths of each to glean as much information as possible from the currently available data. We also identify the velocity of log cumulative cases as an excellent target for modeling and extrapolating COVID-19 case trajectories. We empirically evaluate the predictive performance of the model and provide predicted trajectories with credible intervals for cumulative confirmed case count, active confirmed infections and COVID-19 deaths for each of the 50 U.S. states. Combining sophisticated data analytic methods with proven epidemiological models offers an empirically grounded strategy for making realistic predictions and quantifying their uncertainty. These predictions indicate substantial variation in the COVID-19 trajectories of U.S. states.

Published

2020

10. Machine learning models accurately predict ozone exposure during wildfire events

Author

Gabriele Pfister, Michael Jerrett, Donatello Telesca, Gregory L. Watson, and Colleen E. Reid

Subjects

010504 meteorology & atmospheric sciences, Mean squared error, Health, Toxicology and Mutagenesis, 010501 environmental sciences, Toxicology, Machine learning, computer.software_genre, 01 natural sciences, California, Wildfires, Machine Learning, Ozone, Air Pollution, Covariate, Ozone exposure, 0105 earth and related environmental sciences, Mathematics, Air Pollutants, business.industry, Reproducibility of Results, General Medicine, Pollution, Random forest, Variable (computer science), Metric (mathematics), Artificial intelligence, Gradient boosting, business, computer, Predictive modelling, Algorithms, Environmental Monitoring

Abstract

Epidemiologists use prediction models to downscale (i.e., interpolate) air pollution exposure where monitoring data is insufficient. This study compares machine learning prediction models for ground-level ozone during wildfires, evaluating the predictive accuracy of ten algorithms on the daily 8-hour maximum average ozone during a 2008 wildfire event in northern California. Models were evaluated using a leave-one-location-out cross-validation (LOLO CV) procedure to account for the spatial and temporal dependence of the data and produce more realistic estimates of prediction error. LOLO CV avoids both the well-known overly optimistic bias of k-fold cross-validation on dependent data and the conservative bias of evaluating prediction error over a coarser spatial resolution via leave-k-locations-out CV. Gradient boosting was the most accurate of the ten machine learning algorithms with the lowest LOLO CV estimated root mean square error (0.228) and the highest LOLO CV R ˆ 2 (0.677). Random forest was the second best performing algorithm with an LOLO CV R ˆ 2 of 0.661. The LOLO CV estimates of predictive accuracy were less optimistic than 10-fold CV estimates for all ten models. The difference in estimated accuracy between the 10-fold CV and LOLO CV was greater for more flexible models like gradient boosting and random forest. The order of estimated model accuracy depended on the choice of evaluation metric, indicating that 10-fold CV and LOLO CV may select different models or sets of covariates as optimal, which calls into question the reliability of 10-fold CV for model (or variable) selection. These prediction models are designed for interpolating ozone exposure, and are not suited to inferring the effect of wildfires on ozone or extrapolating to predict ozone in other spatial or temporal domains. This is demonstrated by the inability of the best performing models to accurately predict ozone during 2007 southern California wildfires.

Published

2019

11. Pseudo-likelihood based logistic regression for estimating COVID-19 infection and case fatality rates by gender, race, and age in California

Author

Joseph A. Zoller, Gregory L. Watson, Di Xiong, Lu Zhang, Christina M. Ramirez, Phillip Sundin, Teresa Bufford, John Shamshoian, and Marc A. Suchard

Subjects

Male, Epidemiology, Ethnic group, Logistic regression, California, 0302 clinical medicine, Infection rate, Risk Factors, Case fatality rate, Pandemic, Ethnicity, Risk of mortality, Medicine, 030212 general & internal medicine, Child, Aged, 80 and over, Likelihood Functions, education.field_of_study, Age Factors, Middle Aged, California Health Interview Survey, Infectious Diseases, Female, Monte Carlo Method, Adult, medicine.medical_specialty, Adolescent, 030231 tropical medicine, Population, Microbiology, Article, lcsh:Infectious and parasitic diseases, 03 medical and health sciences, Sex Factors, Acquired immunodeficiency syndrome (AIDS), Virology, Humans, lcsh:RC109-216, education, Pandemics, Aged, SARS-CoV-2, business.industry, Racial Groups, Public Health, Environmental and Occupational Health, COVID-19, medicine.disease, Health Surveys, Logistic Models, Parasitology, business, Demography

Abstract

In emerging epidemics, early estimates of key epidemiological characteristics of the disease are critical for guiding public policy. In particular, identifying high-risk population subgroups aids policymakers and health officials in combating the epidemic. This has been challenging during the coronavirus disease 2019 (COVID-19) pandemic because governmental agencies typically release aggregate COVID-19 data as summary statistics of patient demographics. These data may identify disparities in COVID-19 outcomes between broad population subgroups, but do not provide comparisons between more granular population subgroups defined by combinations of multiple demographics. We introduce a method that helps to overcome the limitations of aggregated summary statistics and yields estimates of COVID-19 infection and case fatality rates - key quantities for guiding public policy related to the control and prevention of COVID-19 - for population subgroups across combinations of demographic characteristics. Our approach uses pseudo-likelihood based logistic regression to combine aggregate COVID-19 case and fatality data with population-level demographic survey data to estimate infection and case fatality rates for population subgroups across combinations of demographic characteristics. We illustrate our method on California COVID-19 data to estimate test-based infection and case fatality rates for population subgroups defined by gender, age, and race/ethnicity. Our analysis indicates that in California, males have higher test-based infection rates and test-based case fatality rates across age and race/ethnicity groups, with the gender gap widening with increasing age. Although elderly infected with COVID-19 are at an elevated risk of mortality, the test-based infection rates do not increase monotonically with age. The workforce population, especially, has a higher test-based infection rate than children, adolescents, and other elderly people in their 60-80. LatinX and African Americans have higher test-based infection rates than other race/ethnicity groups. The subgroups with the highest 5 test-based case fatality rates are all-male groups with race as African American, Asian, Multi-race, LatinX, and White, followed by African American females, indicating that African Americans are an especially vulnerable California subpopulation.

Published

2020

12. Pandemic velocity: Forecasting COVID-19 in the US with a machine learning & Bayesian time series compartmental model.

Author

Gregory L Watson, Di Xiong, Lu Zhang, Joseph A Zoller, John Shamshoian, Phillip Sundin, Teresa Bufford, Anne W Rimoin, Marc A Suchard, and Christina M Ramirez

Subjects

Biology (General), QH301-705.5

Abstract

Predictions of COVID-19 case growth and mortality are critical to the decisions of political leaders, businesses, and individuals grappling with the pandemic. This predictive task is challenging due to the novelty of the virus, limited data, and dynamic political and societal responses. We embed a Bayesian time series model and a random forest algorithm within an epidemiological compartmental model for empirically grounded COVID-19 predictions. The Bayesian case model fits a location-specific curve to the velocity (first derivative) of the log transformed cumulative case count, borrowing strength across geographic locations and incorporating prior information to obtain a posterior distribution for case trajectories. The compartmental model uses this distribution and predicts deaths using a random forest algorithm trained on COVID-19 data and population-level characteristics, yielding daily projections and interval estimates for cases and deaths in U.S. states. We evaluated the model by training it on progressively longer periods of the pandemic and computing its predictive accuracy over 21-day forecasts. The substantial variation in predicted trajectories and associated uncertainty between states is illustrated by comparing three unique locations: New York, Colorado, and West Virginia. The sophistication and accuracy of this COVID-19 model offer reliable predictions and uncertainty estimates for the current trajectory of the pandemic in the U.S. and provide a platform for future predictions as shifting political and societal responses alter its course.

Published

2021