Estimating Absolute and Relative Case Fatality Ratios from Infectious Disease Surveillance Data
Identifieur interne : 001E93 ( Main/Exploration ); précédent : 001E92; suivant : 001E94Estimating Absolute and Relative Case Fatality Ratios from Infectious Disease Surveillance Data
Auteurs : Nicholas G. Reich [États-Unis] ; Justin Lessler [États-Unis] ; Derek A. T. Cummings [États-Unis] ; Ron Brookmeyer [États-Unis]Source :
- Biometrics [ 0006-341X ] ; 2012-06.
English descriptors
- Teeft :
- Accurate estimates, Algorithm, American journal, Annual report, Average estimate, Binomial distribution, Case counts, Case fatality, Case fatality data, Case fatality ratio, Certain conditions, Cfrs, Coarsedatatools package, Complete fatality, Conditional binomial model, Constant proportion, Constant proportion models, Covariate, Covariate group, Covariate independence, Covariate level, Data analysis, Dead case, Dead cases, Death counts, Discrete survival distributions, Discrete weibull, Disease surveillance systems, Estimator, Fatal cases, Fatality, Geographical location, Inclusion criteria, Infectious disease, Infectious diseases, Iter, Johns hopkins university, Linear regression line, Main text, Maryland state board, Maximum survival distribution, Nonfatal cases, Nonlinear functions, Optimal allocation, Outbreak, Pandemic, Point estimates, Poisson formulation, Rate scenarios, Reference county, Relative case fatality ratios, Relative cfrs, Respiratory syndrome, Scenario, Severe outcomes, Simulation, Simulation results, Simulation study, Socioeconomic status, Standard errors, State board, Step function, Surveillance system, Surveillance systems, Survival distribution, Survival probabilities, Survival time, Survival times, Symmetric survival distribution, Symptom onset, Time units, Total number, True survival distribution, Typology, Unobserved data, Washington counties, White population, Wicomico counties, Wide range.
Abstract
Summary Knowing which populations are most at risk for severe outcomes from an emerging infectious disease is crucial in deciding the optimal allocation of resources during an outbreak response. The case fatality ratio (CFR) is the fraction of cases that die after contracting a disease. The relative CFR is the factor by which the case fatality in one group is greater or less than that in a second group. Incomplete reporting of the number of infected individuals, both recovered and dead, can lead to biased estimates of the CFR. We define conditions under which the CFR and the relative CFR are identifiable. Furthermore, we propose an estimator for the relative CFR that controls for time‐varying reporting rates. We generalize our methods to account for elapsed time between infection and death. To demonstrate the new methodology, we use data from the 1918 influenza pandemic to estimate relative CFRs between counties in Maryland. A simulation study evaluates the performance of the methods in outbreak scenarios. An R software package makes the methods and data presented here freely available. Our work highlights the limitations and challenges associated with estimating absolute and relative CFRs in practice. However, in certain situations, the methods presented here can help identify vulnerable subpopulations early in an outbreak of an emerging pathogen such as pandemic influenza.
Url:
DOI: 10.1111/j.1541-0420.2011.01709.x
Affiliations:
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The case fatality ratio (CFR) is the fraction of cases that die after contracting a disease. The relative CFR is the factor by which the case fatality in one group is greater or less than that in a second group. Incomplete reporting of the number of infected individuals, both recovered and dead, can lead to biased estimates of the CFR. We define conditions under which the CFR and the relative CFR are identifiable. Furthermore, we propose an estimator for the relative CFR that controls for time‐varying reporting rates. We generalize our methods to account for elapsed time between infection and death. To demonstrate the new methodology, we use data from the 1918 influenza pandemic to estimate relative CFRs between counties in Maryland. A simulation study evaluates the performance of the methods in outbreak scenarios. An R software package makes the methods and data presented here freely available. Our work highlights the limitations and challenges associated with estimating absolute and relative CFRs in practice. However, in certain situations, the methods presented here can help identify vulnerable subpopulations early in an outbreak of an emerging pathogen such as pandemic influenza.</div></front></TEI><affiliations><list><country><li>États-Unis</li></country><region><li>Massachusetts</li></region><settlement><li>Amherst (Massachusetts)</li></settlement><orgName><li>Université du Massachusetts</li></orgName></list><tree><country name="États-Unis"><region name="Massachusetts"><name sortKey="Reich, Nicholas G" sort="Reich, Nicholas G" uniqKey="Reich N" first="Nicholas G." last="Reich">Nicholas G. Reich</name></region><name sortKey="Brookmeyer, Ron" sort="Brookmeyer, Ron" uniqKey="Brookmeyer R" first="Ron" last="Brookmeyer">Ron Brookmeyer</name><name sortKey="Cummings, Derek A T" sort="Cummings, Derek A T" uniqKey="Cummings D" first="Derek A. T." last="Cummings">Derek A. T. Cummings</name><name sortKey="Lessler, Justin" sort="Lessler, Justin" uniqKey="Lessler J" first="Justin" last="Lessler">Justin Lessler</name><name sortKey="Reich, Nicholas G" sort="Reich, Nicholas G" uniqKey="Reich N" first="Nicholas G." last="Reich">Nicholas G. Reich</name><name sortKey="Reich, Nicholas G" sort="Reich, Nicholas G" uniqKey="Reich N" first="Nicholas G." last="Reich">Nicholas G. Reich</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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