A Cautionary Note About Estimating Effects of Secondary Exposures in Cohort Studies

Overview

Journal Am J Epidemiol

Publisher Oxford University Press

Specialty Public Health

Date 2015 Jan 16

PMID 25589243

Citations 6

Authors

K A Ahrens

S R Cole

D Westreich

R W Platt

E F Schisterman

Affiliations

Soon will be listed here.

Abstract

Cohort studies are often enriched for a primary exposure of interest to improve cost-effectiveness, which presents analytical challenges not commonly discussed in epidemiology. In this paper, we use causal diagrams to represent exposure-enriched cohort studies, illustrate a scenario wherein the risk ratio for the effect of a secondary exposure on an outcome is biased, and propose an analytical method for correcting for such bias. In our motivating example, maternal smoking (Z) is a cause of fetal growth restriction (X), which subsequently affects preterm birth (Y) (i.e., Z → X → Y); strong positive associations exist between both Z, X and X, Y; and enrichment for X increases its prevalence from 10% to 50%. In the X-enriched cohort, unadjusted and X-adjusted analyses lead to bias in the risk ratio for the total effect of Z on Y. After application of inverse probability weights, the bias is corrected, with a small loss of efficiency in comparison with a same-sized study without X-enrichment. With increasing interest in conducting secondary analyses to reduce research costs, caution should be employed when analyzing studies that have already been enriched, intentionally or unintentionally, for a primary exposure of interest. Causal diagrams can help identify scenarios in which secondary analyses may be biased. Inverse probability weights can be used to remove the bias.

Citing Articles

Serum PFAS and Urinary Phthalate Biomarker Concentrations and Bone Mineral Density in 12-19 Year Olds: 2011-2016 NHANES.

Carwile J, Seshasayee S, Ahrens K, Hauser R, Driban J, Rosen C J Clin Endocrinol Metab. 2022; 107(8):e3343-e3352.

PMID: 35511700 PMC: 9282360. DOI: 10.1210/clinem/dgac228.

Dietary correlates of urinary phthalate metabolite concentrations in 6-19 Year old children and adolescents.

Carwile J, Seshasayee S, Ahrens K, Hauser R, Chavarro J, Fleisch A Environ Res. 2021; 204(Pt B):112083.

PMID: 34582800 PMC: 8678286. DOI: 10.1016/j.envres.2021.112083.

Modification of the Associations Between Duration of Oral Contraceptive Use and Ovarian, Endometrial, Breast, and Colorectal Cancers.

Michels K, Pfeiffer R, Brinton L, Trabert B JAMA Oncol. 2018; 4(4):516-521.

PMID: 29346467 PMC: 5885214. DOI: 10.1001/jamaoncol.2017.4942.

Opportunities for Epidemiologists in Implementation Science: A Primer.

Neta G, Brownson R, Chambers D Am J Epidemiol. 2017; 187(5):899-910.

PMID: 29036569 PMC: 6279080. DOI: 10.1093/aje/kwx323.

Epidemiologic Approaches for Studying Assisted Reproductive Technologies: Design, Methods, Analysis and Interpretation.

Messerlian C, Gaskins A Curr Epidemiol Rep. 2017; 4(2):124-132.

PMID: 29034142 PMC: 5636007. DOI: 10.1007/s40471-017-0105-0.

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