Correcting for the bias caused by exposure measurement error in epidemiological studies

Abstract Difficulty in obtaining the correct measurement for an individual's long-term exposure is a major challenge in epidemiological studies that investigate the association between exposures and health outcomes. Measurement error in an exposure biases the association between the exposure and a disease outcome. Usually an internal validation study is required to adjust for exposure measurement error; it is challenging if such a study is not available. We proposed a method (trivariate method) that adjusts for measurement error in three correlated exposures in the absence of internal validation study and illustrated the method using real data. We compared the results from the proposed method with those obtained using a method that ignores measurement error and a method that ignores correlations between the errors and true exposures (the univariate method). It was found that ignoring measurement error leads to bias and underestimates the standard error. It was also found that the magnitude of adjustment in the trivariate method is sensitive to the magnitude of measurement error, sign and correlation between the errors. We conclude that the proposed method can be used to adjust for bias in the outcome-exposure association in a case where three exposures are measured with correlated errors in the absence of an internal validation study. The method is useful in conducting a sensitivity analysis on the magnitude of measurement error and the sign of the error correlation.

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Quantifying the short-term effects of air pollution on health in the presence of exposure measurement error: a simulation study of multi-pollutant model results

Environmental Health ◽

10.1186/s12940-021-00757-4 ◽

2021 ◽

Vol 20 (1) ◽

Author(s):

Dimitris Evangelopoulos ◽

Klea Katsouyanni ◽

Joel Schwartz ◽

Heather Walton

Keyword(s):

Air Pollution ◽

Measurement Error ◽

Simulation Study ◽

Epidemiological Studies ◽

Effect Estimate ◽

Exposure Measurement ◽

Exposure Models ◽

Mortality Effect ◽

Exposure Measurement Error ◽

The Impact

Abstract Background Most epidemiological studies estimate associations without considering exposure measurement error. While some studies have estimated the impact of error in single-exposure models we aimed to quantify the effect of measurement error in multi-exposure models, specifically in time-series analysis of PM2.5, NO2, and mortality using simulations, under various plausible scenarios for exposure errors. Measurement error in multi-exposure models can lead to effect transfer where the effect estimate is overestimated for the pollutant estimated with more error to the one estimated with less error. This complicates interpretation of the independent effects of different pollutants and thus the relative importance of reducing their concentrations in air pollution policy. Methods Measurement error was defined as the difference between ambient concentrations and personal exposure from outdoor sources. Simulation inputs for error magnitude and variability were informed by the literature. Error-free exposures with their consequent health outcome and error-prone exposures of various error types (classical/Berkson) were generated. Bias was quantified as the relative difference in effect estimates of the error-free and error-prone exposures. Results Mortality effect estimates were generally underestimated with greater bias observed when low ratios of the true exposure variance over the error variance were assumed (27.4% underestimation for NO2). Higher ratios resulted in smaller, but still substantial bias (up to 19% for both pollutants). Effect transfer was observed indicating that less precise measurements for one pollutant (NO2) yield more bias, while the co-pollutant (PM2.5) associations were found closer to the true. Interestingly, the sum of single-pollutant model effect estimates was found closer to the summed true associations than those from multi-pollutant models, due to cancelling out of confounding and measurement error bias. Conclusions Our simulation study indicated an underestimation of true independent health effects of multiple exposures due to measurement error. Using error parameter information in future epidemiological studies should provide more accurate concentration-response functions.

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Relying on repeated biospecimens to reduce the effects of classical-type exposure measurement error in studies linking the exposome to health

Environmental Research ◽

10.1016/j.envres.2020.109492 ◽

2020 ◽

Vol 186 ◽

pp. 109492

Author(s):

Lydiane Agier ◽

Rémy Slama ◽

Xavier Basagaña

Keyword(s):

Measurement Error ◽

Classical Type ◽

Exposure Measurement ◽

Exposure Measurement Error

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The effect of exposure variance and exposure measurement error on study sample size: Implications for the design of epidemiologic studies

Journal of Clinical Epidemiology ◽

10.1016/0895-4356(94)90190-2 ◽

1994 ◽

Vol 47 (8) ◽

pp. 873-880 ◽

Cited By ~ 29

Author(s):

Emily White ◽

Lawrence H. Kushiz ◽

Margaret S. Pepe

Keyword(s):

Measurement Error ◽

Sample Size ◽

Epidemiologic Studies ◽

Exposure Measurement ◽

Exposure Measurement Error

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The Effect of Random Error in Exposure Measurement upon the Shape of the Exposure Response

Dose-Response ◽

10.2203/dose-response.003.04.002 ◽

2005 ◽

Vol 3 (4) ◽

pp. dose-response.0 ◽

Cited By ~ 18

Author(s):

Kenny S. Crump

Keyword(s):

Measurement Error ◽

Measurement Errors ◽

Epidemiological Data ◽

Epidemiological Studies ◽

Random Errors ◽

Exposure Measurement ◽

Considerable Uncertainty ◽

Exposure Response ◽

Log Normal ◽

Normally Distributed

Although statistical analyses of epidemiological data usually treat the exposure variable as being known without error, estimated exposures in epidemiological studies often involve considerable uncertainty. This paper investigates the theoretical effect of random errors in exposure measurement upon the observed shape of the exposure response. The model utilized assumes that true exposures are log-normally distributed, and multiplicative measurement errors are also log-normally distributed and independent of the true exposures. Under these conditions it is shown that whenever the true exposure response is proportional to exposure to a power r, the observed exposure response is proportional to exposure to a power K, where K < r. This implies that the observed exposure response exaggerates risk, and by arbitrarily large amounts, at sufficiently small exposures. It also follows that a truly linear exposure response will appear to be supra-linear—i.e., a linear function of exposure raised to the K-th power, where K is less than 1.0. These conclusions hold generally under the stated log-normal assumptions whenever there is any amount of measurement error, including, in particular, when the measurement error is unbiased either in the natural or log scales. Equations are provided that express the observed exposure response in terms of the parameters of the underlying log-normal distribution. A limited investigation suggests that these conclusions do not depend upon the log-normal assumptions, but hold more widely. Because of this problem, in addition to other problems in exposure measurement, shapes of exposure responses derived empirically from epidemiological data should be treated very cautiously. In particular, one should be cautious in concluding that the true exposure response is supra-linear on the basis of an observed supra-linear form.

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