%0 Journal Article %1 Devine1998 %A Devine, O J %A Smith, J M %D 1998 %J Statistics in medicine %K Adolescent AgeFactors Child CohortStudies EpidemiologicStudies Humans IodineRadioisotopes IodineRadioisotopes:adverseeffects LikelihoodFunctions Models Neoplasms Radiation-Induced Radiation-Induced:epidemiology Radiation-Induced:etiology RadiationDosage RiskFactors SampleSize SelectionBias Statistical ThyroidNeoplasms ThyroidNeoplasms:epidemiology ThyroidNeoplasms:etiology %N 12 %P 1375-89 %T Estimating sample size for epidemiologic studies: the impact of ignoring exposure measurement uncertainty. %U http://www.ncbi.nlm.nih.gov/pubmed/9682326 %V 17 %X Sample size requirements for epidemiologic studies are usually determined on the basis of the desired level of statistical power. Suppose, however, that one is planning a study in which the participants' true exposure levels are unobservable. Instead, the analysis will be based on an imprecise surrogate measure that differs from true exposure by some non-negligible amount of measurement error. Sample size estimates for tests of association between the surrogate exposure measure and the outcome of interest may be misleading if they are based solely on the anticipated characteristics of the distribution of surrogate measures in the study population. We examine the accuracy of sample size estimates for cohort studies in which a continuous surrogate exposure measure is subject to either classical or Berkson measurement error. In particular, we evaluate the consequences of not adjusting the sample size estimation procedure for tests based on imprecise exposure measurements to account for anticipated differences between the distributions of the true exposure and the surrogate measure in the study population. As expected, failure to adjust for classical measurement error can lead to underestimation of the required sample size. Disregard of Berkson measurement error, however, can result in sample size estimates that exceed the actual number of participants required for tests of association between the outcome and the surrogate exposure measure. We illustrate this Berkson error effect by estimating sample size for a hypothetical cohort study that examines an association between childhood exposure to radioiodine and the development of thyroid neoplasms.

@article{Devine1998, abstract = {Sample size requirements for epidemiologic studies are usually determined on the basis of the desired level of statistical power. Suppose, however, that one is planning a study in which the participants' true exposure levels are unobservable. Instead, the analysis will be based on an imprecise surrogate measure that differs from true exposure by some non-negligible amount of measurement error. Sample size estimates for tests of association between the surrogate exposure measure and the outcome of interest may be misleading if they are based solely on the anticipated characteristics of the distribution of surrogate measures in the study population. We examine the accuracy of sample size estimates for cohort studies in which a continuous surrogate exposure measure is subject to either classical or Berkson measurement error. In particular, we evaluate the consequences of not adjusting the sample size estimation procedure for tests based on imprecise exposure measurements to account for anticipated differences between the distributions of the true exposure and the surrogate measure in the study population. As expected, failure to adjust for classical measurement error can lead to underestimation of the required sample size. Disregard of Berkson measurement error, however, can result in sample size estimates that exceed the actual number of participants required for tests of association between the outcome and the surrogate exposure measure. We illustrate this Berkson error effect by estimating sample size for a hypothetical cohort study that examines an association between childhood exposure to radioiodine and the development of thyroid neoplasms.}, added-at = {2023-02-03T11:44:35.000+0100}, author = {Devine, O J and Smith, J M}, biburl = {https://www.bibsonomy.org/bibtex/2fef98041b838e24c426a834959020b11/jepcastel}, interhash = {79ae040e232416c28f33d411fa48cb37}, intrahash = {fef98041b838e24c426a834959020b11}, issn = {0277-6715}, journal = {Statistics in medicine}, keywords = {Adolescent AgeFactors Child CohortStudies EpidemiologicStudies Humans IodineRadioisotopes IodineRadioisotopes:adverseeffects LikelihoodFunctions Models Neoplasms Radiation-Induced Radiation-Induced:epidemiology Radiation-Induced:etiology RadiationDosage RiskFactors SampleSize SelectionBias Statistical ThyroidNeoplasms ThyroidNeoplasms:epidemiology ThyroidNeoplasms:etiology}, month = {6}, note = 2463, number = 12, pages = {1375-89}, pmid = {9682326}, timestamp = {2023-02-03T11:44:35.000+0100}, title = {Estimating sample size for epidemiologic studies: the impact of ignoring exposure measurement uncertainty.}, url = {http://www.ncbi.nlm.nih.gov/pubmed/9682326}, volume = 17, year = 1998 }