Research

Efficiency of two-phase methods with focus on a planned population-based case-control study on air pollution and stroke

Anna Oudin^1*, Jonas Björk² and Ulf Strömberg¹

• * Corresponding author: Anna Oudin anna.oudin@med.lu.se

Author Affiliations

¹ Department of Occupational and Environmental Medicine, Lund University Hospital, Lund, Sweden

² Competence Centre for Clinical Research, Lund University Hospital, Lund, Sweden

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Environmental Health 2007, 6:34 doi:10.1186/1476-069X-6-34

Published: 7 November 2007

Abstract

Background

We plan to conduct a case-control study to investigate whether exposure to nitrogen dioxide (NO₂) increases the risk of stroke. In case-control studies, selective participation can lead to bias and loss of efficiency. A two-phase design can reduce bias and improve efficiency by combining information on the non-participating subjects with information from the participating subjects. In our planned study, we will have access to individual disease status and data on NO₂ exposure on group (area) level for a large population sample of Scania, southern Sweden. A smaller sub-sample will be selected to the second phase for individual-level assessment on exposure and covariables. In this paper, we simulate a case-control study based on our planned study. We develop a two-phase method for this study and compare the performance of our method with the performance of other two-phase methods.

Methods

A two-phase case-control study was simulated with a varying number of first- and second-phase subjects. Estimation methods: Method 1: Effect estimation with second-phase data only. Method 2: Effect estimation by adjusting the first-phase estimate with the difference between the adjusted and unadjusted second-phase estimate. The first-phase estimate is based on individual disease status and residential address for all study subjects that are linked to register data on NO₂-exposure for each geographical area. Method 3: Effect estimation by using the expectation-maximization (EM) algorithm without taking area-level register data on exposure into account. Method 4: Effect estimation by using the EM algorithm and incorporating group-level register data on NO₂-exposure.

Results

The simulated scenarios were such that, unbiased or marginally biased (< 7%) odds ratio (OR) estimates were obtained with all methods. The efficiencies of method 4, are generally higher than those of methods 1 and 2. The standard errors in method 4 decreased further when the case/control ratio is above one in the second phase. For all methods, the standard errors do not become substantially reduced when the number of first-phase controls is increased.

Conclusion

In the setting described here, method 4 had the best performance in order to improve efficiency, while adjusting for varying participation rates across areas.