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Optimising the case-crossover design for use in shared exposure settings

Published online by Cambridge University Press:  04 May 2020

T. Braeye*
Affiliation:
Department of Public Health and Surveillance, Sciensano, Brussels, Belgium Interuniversity Institute for Biostatistics and Statistical Bioinformatics, Data Science Institute, Hasselt University, Hasselt, Belgium
N. Hens
Affiliation:
Interuniversity Institute for Biostatistics and Statistical Bioinformatics, Data Science Institute, Hasselt University, Hasselt, Belgium Centre for Health Economics Research & Modelling Infectious Diseases (CHERMID), Vaccine & Infectious Disease Institute, University of Antwerp, Antwerp, Belgium
*
Author for correspondence: T. Braeye, E-mail: Toon.Braeye@sciensano.be
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Abstract

With a case-crossover design, a case's exposure during a risk period is compared to the case's exposures at referent periods. The selection of referents for this self-controlled design is determined by the referent selection strategy (RSS). Previous research mainly focused on systematic bias associated with the RSS. We additionally focused on how RSS determines the number of referents per risk, sensitivity to overdispersion and time-varying confounding.

We illustrated the consequences of different RSS using a simulation study informed by data on meteorological variables and Legionnaires’ disease. By randomising the events and exposure time series, we explored statistical power associated with time-stratified and fixed bidirectional RSS and their susceptibility to systematic bias and confounding bias. In addition, we investigated how a high number of events on the same date (e.g. outbreaks) affected coefficient estimation. As illustrated by our work, referent selection alone can be insufficient to control for a time-varying confounding bias. In contrast to systematic bias, confounding bias can be hard to detect. We studied potential solutions: varying the model parameters and link-function, outlier-removal and aggregating the input-data over smaller areas. Our simulation study offers a framework for researchers looking to detect and to avoid bias in case-crossover studies.

Information

Type
Original Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press
Figure 0

Fig. 1. Graphical representation of the events and exposures time series in the different simulation scenarios (green = temperature, blue = number of cases (Ncases), dotted line = random, full line = unaltered).

Figure 1

Fig. 2. Overview of the different referent selection strategies.

Figure 2

Table 1. Overview of the different models. The name refers to the referent selection and the model used for fitting the data after referent selection

Figure 3

Fig. 3. Scenario ‘random events, unaltered exposures’. Boxplots of the coefficient estimates per exposure (relative humidity (A), temperature (B), wind speed (C)) and per RSS (AD = adjacent days, AY = adjacent years, SM = strata month-weekday, SY = strata day-of-the-year). Aggregation on (1) national (2) provincial level.

Figure 4

Fig. 4. Scenario ‘random events, unaltered exposures’. The proportion of significant coefficients over the nominal individual significance level by RSS (AD = adjacent days, AY = adjacent years, SM = strata month-weekday, SY = strata day-of-the-year). Aggregation on (1) national (2) provincial level.

Figure 5

Fig. 5. Scenario ‘unaltered events, random exposures’. (1) Boxplots of the coefficient estimates per exposure (relative humidity (A), temperature (B), wind speed (C)) and per RSS (AD = adjacent days, AY = adjacent years, SM = strata month-weekday, SY = strata day-of-the-year, SM.cp = strata month-weekday quasi-Poisson, SY.cp = strata day-of-the-year quasi-Poisson). Aggregation on (1) national, (2) national no-outliers, (3) provincial, (4) provincial no-outliers level.

Figure 6

Fig. 6. Scenario ‘unaltered events, random exposures’. The proportion of significant coefficients over the nominal individual significance level by RSS (AD = adjacent days, AY = adjacent years, SM = strata month-weekday, SY = strata day-of-the-year, SM.cp = strata month-weekday quasi-Poisson, SY.cp = strata day-of-the-year quasi-Poisson). (1A) National, (1B) national no-outliers, (1C) provincial (1D) provincial no-outliers.

Figure 7

Fig. 7. Scenario ‘event probability modelled by exposure values’. (A&B) Boxplots of the coefficient estimates by RSS. (C & D) The proportion of significant coefficients over the nominal individual significance level by RSS. (A & C) National. (B&D) Provincial. (AD = adjacent days, AY = adjacent years, SM = strata month-weekday, SY = strata day-of-the-year, SM.m.cp = strata month-weekday quasi-Poisson model with an additional variable for seasonality, SY.m.cp = strata day-of-the-year quasi-Poisson model with additional time-varying variable).

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