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A Note on Modeling the Covariance Structure in Longitudinal Clinical Trials. Devan V. Mehrotra Merck Research Laboratories, Blue Bell, PA FDA/Industry Statistics Workshop September 18, 2003. Outline. Comparative clinical trial Typical questions of interest Standard analysis
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A Note on Modeling the Covariance Structure in Longitudinal Clinical Trials Devan V. Mehrotra Merck Research Laboratories, Blue Bell, PA FDA/Industry Statistics Workshop September 18, 2003
Outline • Comparative clinical trial • Typical questions of interest • Standard analysis • Simulation results • Concluding remarks
Longitudinal Clinical Trial • Subjects are randomized to receive either treatment A or B. (N = NA + NB) • Response is measured at baseline (time = 0) and at fixed post-baseline visits (time = 1, 2, … T). • Yijk = response for time i, trt. j, subject k ij = E(Yijk) Note: Due to randomization, 0A = 0B
Typical Questions of Interest • Is there a differential treatment effect? What is the magnitude of the difference? • Typical endpoints for comparing treatments 1) Response at last time point (L) 2) Average of all responses over time (A) 3) “Slope”, or linear component of the treatment x time interaction (S) • Our focus in this talk is on endpoint (1)
Typical Questions of Interest (continued) • Null Hypothesis: TA = TB Equivalent to (TA- 0A) = (TB- 0B) because 0A = 0B under randomization • Two common analyses - “Change from baseline” (L) - “ANCOVA”: baseline is a covariate (L*) Note: L and L* test the same hypothesis and estimate the same parameter.
Standard Analysis (REML) • Assumptions (1) Multivariate normality of residual vector (2) Correct specification of the variance- covariance matrix of the residual vector • For this talk, we assume (1) is ~ true and focus on potential departures from assumption (2)
Comments on the Covariance Structure PROC MIXED “BC” • Type=CS is implicit in classic linear model analyses of longitudinal data (split-plot, variance component ANOVA models with compound symmetry structure) • Box (1954), Huynh & Feldt (1970) etc., noted that classic analyses can provide incorrect inference if Type=CS assumption is violated • Greenhouse & Geisser (1959), Huynh & Feldt (1976) provided approximate alternative tests based on adjusted d.f. • Note: Finney (1990) refers to the classic mixed model ANOVA as a “dangerously wrong” method
Comments on the Covariance Structure (continued) PROC MIXED “AD” • Laird & Ware (1982), Jenrich & Schlucter (1986), etc. suggested using prior experience or the current data to select an appropriate covariance structure. PROC MIXED provides several choices, including CS, AR(1), Toeplitz, and UN. • Frison & Pocock (1992) looked at data from several trials, covering a variety of diseases and quantitative outcome measures. They reported “no major departure from the compound symmetry assumption” • Our alternative strategy: specify Type=CS but use Liang and Zeger’s (1996) “sandwich” estimator via the EMPIRICAL option as insulation against an incorrect covariance structure assumption.
Concluding Remarks • Incorrect specification of the covariance structure can result in Type I error rates that are far from the nominal level. Using the Liang and Zeger “sandwich” estimator via the EMPIRICAL option insulates us from an incorrect covariance structure assumption. • Using TYPE=CS with the EMPIRICAL option is an attractive default approach. It usually provides more power than using TYPE=UN, particularly for small trials.
Concluding Remarks (continued) • Analysis with baseline as a covariate usually provides notably more power than the corresponding “change from baseline” analysis. • The (not uncommon) naïve t-test approach (same as “complete case” approach) should be abandoned for longitudinal trials. It can result in a substantial loss of power, especially when there are missing values.
References • Box GEP (1954). Annals of Mathematical Statisitcs, 25, 484-498. • Finney, DJ (1990). Statistics in Medicine, 9, 639-644. • Frison L and Pocock SJ (1992). Statistics in Medicine, 11, 1685-1704. • Greenhouse SW and Geisser S (1959). Psychometrika, 24, 95-112. • Huynh H and Feldt LS (1970). JASA, 65, 1582-1589. • Huynh H (1976). Journal of Educational Statistics, 1, 69-82. • Jenrich RI and Schulchter MD (1986). Biometrics, 42, 805-820. • Laird N and Ware JH (1982). Biometrics, 38, 963-974. • Liang NM and Zeger SL (1986). Biometrika, 73, 13-22.