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Lifetime Data Analysis

Erschienen in:

11.07.2020

Subtleties in the interpretation of hazard contrasts

verfasst von: Torben Martinussen, Stijn Vansteelandt, Per Kragh Andersen

Erschienen in: Lifetime Data Analysis | Ausgabe 4/2020

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Abstract

The hazard ratio is one of the most commonly reported measures of treatment effect in randomised trials, yet the source of much misinterpretation. This point was made clear by Hernán (Epidemiology (Cambridge, Mass) 21(1):13–15, 2010) in a commentary, which emphasised that the hazard ratio contrasts populations of treated and untreated individuals who survived a given period of time, populations that will typically fail to be comparable—even in a randomised trial—as a result of different pressures or intensities acting on different populations. The commentary has been very influential, but also a source of surprise and confusion. In this note, we aim to provide more insight into the subtle interpretation of hazard ratios and differences, by investigating in particular what can be learned about a treatment effect from the hazard ratio becoming 1 (or the hazard difference 0) after a certain period of time. We further define a hazard ratio that has a causal interpretation and study its relationship to the Cox hazard ratio, and we also define a causal hazard difference. These quantities are of theoretical interest only, however, since they rely on assumptions that cannot be empirically evaluated. Throughout, we will focus on the analysis of randomised experiments.

Vorheriger Artikel Statistical analysis of clustered mixed recurrent-event data with application to a cancer survivor study

Nächster Artikel Measuring the temporal prognostic utility of a baseline risk score

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Aalen OO, Cook RJ, Røysland K (2015) Does cox analysis of a randomized survival study yield a causal treatment effect? Lifetime Data Anal 21(4):579–93MathSciNetCrossRef

Bartolucci F, Grilli L (2011) Modeling partial compliance through copulas in a principal stratification framework. J Am Stat Assoc 106(494):469–479MathSciNetCrossRef

Collett D (2015) Modelling survival data in medical research. CRC Press, Boca RatonCrossRef

Frangakis CE, Rubin DB (2002) Principal stratification in causal inference. Biometrics 58(1):21–9MathSciNetCrossRef

Hernán M (2010) The hazards of hazard ratios. Epidemiology (Cambridge, Mass) 21(1):13–15MathSciNetCrossRef

Lederle FA, Kyriakides TC, Stroupe KT, Freischlag JA, Padberg FT, Matsumura JS, Huo Z, Johnson GR (2019) Open versus endovascular repair of abdominal aortic aneurysm. N Engl J Med 380(22):2126–2135 PMID: 31141634CrossRef

Lin DY, Wei LJ, Ying Z (1993) Checking the Cox model with cumulative sums of martingale-based residuals. Biometrika 80:557–572MathSciNetCrossRef

Martinussen T, Scheike TH (2006) Dynamic regression models for survival data. Springer, New YorkMATH

Martinussen T, Vansteelandt S (2013) On collapsibility and confounding bias in cox and aalen regression models. Lifetime Data Anal 19(3):279–96MathSciNetCrossRef

Nelsen RB (2006) An introduction to copulas. Springer, New YorkMATH

Oakes D (1989) Bivariate survival models induced by frailties. J Am Stat Assoc 84(406):487–493MathSciNetCrossRef

Primrose JN, Fox RP, Palmer DH, Malik HZ, Prasad R, Mirza D, Anthony A, Corrie P, Falk S, Finch-Jones M, Wasan H, Ross P, Wall L, Wadsley J, Evans JTR, Stocken D, Praseedom R, Ma YT, Davidson B, Neoptolemos JP, Iveson T, Raftery J, Zhu S, Cunningham D, Garden OJ, Stubbs C, Valle JW, Bridgewater J, Primrose J, Fox R, Morement H, Chan O, Rees C, Ma Y, Hickish T, Falk S, Finch-Jones M, Pope I, Corrie P, Crosby T, Sothi S, Sharkland K, Adamson D, Wall L, Evans J, Dent J, Hombaiah U, Iwuji C, Anthoney A, Bridgewater J, Cunningham D, Gillmore R, Ross P, Slater S, Wasan H, Waters J, Valle J, Palmer D, Malik H, Neoptolemos J, Faluyi O, Sumpter K, Dernedde U, Maduhusudan S, Cogill G, Archer C, Iveson T, Wadsley J, Darby S, Peterson M, Mukhtar A, Thorpe J, Bateman A, Tsang D, Cummins S, Nolan L, Beaumont E, Prasad R, Mirza D, Stocken D, Praseedom R, Davidson B, Raftery J, Zhu S, Garden J, Stubbs C, Coxon F (2019) Capecitabine compared with observation in resected biliary tract cancer (bilcap): a randomised, controlled, multicentre, phase 3 study. Lancet Oncol 20(5):663–673CrossRef

Rubin DB (2000) Causal inference without counterfactuals: comment. J Am Stat Assoc 95(450):435–438

Stablein DM, Koutrouvelis IA (1985) A two-sample test sensitive to crossing hazards in uncensored and singly censored data. Biometrics 41(3):643–52MathSciNetCrossRef

Uno H, Claggett B, Tian L, Inoue E, Gallo P, Miyata T, Schrag D, Takeuchi M, Uyama Y, Zhao L, Skali H, Solomon S, Jacobus S, Hughes M, Packer M, Wei L-J (2014) Moving beyond the hazard ratio in quantifying the between-group difference in survival analysis. J Clin Oncol 32(22):2380–5CrossRef

Vansteelandt S, Martinussen T, Tchetgen ET (2014) On adjustment for auxiliary covariates in additive hazard models for the analysis of randomized experiments. Biometrika 101(1):237–244MathSciNetCrossRef

White IR, Royston P (2009) Imputing missing covariate values for the cox model. Stat Med 28(15):1982–98MathSciNetCrossRef

Zhao L, Claggett B, Tian L, Uno H, Pfeffer MA, Solomon SD, Trippa L, Wei LJ (2016) On the restricted mean survival time curve in survival analysis. Biometrics 72(1):215–21MathSciNetCrossRef

Titel: Subtleties in the interpretation of hazard contrasts
verfasst von: Torben Martinussen
Stijn Vansteelandt
Per Kragh Andersen
Publikationsdatum: 11.07.2020
Verlag: Springer US
Erschienen in: Lifetime Data Analysis / Ausgabe 4/2020
Print ISSN: 1380-7870
Elektronische ISSN: 1572-9249
DOI: https://doi.org/10.1007/s10985-020-09501-5

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