Marginal hazard ratio estimates in joint frailty models for heart failure trials

Biom J. 2019 Nov;61(6):1385-1401. doi: 10.1002/bimj.201800133. Epub 2019 Jun 17.

Abstract

This work is motivated by clinical trials in chronic heart failure disease, where treatment has effects both on morbidity (assessed as recurrent non-fatal hospitalisations) and on mortality (assessed as cardiovascular death, CV death). Recently, a joint frailty proportional hazards model has been proposed for these kind of efficacy outcomes to account for a potential association between the risk rates for hospital admissions and CV death. However, more often clinical trial results are presented by treatment effect estimates that have been derived from marginal proportional hazards models, that is, a Cox model for mortality and an Andersen-Gill model for recurrent hospitalisations. We show how these marginal hazard ratios and their estimates depend on the association between the risk processes, when these are actually linked by shared or dependent frailty terms. First we derive the marginal hazard ratios as a function of time. Then, applying least false parameter theory, we show that the marginal hazard ratio estimate for the hospitalisation rate depends on study duration and on parameters of the underlying joint frailty model. In particular, we identify parameters, for example the treatment effect on mortality, that determine if the marginal hazard ratio estimate for hospitalisations is smaller, equal or larger than the conditional one. How this affects rejection probabilities is further investigated in simulation studies. Our findings can be used to interpret marginal hazard ratio estimates in heart failure trials and are illustrated by the results of the CHARM-Preserved trial (where CHARM is the 'Candesartan in Heart failure Assessment of Reduction in Mortality and morbidity' programme).

Keywords: heart failure trials; joint frailty model; least false parameter; recurrent events; unexplained heterogeneity.

Publication types

  • Research Support, Non-U.S. Gov't

MeSH terms

  • Asymptomatic Diseases
  • Biometry / methods*
  • Clinical Trials as Topic*
  • Heart Failure / drug therapy*
  • Humans
  • Proportional Hazards Models*
  • Risk Assessment