Simulación de ensayos clínicos de deprescripción
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2025
Defense date
09/2025
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Abstract
Los ensayos clínicos aleatorizados sobre deprescripción son complejos de realizar por la heterogeneidad de las intervenciones, la inconsistencia en los resultados y la susceptibilidad al sesgo. Proponemos un marco basado en simulaciones para emular ensayos objetivo y evaluar los efectos de la deprescricpión. El enfoque integra tres componentes: (i) el diseño del ensayo objetivo, que define elegilibilidad, intervenciones, resultados y seguimiento según principios de inferencia causal; (ii) la generación de poblaciones sintéticas a partir de distribuciones multivariantes informadas por ensayos previos para preservar correlaciones empíricas; y (iii) la modelización del tiempo hasta el evento mediante modelos de supervivencia paramétricos en una estructura multi estado semi-Markov. Esto permite transiciones dinámicas entre deprescripción, eventos adversos y muerte.
La evaluación metodológica reveló dos conclusiones clave. Primero, es esencial especificar los riesgos particulares de cada resultado. Segundo, la fiabilidad inferencial depende del tamaño de la muestra: una especificación correcta proporciona estimaciones estables en cohortes pequeñas, mientras que una espacificación errónea en cohortes grandes provoca un sesgo amplificado y una pérdida de cobertura.
Este marco refuerza la inferencia causal basada en simulaciones y ofrece un enfoque reproducible y extensible para investigar deprescripción y otros contextos en los que los ensayos aleatorios no son viables.
Randomized deprescribing trials are challenging due to heterogeneous interventions, inconsistent outcome definitions, and vulnerability to bias. We propose a simulation-based framework for emulating target trials to evaluate the effects of deprescribing. The framework integrates three key elements: (i) the target trial design, wich specifies eligilibility, interventions, outcomes, and follow-up to replicate causal inference principles; (ii) generation of synthetic population data from multivariate distributions informed by previous clinical essays to preserve empirical correlations; and (iii) time-to-event modelling with covariate-adjusted parametric survival models embedded in a semi-Markov multistate structure. This enables dynamic transitions between discontinuation, adverse events, and death, with event risks adapting to prior history. The methodological evaluation revealed two key findings. Firstly, outcome-specific hazard specification is essential. Gompertz models were more closely aligned with stroke and bleeding, whereas Weibull models better represented mortality. Secondly, inferential reliability depended on sample size; correct specification yielded stable estimates in small cohorts, whereas misspecification in large cohorts resulted in amplified bias and loss of coverage. This framework strengthens simulation-based causal inference by combining target trial emulation with flexible hazard modelling. It provides a reproducible, extensible approach for deprescribing research and other contexts where randomized trials are infeasible.
Randomized deprescribing trials are challenging due to heterogeneous interventions, inconsistent outcome definitions, and vulnerability to bias. We propose a simulation-based framework for emulating target trials to evaluate the effects of deprescribing. The framework integrates three key elements: (i) the target trial design, wich specifies eligilibility, interventions, outcomes, and follow-up to replicate causal inference principles; (ii) generation of synthetic population data from multivariate distributions informed by previous clinical essays to preserve empirical correlations; and (iii) time-to-event modelling with covariate-adjusted parametric survival models embedded in a semi-Markov multistate structure. This enables dynamic transitions between discontinuation, adverse events, and death, with event risks adapting to prior history. The methodological evaluation revealed two key findings. Firstly, outcome-specific hazard specification is essential. Gompertz models were more closely aligned with stroke and bleeding, whereas Weibull models better represented mortality. Secondly, inferential reliability depended on sample size; correct specification yielded stable estimates in small cohorts, whereas misspecification in large cohorts resulted in amplified bias and loss of coverage. This framework strengthens simulation-based causal inference by combining target trial emulation with flexible hazard modelling. It provides a reproducible, extensible approach for deprescribing research and other contexts where randomized trials are infeasible.