Publication date: Feb 12, 2025
Survival models with cure fractions, known as long-term survival models, are widely used in epidemiology to account for both immune and susceptible patients regarding a failure event. In such studies, it is also necessary to estimate unobservable heterogeneity caused by unmeasured prognostic factors. Moreover, the hazard function may exhibit a non-monotonic shape, specifically, an unimodal hazard function. In this article, we propose a long-term survival model based on a defective version of the Dagum distribution, incorporating a power variance function frailty term to account for unobservable heterogeneity. This model accommodates survival data with cure fractions and non-monotonic hazard functions. The distribution is reparameterized in terms of the cure fraction, with covariates linked via a logit link, allowing for direct interpretation of covariate effects on the cure fraction-an uncommon feature in defective approaches. We present maximum likelihood estimation for model parameters, assess performance through Monte Carlo simulations, and illustrate the model’s applicability using two health-related datasets: severe COVID-19 in pregnant and postpartum women and patients with malignant skin neoplasms.
| Concepts | Keywords |
|---|---|
| Carlo | Cure fraction |
| Epidemiology | Dagum distribution |
| Heterogeneity | defective distribution |
| Pregnant | frailty term |
| Survival | long-term model |
| non-monotone hazard function |
Semantics
| Type | Source | Name |
|---|---|---|
| disease | MESH | frailty |
| disease | MESH | COVID-19 |
| disease | MESH | skin neoplasms |