Comparing Strategies for Modeling Competing Risks in Discrete-Event Simulations: A Simulation Study and Illustration in Colorectal Cancer

Background. Different strategies toward implementing competing risks in discrete-event simulation (DES) models are available. This study aims to provide recommendations regarding modeling approaches that can be defined based on these strategies by performing a quantitative comparison of alternative modeling approaches. Methods. Four modeling approaches were defined: 1) event-specific distribution (ESD), 2) event-specific probability and distribution (ESPD), 3) unimodal joint distribution and regression model (UDR), and 4) multimodal joint distribution and regression model (MDR). Each modeling approach was applied to uncensored individual patient data in a simulation study and a case study in colorectal cancer. Their performance was assessed in terms of relative event incidence difference, relative absolute event incidence difference, and relative entropy of time-to-event distributions. Differences in health economic outcomes were also illustrated for the case study. Results. In the simulation study, the ESPD and MDR approaches outperformed the ESD and UDR approaches, in terms of both event incidence differences and relative entropy. Disease pathway and data characteristics, such as the number of competing risks and overlap between competing time-to-event distributions, substantially affected the approaches’ performance. Although no considerable differences in health economic outcomes were observed, the case study showed that the ESPD approach was most sensitive to low event rates, which negatively affected performance. Conclusions. Based on overall performance, the recommended modeling approach for implementing competing risks in DES models is the MDR approach, which is defined according to the general strategy of selecting the time-to-event first and the corresponding event second. The ESPD approach is a less complex and equally performing alternative if sufficient observations are available for each competing event (i.e., the internal validity shows appropriate data representation).

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Comparing Modeling Approaches for Discrete Event Simulations With Competing Risks Based on Censored Individual Patient Data: A Simulation Study and Illustration in Colorectal Cancer

Value in Health ◽

10.1016/j.jval.2021.07.016 ◽

2021 ◽

Author(s):

Koen Degeling ◽

Maarten J. IJzerman ◽

Catharina G.M. Groothuis-Oudshoorn ◽

Mira D. Franken ◽

Miriam Koopman ◽

...

Keyword(s):

Colorectal Cancer ◽

Competing Risks ◽

Simulation Study ◽

Individual Patient Data ◽

Discrete Event ◽

Patient Data ◽

Discrete Event Simulations ◽

Modeling Approaches ◽

Event Simulations

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Dynamic clinical prediction models for discrete time‐to‐event data with competing risks—A case study on the OUTCOMEREA database

Biometrical Journal ◽

10.1002/bimj.201700259 ◽

2018 ◽

Vol 61 (3) ◽

pp. 514-534 ◽

Cited By ~ 2

Author(s):

Rachel Heyard ◽

Jean‐François Timsit ◽

Wafa Ibn Essaied ◽

Leonhard Held ◽

Keyword(s):

Competing Risks ◽

Discrete Time ◽

Prediction Models ◽

Event Data ◽

Clinical Prediction ◽

Time To Event ◽

Clinical Prediction Models ◽

Time To Event Data

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How to Address Uncertainty in Health Economic Discrete-Event Simulation Models: An Illustration for Chronic Obstructive Pulmonary Disease

Medical Decision Making ◽

10.1177/0272989x20932145 ◽

2020 ◽

Vol 40 (5) ◽

pp. 619-632

Author(s):

Isaac Corro Ramos ◽

Martine Hoogendoorn ◽

Maureen P. M. H. Rutten-van Mölken

Keyword(s):

Chronic Obstructive Pulmonary Disease ◽

Health Economic ◽

Pulmonary Disease ◽

Discrete Event Simulation ◽

Discrete Event ◽

Chronic Obstructive ◽

Obstructive Pulmonary Disease ◽

Modeling Uncertainty ◽

Event Simulation

Background. Evaluation of personalized treatment options requires health economic models that include multiple patient characteristics. Patient-level discrete-event simulation (DES) models are deemed appropriate because of their ability to simulate a variety of characteristics and treatment pathways. However, DES models are scarce in the literature, and details about their methods are often missing. Methods. We describe 4 challenges associated with modeling heterogeneity and structural, stochastic, and parameter uncertainty that can be encountered during the development of DES models. We explain why these are important and how to correctly implement them. To illustrate the impact of the modeling choices discussed, we use (results of) a model for chronic obstructive pulmonary disease (COPD) as a case study. Results. The results from the case study showed that, under a correct implementation of the uncertainty in the model, a hypothetical intervention can be deemed as cost-effective. The consequences of incorrect modeling uncertainty included an increase in the incremental cost-effectiveness ratio ranging from 50% to almost a factor of 14, an extended life expectancy of approximately 1.4 years, and an enormously increased uncertainty around the model outcomes. Thus, modeling uncertainty incorrectly can have substantial implications for decision making. Conclusions. This article provides guidance on the implementation of uncertainty in DES models and improves the transparency of reporting uncertainty methods. The COPD case study illustrates the issues described in the article and helps understanding them better. The model R code shows how the uncertainty was implemented. For readers not familiar with R, the model’s pseudo-code can be used to understand how the model works. By doing this, we can help other developers, who are likely to face similar challenges to those described here.

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