Improved survival modeling in cancer research using a reduced piecewise exponential approach. Academic Article

abstract

• Statistical models for survival data are typically nonparametric, for example, the Kaplan-Meier curve. Parametric survival modeling, such as exponential modeling, however, can reveal additional insights and be more efficient than nonparametric alternatives. A major constraint of the existing exponential models is the lack of flexibility due to distribution assumptions. A flexible and parsimonious piecewise exponential model is presented to best use the exponential models for arbitrary survival data. This model identifies shifts in the failure rate over time based on an exact likelihood ratio test, a backward elimination procedure, and an optional presumed order restriction on the hazard rate. Such modeling provides a descriptive tool in understanding the patient survival in addition to the Kaplan-Meier curve. This approach is compared with alternative survival models in simulation examples and illustrated in clinical studies.

authors

• Han, Gang

published proceedings

• Stat Med

altmetric score

• 16.5

author list (cited authors)

• Han, G., Schell, M. J., & Kim, J.

citation count

• 17

complete list of authors

• Han, Gang||Schell, Michael J||Kim, Jongphil

publication date

• January 2014

publisher

• Wiley  Publisher

published in

• Statistics in Medicine  Journal

keywords

• Clinical Trials As Topic
• Computer Simulation
• Exponential Survival
• Humans
• Likelihood Functions
• Median Survival
• Models, Statistical
• Neoplasms
• Nonsmall Cell Lung Cancer
• Survival Analysis

PubMed Central ID

• 23900779

Digital Object Identifier (DOI)

• 10.1002/sim.5915

start page

• 59

end page

• 73

volume

• 33

issue

• 1

URL

• http://dx.doi.org/10.1002/sim.5915