A bounded hazard ratio Cox model for the effect of time to treatment on mortality

Abstract

In resource-limited or time-sensitive care settings, there is interest in assessing the impact of time to treatment (TTT) on mortality. Traditional Cox proportional hazards models, which specify the effect of TTT as an unrestricted term in the log hazard ratio, can produce counterintuitive results where the survival probability may not decrease monotonically with longer delays. Moreover, hazard ratios from such models quantify the effect of TTT conditional on surviving until treatment, rather than the effect of delayed treatment at baseline. We propose a class of bounded hazard ratio (BHR) Cox models that constrain the hazard ratio for TTT to attenuate towards the null with increasing treatment delay, such that hazard for death after treatment cannot exceed the hazard without treatment. Estimation can be performed using direct optimization of the partial log-likelihood or with an iterative linearized estimation procedure for large sample sizes. From BHR models, the estimated hazard ratio curve describes how treatment benefit diminishes with delay. Additionally, we propose a survival probability difference that provides an absolute measure for comparing survival under different treatment delays. We evaluate model performance in simulations and apply the method to examine treatment delays for colon cancer with data from the National Cancer Database.

Keywords

Time-to-event time-to-treatment survival semi-competing risks proportional hazards

Get full access to this article

View all access options for this article.

References

Amri

Bordeianou

Sylla

, et al.

Treatment delay in surgically-treated colon cancer: does it affect outcomes?

Ann Surg Oncol 2014; 21: 3909–3916.

Kaltenmeier

Shen

Medich

, et al. Time to surgery and colon cancer survival in the united states. Ann Surg 2021; 274: 1025–1031.

Band

Gaieski

Hylton

, et al. Arriving by emergency medical services improves time to treatment endpoints for patients with severe sepsis or septic shock. Acad Emerg Med 2011; 18: 934–940.

Suresh

Dixon

Patel

, et al. The epidemiology and outcomes of prolonged trauma care (epic) study: methodology of a prospective multicenter observational study in the western cape of south africa. Scand J Trauma Resusc Emerg Med 2022; 30: 55.

Meier-Kriesche

Port

Ojo

, et al. Effect of waiting time on renal transplant outcome. Kidney Int 2000; 58: 1311–1317.

Cone

Marchese

Paciotti

, et al. Assessment of time-to-treatment initiation and survival in a cohort of patients with common cancers. JAMA network open 2020; 3: e2030072.

Hartman

Sun

Devasia

, et al. Integrated survival estimates for cancer treatment delay among adults with cancer during the covid-19 pandemic. JAMA Oncol 2020; 6: 1881–1889.

Epstein

Muñoz

. A bivariate parametric model for survival and intermediate event times. Stat Med 1996; 15: 1171–1185.

Kalbfleisch

Prentice

. The statistical analysis of failure time data. Hoboken, NJ: J. Wiley, 2002.

10.

Andersen

Gill

. Cox’s regression model for counting processes: a large sample study. Ann Stat 1982; 10: 1100–1120.

11.

Van Houwelingen

Putter

. Dynamic prediction in clinical survival analysis. Boca Raton, FL: CRC Press, 2012.

12.

Meira-Machado

de Uña-Álvarez

Cadarso-Suárez

, et al. Multi-state models for the analysis of time-to-event data. Stat Methods Med Res 2009; 18: 195–222.

13.

Valeri

Proust-Lima

Fan

, et al. A multistate approach for the study of interventions on an intermediate time-to-event in health disparities research. Stat Methods Med Res 2023; 32: 1445–1460.

14.

Agarwal

Moshier

, et al. Immortal time bias in observational studies of time-to-event outcomes: assessing effects of postmastectomy radiation therapy using the national cancer database. Cancer Control 2018; 25: 1073274818789355.

15.

Jones

Fowler

. Immortal time bias in observational studies of time-to-event outcomes. J Crit Care 2016; 36: 195–199.

16.

Karim

Gustafson

Petkau

, et al. Comparison of statistical approaches for dealing with immortal time bias in drug effectiveness studies. Am J Epidemiol 2016; 184: 325–335.

17.

Hanna

King

Thibodeau

, et al. Mortality due to cancer treatment delay: systematic review and meta-analysis. bmj 2020; 371: m4087.

18.

Khorana

Tullio

Elson

, et al. Time to initial cancer treatment in the united states and association with survival over time: an observational study. PLoS ONE 2019; 14: e0213209.

19.

De Luca

Suryapranata

Ottervanger

, et al. Time delay to treatment and mortality in primary angioplasty for acute myocardial infarction. Circulation 2004; 109: 1223–1225.

20.

Kumar

Roberts

Wood

, et al. Duration of hypotension before initiation of effective antimicrobial therapy is the critical determinant of survival in human septic shock. Crit Care Med 2006; 34: 1589–1596.

21.

Chung

. Nonparametric estimation of proportional hazards with monotone baseline hazard and covariate effect. Stat Biosci 2024; 16: 787–800.

22.

Chung

Ivanova

Hudgens

, et al. Partial likelihood estimation of isotonic proportional hazards models. Biometrika 2018; 105: 133–148.

23.

Dunson

Herring

. Bayesian inferences in the cox model for order-restricted hypotheses. Biometrics 2003; 59: 916–923.

24.

Gelfand

Mallick

. Bayesian analysis of proportional hazards models built from monotone functions. Biometrics 1995; 51: 843–852.

25.

Le-Rademacher

Therneau

. The utility of multistate models: a flexible framework for time-to-event data. Curr Epidemiol Rep 2022; 9: 183–189.

26.

Therneau

. A Package for Survival Analysis in R. 2022. https://CRAN.R-project.org/package=survival. R package version 3.4-0.

27.

Self

Liang

. Asymptotic properties of maximum likelihood estimators and likelihood ratio tests under nonstandard conditions. J Am Stat Assoc 1987; 82: 605–610.

28.

Rice

Johnson

Juarez-Colunga

, et al. Application of gap time analysis with flexible hazards to pulmonary exacerbations in the epic observational study. Biomet J 2022; 64: 1075–1089.

29.

Franssen

Strous

Bongers

, et al. The association between treatment interval and survival in patients with colon or rectal cancer: a systematic review. World J Surg 2021; 45: 2924–2937.

30.

Ang

Lee

Chia

, et al. Time-to-treatment initiation and its effect on all-cause mortality: insights from the surveillance, epidemiology, and end results database. World J Oncol 2025; 16: 286.

31.

Bagaria

Heckman

Diehl

, et al. Delay to colectomy and survival for patients diagnosed with colon cancer. J Invest Surg 2019; 32: 350–357.

32.

Grass

Behm

Duchalais

, et al. Impact of delay to surgery on survival in stage i–iii colon cancer. Eur J Surg Oncol 2020; 46: 455–461.

33.

Kucejko

Holleran

Stein

, et al. How soon should patients with colon cancer undergo definitive resection?. Diseases Colon Rectum 2020; 63: 172–182.

34.

Stacy

. A generalization of the gamma distribution. Ann Math Stat 1962; 33: 1187–1192.

35.

Cain

Robins

Lanoy

, et al. When to start treatment? a systematic approach to the comparison of dynamic regimes using observational data. Int J Biostat 2010; 6: 18.

36.

Cole

Hernán

. Constructing inverse probability weights for marginal structural models. Am J Epidemiol 2008; 168: 656–664.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

2.16 MB

0.00 MB