Evaluating Eight Smoking Metrics for Modelling Survival in Non-Small Cell Lung Cancer

Authors

Andrew Cl Lam
Yao Li
M Catherine Brown
Yangqing Deng
Katrina Hueniken
Natasha B Leighl
Frances A Shepherd
Kiera Murison
Zhichao Wang
Jui Kothari
Angela S Wenzlaff
Haoran Liu
Takashi Kohno
Angela Cecilia Pesatori
Curtis Harris
Hongxia Ma
Juncheng Dai
Matthew J Barnett
Ryan Diver
Leticia Ferro Leal
Guillermo Fernandez-Tardon
Mónica Pérez-Ríos
Michael Pa Davies
Bernd Holleczek
Paul Brennan
David Zaridze
Ivana Holcatova
Jolanta Lissowska
Beata Świątkowska
Dana Mates
Milan Savic
Hermann Brenner
Angeline S Andrew
Fiona Taylor
John K Field
Alberto Ruano-Ravina
Sanjay S Shete
Adonina Tardon
Ying Wang
Loic Le Marchand
Rui Manuel Reis
Matthew B Schabath
Marian L Neuhouser
Hongbing Shen
Maria Teresa Landi
Kouya Shiraishi
Jie Zhang
Ann G Schwartz
Ming S Tsao
David C Christiani
Ping Yang
Rayjean J Hung
Wei Xu
Geoffrey Liu

Language

English

Publication Date

3-19-2026

Journal

Cancer Epidemiology

DOI

10.1016/j.canep.2026.103052

PMID

41861692

Abstract

Introduction: Smoking is a strong modifiable prognostic factor for lung cancer survival. We compared eight smoking metrics to determine which metric best models the relationship between smoking exposure with overall survival (OS) and lung cancer-specific survival (LCSS). These metrics included cigarettes-per-day, smoking duration, pack-years, square-root pack-years, logcig-years, the comprehensive smoking index, age-of-initiation, and years-since-quit.

Materials/methods: This retrospective, pooled analysis included 25 International Lung Cancer Consortium studies between June 1, 1983-December 31, 2019. The performance of smoking metrics for modelling OS was compared based on 1) strength and significance in adjusted Cox-proportional hazard models and 2) linearity based on the goodness-of-fit assuming the log-hazard varies linearly with each smoking metric (i.e. the hazard ratio is constant across different values of the smoking metric) compared to models using non-linear splines. This process was repeated across clinicodemographic subgroups and for LCSS.

Results: In total, 28,702 lung cancer patients were included (median age 64 [IQR: 57-71]; 53% male). Logcig-years (log(cigarettes/day+1)·years-smoked) had the highest adjusted hazard ratio per standard deviation (aHR 1.11; 95% CI: 1.09-1.13) and best goodness-of-fit when modelled linearly. Square-root pack-years had a similar effect size (aHR 1.11; 95% CI: 1.09-1.13) and had a strong linear relationship on visual assessment of spline curves. In subgroup analyses, logcig-years had a large effect size and maintained a linear relationship regardless of age, sex, stage, and histology. For lung cancer-specific survival (LCSS), logcig-years again had the highest aHR (1.09; 95% CI: 1.05-1.12) and the best linear goodness-of-fit, while square-root pack-years demonstrated the most linear relationship on visual assessment.

Discussion: Logcig-years best modelled the relationship between smoking exposure and OS as well as LCSS, and had consistent associations across clinicodemographic subgroups. Logcig-years should be considered in clinical and research applications for quantifying smoking exposure in lung cancer.

Keywords

Cancer survival, Cigarette smoking, Lung cancer, Overall survival, Smoking metric

Published Open-Access

yes

Recommended Citation

Lam, Andrew Cl; Li, Yao; Brown, M Catherine; et al., "Evaluating Eight Smoking Metrics for Modelling Survival in Non-Small Cell Lung Cancer" (2026). Faculty, Staff and Student Publications. 6526.
https://digitalcommons.library.tmc.edu/uthgsbs_docs/6526