Restricted accessResearch articleFirst published online 2019-8
Flexible and structured survival model for a simultaneous estimation of non-linear and non-proportional effects and complex interactions between continuous variables: Performance of this multidimensional penalized spline approach in net survival trend analysis
Cancer survival trend analyses are essential to describe accurately the way medical practices impact patients’ survival according to the year of diagnosis. To this end, survival models should be able to account simultaneously for non-linear and non-proportional effects and for complex interactions between continuous variables. However, in the statistical literature, there is no consensus yet on how to build such models that should be flexible but still provide smooth estimates of survival. In this article, we tackle this challenge by smoothing the complex hypersurface (time since diagnosis, age at diagnosis, year of diagnosis, and mortality hazard) using a multidimensional penalized spline built from the tensor product of the marginal bases of time, age, and year. Considering this penalized survival model as a Poisson model, we assess the performance of this approach in estimating the net survival with a comprehensive simulation study that reflects simple and complex realistic survival trends. The bias was generally small and the root mean squared error was good and often similar to that of the true model that generated the data. This parametric approach offers many advantages and interesting prospects (such as forecasting) that make it an attractive and efficient tool for survival trend analyses.
ColonnaMBossardNRemontetL, et al.Changes in the risk of death from cancer up to five years after diagnosis in elderly patients: a study of five common cancers. Int J Cancer2010; 127: 924–931.
2.
BossardNVeltenMRemontetL, et al.Survival of cancer patients in France: a population-based study from The Association of the French Cancer Registries (FRANCIM). Eur J Cancer2007; 43: 149–160.
3.
UhryZBossardNRemontetL, et al.New insights into survival trend analyses in cancer population-based studies: the SUDCAN methodology. Eur J Cancer Prev2016; 26. Trends in cancer net survival in six European Latin Countries: the SUDCAN study: S9–S15.
4.
AllemaniCWeirHKCarreiraH, et al.Global surveillance of cancer survival 1995–2009: analysis of individual data for 25,676,887 patients from 279 population-based registries in 67 countries (CONCORD-2). Lancet2015; 385: 977–1010.
5.
De AngelisRSantMColemanMP, et al.Cancer survival in Europe 1999–2007 by country and age: results of EUROCARE-5 – a population-based study. Lancet Oncol2014; 15: 23–34.
6.
EdererFAxtellLMCutlerSJ. The relative survival rate: a statistical methodology. Natl Cancer Inst Monogr1961; 6: 101–121.
7.
PermeMPStareJEsteveJ. On estimation in relative survival. Biometrics2012; 68: 113–120.
8.
CrowtherMJLambertPC. A general framework for parametric survival analysis. Stat Med2014; 33: 5280–5297.
9.
GiorgiRAbrahamowiczMQuantinC, et al.A relative survival regression model using B-spline functions to model non-proportional hazards. Stat Med2003; 22: 2767–2784.
10.
RemontetLBossardNBelotA, et al.An overall strategy based on regression models to estimate relative survival and model the effects of prognostic factors in cancer survival studies. Stat Med2007; 26: 2214–2228.
11.
RoystonPSauerbreiW. Multivariable model-building: a pragmatic approach to regression analysis based on fractional polynomials for continuous variables, New York: Wiley, 2008.
12.
SauerbreiWRoystonPLookM. A new proposal for multivariable modelling of time-varying effects in survival data based on fractional polynomial time-transformation. Biom J2007; 49: 453–473.
13.
WynantWAbrahamowiczM. Impact of the model-building strategy on inference about nonlinear and time-dependent covariate effects in survival analysis. Stat Med2014; 33: 3318–3337.
14.
CharvatHRemontetLBossardN, et al.A multilevel excess hazard model to estimate net survival on hierarchical data allowing for non-linear and non-proportional effects of covariates. Stat Med2016; 35: 3066–3084.
15.
MounierMBossardNRemontetL, et al.Changes in dynamics of excess mortality rates and net survival after diagnosis of follicular lymphoma or diffuse large B-cell lymphoma: comparison between European population-based data (EUROCARE-5). Lancet Haematol2015; 2: e481–e491.
16.
BurnhamKPAndersonDR. Model selection and multimodel inference: a practical information - theoretic approach, 2nd ed. New York: Springer-Verlag, 2010, pp. 488–488.
17.
WoodSN. Generalized additive models: an introduction with R, 2nd ed. London: Chapman & Hall/CRC, 2017.
18.
HastieTTibshiraniR. Varying-coefficient models. J R Stat Soc Series B1993; 55: 757–796.
19.
DickmanPWSloggettAHillsM, et al.Regression models for relative survival. Stat Med2004; 23: 51–64.
20.
WoodSN. GAMs with integrated model selection using penalized regression splines and applications to environmental modelling. Ecol Model2002; 157: 157–177.
21.
MarraGRadiceR. Penalised regression splines: theory and application to medical research. Stat Methods Med Res2010; 19: 107–125.
22.
EilersPHMarxBD. Flexible smoothing with B-splines and penalties. Stat Sci1996; 11: 89–121.
23.
RuppertDWandMPCarrollRJ. Semiparametric regression during 2003–2007. Electron J Stat2009; 3: 1193–1256.
MarxBDEilersPH. Multidimensional penalized signal regression. Technometrics2005; 47: 13–22.
26.
EilersPHMarxBD. Multivariate calibration with temperature interaction using two-dimensional penalized signal regression. Chemometr Intellig Lab Syst2003; 66: 159–174.
27.
UgarteMDGoicoaTEtxeberriaJ, et al.Projections of cancer mortality risks using spatio-temporal P-spline models. Stat Methods Med Res2012; 21: 545–560.
28.
EtxeberriaJUgarteMDGoicoaT, et al.On predicting cancer mortality using ANOVA-type P-spline models. REVSTAT2015; 13: 21–40.
29.
CurrieIDDurbanMEilersPH. Smoothing and forecasting mortality rates. Stat Model2004; 4: 279–298.
30.
HerndonJEHarrellFE. The restricted cubic spline hazard model. Commun Stat Theor Methods1990; 19: 639–663.
31.
HerndonJEHarrellFE. The restricted cubic spline as baseline hazard in the proportional hazards model with step function time-dependent covariables. Stat Med1995; 14: 2119–2129.
32.
GrayRJ. Flexible methods for analysing survival data using splines, with applications to breast cancer prognosis. J Am Stat Assoc1992; 87: 942–951.
33.
Rodriguez-GirondoMKneibTCadarso-SuarezC, et al.Model building in nonproportional hazard regression. Stat Med2013; 32: 5301–5314.
34.
HastieTTibshiraniR. Generalized additive models, London: Chapman and Hall, 1990.
35.
RuppertDWandMPCarrollRJ. Semiparametric regression, New York: Cambridge University Press, 2003.
36.
KauermannG. Penalized spline smoothing in multivariable survival models with varying coefficients. Comput Stat Data Anal2005; 49: 169–186.
37.
BecherHKauermannGKhomskiP, et al.Using penalized splines to model age- and season-of-birth-dependent effects of childhood mortality risk factors in rural Burkina Faso. Biom J2009; 51: 110–122.
38.
LiuXRPawitanYClementsM. Parametric and penalized generalized survival models. Stat Methods Med Res2018; 27: 1531–1546.
39.
RoystonPParmarMK. Flexible parametric proportional-hazards and proportional-odds models for censored survival data, with application to prognostic modelling and estimation of treatment effects. Stat Med2002; 21: 2175–2197.
40.
NychkaD. Bayesian confidence intervals for smoothing splines. J Am Stat Assoc1988; 83: 1134–1143.
41.
Cowppli-BonyAUhryZRemontetL, et al.Survie des personnes atteintes de cancer en France métropolitaine, 1989–2013. Partie 1 – Tumeurs solides, Saint-Maurice: Institut de veille sanitaire, 2016, pp. 274–274.
42.
DanieliCRemontetLBossardN, et al.Estimating net survival: the importance of allowing for informative censoring. Stat Med2012; 31: 775–786.
CorazziariIQuinnMCapocacciaR. Standard cancer patient population for age standardising survival ratios. Eur J Cancer2004; 40: 2307–2316.
45.
AbrahamowiczMMacKenzieTA. Joint estimation of time-dependent and non-linear effects of continuous covariates on survival. Stat Med2007; 26: 392–408.
46.
BuchholzASauerbreiW. Comparison of procedures to assess non-linear and time-varying effects in multivariable models for survival data. Biom J2011; 53: 308–331.
47.
CharvatHBossardNDaubisseL, et al.Probabilities of dying from cancer and other causes in French cancer patients based on an unbiased estimator of net survival: a study of five common cancers. Cancer Epidemiol2013; 37: 857–863.
48.
AnderssonTMDickmanPWElorantaS, et al.Estimating the loss in expectation of life due to cancer using flexible parametric survival models. Stat Med2013; 32: 5286–5300.
49.
MarraGWoodSN. Practical variable selection for generalized additive models. Comput Stat Data Anal2011; 55: 2372–2387.
50.
KooperbergCStoneCJTruongYK. Hazard regression. J Am Stat Assoc1995; 90: 78–94.
51.
GuillaumeEPornetCDejardinO, et al.Development of a cross-cultural deprivation index in five European countries. J Epidemiol Community Health2016; 70: 493–499.
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.
