Abstract
We consider data from the Danish twin registry and aim to study in detail how lifetimes for twin-pairs are correlated. We consider models where we specify the marginals using a regression structure, here Cox’s regression model or the additive hazards model. The best known such model is the Clayton-Oakes model. This model can be extended in several directions. One extension is to allow the dependence parameter to depend on covariates. Another extension is to model dependence via piecewise constant cross-hazard ratio models. We show how both these models can be implemented for large sample data, and suggest a computational solution for obtaining standard errors for such models for large registry data. In addition we consider alternative models that have some computational advantages and with different dependence parameters based on odds ratios of the survival function using the Plackett distribution. We also suggest a way of assessing how and if the dependence is changing over time, by considering either truncated or right-censored versions of the data to measure late or early dependence. This can be used for formally testing if the dependence is constant, or decreasing/increasing. The proposed procedures are applied to Danish twin data to describe dependence in the lifetimes of the twins. Here we show that the early deaths are more correlated than the later deaths, and by comparing MZ and DZ associations we suggest that early deaths might be more driven by genetic factors. This conclusion requires models that are able to look at more local dependence measures. We further show that the dependence differs for MZ and DZ twins and appears to be the same for males and females, and that there are indications that the dependence increases over calendar time.
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References
Anderson J, Louis T, Holm N, Harvald B (1992) Time-dependent association measures for bivariate survival distributions. J Am Stat Assoc 87:641–650
Clayton DG (1978) A model for association in bivariate life tables and its application in epidemiological studies of familial tendency in chronic disease incidence. Biometrika 65:141–151
Ghosh D (2006) Semiparametric global cross-ratio models for bivariate censored data. Scand J Stat 33(4):609–619
Glidden D, Self S (1999) Semiparametric likelihood estimation in the clayton-oakes failure time model. Scand J Stat 26:363–372
Glidden DV (2000) A two-stage estimator of the dependence parameter for the Clayton-Oakes model. Lifetime Data Anal 6(2):141–156
Hjelmborg J, Iachine I, Skytthe A, Vaupel J, McGue M, Kaprio J, Pedersen N, Christensen K (2006) Genetic influence on human lifespan and longevity. Hum Genet 119(3):312–321
Hu T, Nan B, Lin X, Robins J (2011) Time-dependent cross ratio estimation for bivariate failure times. Biometrika 98(2):341
Martinussen T, Scheike T (2006) Dynamic regression models for survival data. Springer-Verlag, New York
Nan B, Lin X, Lisabeth L, Harlow S (2006) Piecewise constant cross-ratio estimation for association of age at a marker event and age at menopause. J Am Stat Assoc 101(473):65–77
Oakes D (1982) A model for association in bivariate survival data. J R Stat Soc B 44:414–422
Oakes D (1986a) A model for bivariate survival data. In: Moolgavkar SH, Prentice RL (eds) Modern statistical methods in chronic disease epidemiology. Wiley, New York, pp 151–166
Oakes D (1986b) Semiparametric inference in a model for association in bivariate survival data. Biometrika 73:353–361
Oakes D (1989) Bivariate survival models induced by frailties. J Am Stat Assoc 84:487–493
Petzoldt T, Rinke K (2007) simecol: an object-oriented framework for ecological modeling in R. J Stat Softw 22(9):1–31
Plackett RL (1965) A class of bivariate distributions. J Am Stat Assoc 60(310):516–522
Sham P (1998) Statistics in human genetics. Arnold Applications of Statistics, New York
Shih J, Albert P (2010) Modeling familial association of ages at onset of disease in the presence of competing risk. Biometrics 66:1012–1023
Spiekerman CF, Lin DY (1998) Marginal regression models for multivariate failure time data. J Am Stat Assoc 93:1164–1175
Wienke A, Holm N, Christensen K, Skytthe A, Vaupel J, Yashin A (2003) The heritability of cause-specific mortality: a correlated gamma-frailty model applied to mortality due to respiratory diseases in danish twins born 1870–1930. Stat Med 22(24):3873–3887
Wienke A, Lichtenstein P, Czene K, Yashin AI. The role of correlated frailty models in studies of human health, ageing, and longevity. In: Auget J-L, Balakrishnan N, Mesbah M, Molenberghs G (ed) Advances in statistical methods for the health sciences. Birkhäuser, Boston, pp 151–166
Wienke A, Lichtenstein P, Czene K, Yashin A (2007) The role of correlated frailty models in studies of human health, ageing, and longevity. Adv Stat Methods Health Sci 151–166
Zdravkovic S, Wienke A, Pedersen N, Marenberg M, Yashin A, De Faire U (2002) Heritability of death from coronary heart disease: a 36-year follow-up of 20,966 swedish twins. J Intern Med 252(3):247–254
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Scheike, T.H., Holst, K.K. & Hjelmborg, J.B. Measuring early or late dependence for bivariate lifetimes of twins. Lifetime Data Anal 21, 280–299 (2015). https://doi.org/10.1007/s10985-014-9309-5
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DOI: https://doi.org/10.1007/s10985-014-9309-5