Finite Mixture, Zero-inflated Poisson and Hurdle models with application to SIDS

This study examines the incidence of sudden infant death syndrome (SIDS) in Canterbury (1973-1989) in relation to climate. Three mixture models (Finite Mixture, Zero-inflated Poisson and Hurdle) are used as novel methods which are able to highlight differential effects of climatic covariates between months of SIDS and no SIDS. These methods accommodate the extra zeros, heterogeneity and autocorrelation found in the SIDS series. Mixture models are comprehensive methods applicable to many discrete chronological series including the Canterbury SIDS data. This analysis leads to a better understanding of the association between climate and SIDS deaths.Results show a deviance-temperature (a measure of extreme change from the fortnightly average) is significantly associated with SIDS risk (p > 0.005). Months where there is a high deviance-temperature are associated with increased risk of SIDS, compared to months where the temperature has remained reasonably constant. This finding is consistent with the theory that hyperthermia, or overheating of infants leads to increased SIDS risk. In months where at least one SIDS death occurs, increased humidity leads to increased risk of SIDS (p > 0.001).

[1]  D. Lindenmayer,et al.  Modelling the abundance of rare species: statistical models for counts with extra zeros , 1996 .

[2]  M. Clements,et al.  Seasonal differences in risk factors for sudden infant death syndrome , 1999, Acta paediatrica.

[3]  N. L. Johnson,et al.  Distributions in Statistics: Discrete Distributions. , 1970 .

[4]  M. Graffar [Modern epidemiology]. , 1971, Bruxelles medical.

[5]  M. Campbell Sudden infant death syndrome and environmental temperature: further evidence for a time‐lagged relationship (for editorial comment, see page 361) , 1989, The Medical journal of Australia.

[6]  Dankmar Böhning,et al.  The zero‐inflated Poisson model and the decayed, missing and filled teeth index in dental epidemiology , 1999 .

[7]  Dankmar Böhning,et al.  On estimation of the Poisson parameter in zero-modified Poisson models , 2000 .

[8]  J. C. Wells Can risk factors for over-heating explain epidemiological features of sudden infant death syndrome? , 1997, Medical hypotheses.

[9]  A. P. Ryan,et al.  Weather temperatures and sudden infant death syndrome: a regional study over 22 years in New Zealand. , 1998, Journal of epidemiology and community health.

[10]  E. Mitchell,et al.  Reduction in mortality from sudden infant death syndrome in New Zealand: 1986-92. , 1994, Archives of disease in childhood.

[11]  K. Liang,et al.  Sudden infant death syndrome in relation to weather and optimetrically measured air pollution in Taiwan. , 1995, Pediatrics.

[12]  J. Nash Compact Numerical Methods for Computers , 2018 .

[13]  Martin L. Puterman,et al.  Analysis of Patent Data—A Mixed-Poisson-Regression-Model Approach , 1998 .

[14]  R. Scragg,et al.  Trends in rates and seasonal distribution of sudden infant deaths in England and Wales, 1988-92 , 1995, BMJ.

[15]  Pravin K. Trivedi,et al.  Regression Analysis of Count Data: Preface , 1998 .

[16]  Diane Lambert,et al.  Zero-inflacted Poisson regression, with an application to defects in manufacturing , 1992 .

[17]  E. Mitchell,et al.  Four modifiable and other major risk factors for cot death: The New Zealand study , 1992, Journal of paediatrics and child health.

[18]  LambertDiane Zero-inflated Poisson regression, with an application to defects in manufacturing , 1992 .

[19]  M. Puterman,et al.  Mixed Poisson regression models with covariate dependent rates. , 1996, Biometrics.

[20]  D H Freeman,et al.  Birth weight- and gestational age-specific sudden infant death syndrome mortality: United States, 1991 versus 1995. , 2000, Pediatrics.

[21]  P Schlattmann,et al.  Covariate adjusted mixture models and disease mapping with the program DismapWin. , 1996, Statistics in medicine.

[22]  ScienceDirect Computational statistics & data analysis , 1983 .