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http://dx.doi.org/10.29220/CSAM.2018.25.2.173

Weighted zero-inflated Poisson mixed model with an application to Medicaid utilization data  

Lee, Sang Mee (Department of Public Health Sciences, University of Chicago)
Karrison, Theodore (Department of Public Health Sciences, University of Chicago)
Nocon, Robert S. (Department of Medicine, University of Chicago)
Huang, Elbert (Department of Medicine, University of Chicago)
Publication Information
Communications for Statistical Applications and Methods / v.25, no.2, 2018 , pp. 173-184 More about this Journal
Abstract
In medical or public health research, it is common to encounter clustered or longitudinal count data that exhibit excess zeros. For example, health care utilization data often have a multi-modal distribution with excess zeroes as well as a multilevel structure where patients are nested within physicians and hospitals. To analyze this type of data, zero-inflated count models with mixed effects have been developed where a count response variable is assumed to be distributed as a mixture of a Poisson or negative binomial and a distribution with a point mass of zeros that include random effects. However, no study has considered a situation where data are also censored due to the finite nature of the observation period or follow-up. In this paper, we present a weighted version of zero-inflated Poisson model with random effects accounting for variable individual follow-up times. We suggested two different types of weight function. The performance of the proposed model is evaluated and compared to a standard zero-inflated mixed model through simulation studies. This approach is then applied to Medicaid data analysis.
Keywords
emergency department; Health care utilization; weight function; zero-inflated model;
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1 Emerson SS, McGee DL, Fennerty B, Hixson L, Garewal H, and Alberts D (1993). Design and analysis of studies to reduce the incidence of colon polyps. Statistics in Medicine, 12, 339-351.   DOI
2 Goodman DC, Mick SS, Bott D, et al. (2003). Primary care service areas: a new tool for the evaluation of primary care services. Health Services Research, 38, 287-309.   DOI
3 Hall DB (2000). Zero-inflated and binomial regression with random effects: a case study, Biometrics, 56, 1030-1039.
4 Hsu CH (2005). Joint modelling of recurrence and progression of adenomas: a latent variable approach. Statistical Modelling, 5, 201-215.   DOI
5 Hsu CH (2007). A weighted zero-inflated Poisson model for estimation of recurrence of adenomas. Statistical Methods in Medical Research, 16, 155-166.   DOI
6 Lambert D (1992). Zero-inflated Poisson regression, with an application to defects in manufacturing. Technometrics, 34, 1-14.   DOI
7 Lee AH, Wang K, Scott JA, Yau KK, and McLachlan GJ (2006). Multi-level zero-inflated Poisson regression modelling of correlated count data with excess zeros. Statistical Methods in Medical Research, 15, 47-61.   DOI
8 Lee AH, Wang K, and Yau KK (2001). Analysis of zero-inflated Poisson incorporating extent of exposure. Biometrical Journal, 43, 963-975.   DOI
9 McGilchrist C and Yau K (1995). The derivation of BLUP, ML, REML estimation methods for generalised linear mixed models. Communications in Statistics-Theory and Methods, 24, 2963-2980.
10 Min Y and Agresti A (2005). Random effect models for repeated measures of zero-inflated count data. Statistical Modelling, 5, 1-19.   DOI
11 Moghimbeigi A, Eshraghian MR, Mohammad K, and McArdle B (2008). Multilevel zero-inflated negative binomial regression modeling for over-dispersed count data with extra zeros. Journal of Applied Statistics, 35, 1193-1202.   DOI
12 Monod A (2014). Random effects modeling and the zero-inflated Poisson distribution. Communications in Statistics, 43, 664-680.   DOI
13 Mullahy J (1986). Specification and testing of some modified count data models. Journal of Econometrics, 33, 341-365.
14 Ridout M, Demetrio CG, and Hinde J (1998). Models for count data with many zeros. In Proceedings of the XIXth International Biometric Conference, 19, 179-192.
15 Yau KK and Lee AH (2001). Zero-inflated Poisson regression with random effects to evaluate an occupational injury prevention programme. Statistics in Medicine, 20, 2907-2920.   DOI