Multikink quantile regression for longitudinal data with application to progesterone data analysis. (English) Zbl 1522.62243
Summary: Motivated by investigating the relationship between progesterone and the days in a menstrual cycle in a longitudinal study, we propose a multikink quantile regression model for longitudinal data analysis. It relaxes the linearity condition and assumes different regression forms in different regions of the domain of the threshold covariate. In this paper, we first propose a multikink quantile regression for longitudinal data. Two estimation procedures are proposed to estimate the regression coefficients and the kink points locations: one is a computationally efficient profile estimator under the working independence framework while the other one considers the within-subject correlations by using the unbiased generalized estimation equation approach. The selection consistency of the number of kink points and the asymptotic normality of two proposed estimators are established. Second, we construct a rank score test based on partial subgradients for the existence of the kink effect in longitudinal studies. Both the null distribution and the local alternative distribution of the test statistic have been derived. Simulation studies show that the proposed methods have excellent finite sample performance. In the application to the longitudinal progesterone data, we identify two kink points in the progesterone curves over different quantiles and observe that the progesterone level remains stable before the day of ovulation, then increases quickly in 5 to 6 days after ovulation and then changes to stable again or drops slightly.
{© 2022 The International Biometric Society.}
{© 2022 The International Biometric Society.}
MSC:
| 62P10 | Applications of statistics to biology and medical sciences; meta analysis |
Keywords:
efficiency; longitudinal data analysis; multikink; progesterone data; quantile regression; score testReferences:
| [1] | Brumback, B.A. and Rice, J.A. (1998) Smoothing spline models for the analysis of nested and crossed samples of curves. Journal of the American Statistical Association, 93, 961-976. · Zbl 1064.62515 |
| [2] | Chan, N.H., Yau, C.Y. and Zhang, R.‐M. (2014) Group lasso for structural break time series. Journal of the American Statistical Association, 109, 590-599. · Zbl 1367.62251 |
| [3] | Das, R., Banerjee, M., Nan, B. and Zheng, H. (2016) Fast estimation of regression parameters in a broken‐stick model for longitudinal data. Journal of the American Statistical Association, 111, 1132-1143. |
| [4] | Fan, J. and Zhang, J.‐T. (2000) Two‐step estimation of functional linear models with applications to longitudinal data. Journal of the Royal Statistical Society: Series B (Statistical Methodology), 62, 303-322. |
| [5] | Fryzlewicz, P. (2014) Wild binary segmentation for multiple change‐point detection. Annals of Statistics, 42, 2243-2281. · Zbl 1302.62075 |
| [6] | Ge, X., Peng, Y. and Tu, D. (2020) A threshold linear mixed model for identification of treatment‐sensitive subsets in a clinical trial based on longitudinal outcomes and a continuous covariate. Statistical Methods in Medical Research, 29, 2919-2931. |
| [7] | Hansen, B.E. (2017) Regression kink with an unknown threshold. Journal of Business & Economic Statistics, 35, 228-240. |
| [8] | Hansen, L.P. (1982) Large sample properties of generalized method of moments estimators. Econometrica, 50, 1029-1054. · Zbl 0502.62098 |
| [9] | Hendricks, W. and Koenker, R. (1992) Hierarchical spline models for conditional quantiles and the demand for electricity. Journal of the American Statistical Association, 87, 58-68. |
| [10] | Jiang, F., Zhao, Z. and Shao, X. (2022) Modeling the Covid‐19 infection trajectory: a piecewise linear quantile trend model. Journal of the Royal Statistical Society: Series B (Statistical Methodology), forthcoming. · Zbl 07686592 |
| [11] | Lange, K. (1994) An adaptive barrier method for convex programming. Methods and Applications of Analysis, 1, 392-402. · Zbl 0835.90068 |
| [12] | Leng, C. and Zhang, W. (2014) Smoothing combined estimating equations in quantile regression for longitudinal data. Statistics and Computing, 24, 123-136. · Zbl 1325.62141 |
| [13] | Li, C., Dowling, N.M. and Chappell, R. (2015) Quantile regression with a change‐point model for longitudinal data: an application to the study of cognitive changes in preclinical Alzheimer’s disease. Biometrics, 71, 625-635. · Zbl 1419.62390 |
| [14] | Li, C., Wei, Y., Chappell, R. and He, X. (2011) Bent line quantile regression with application to an allometric study of land mammals’ speed and mass. Biometrics, 67, 242-249. · Zbl 1217.62052 |
| [15] | Li, J. and Zhang, W. (2011) A semiparametric threshold model for censored longitudinal data analysis. Journal of the American Statistical Association, 106, 685-696. · Zbl 1232.62065 |
| [16] | Liang, K.‐Y. and Zeger, S.L. (1986) Longitudinal data analysis using generalized linear models. Biometrika, 73, 13-22. · Zbl 0595.62110 |
| [17] | Munro, C.J., Stabenfeldt, G., Cragun, J., Addiego, L., Overstreet, J. and Lasley, B. (1991) Relationship of serum estradiol and progesterone concentrations to the excretion profiles of their major urinary metabolites as measured by enzyme immunoassay and radioimmunoassay. Clinical Chemistry, 37, 838-844. |
| [18] | Oka, T. and Qu, Z. (2011) Estimating structural changes in regression quantiles. Journal of Econometrics, 162, 248-267. · Zbl 1441.62823 |
| [19] | Qu, A., Lindsay, B.G. and Li, B. (2000) Improving generalised estimating equations using quadratic inference functions. Biometrika, 87, 823-836. · Zbl 1028.62045 |
| [20] | Wang, H.J., Feng, X. and Dong, C. (2019) Copula‐based quantile regression for longitudinal data. Statistica Sinica, 29, 245-264. · Zbl 1412.62045 |
| [21] | Wu, H. and Zhang, J.‐T. (2002) Local polynomial mixed‐effects models for longitudinal data. Journal of the American Statistical Association, 97, 883-897. · Zbl 1048.62048 |
| [22] | Zhong, W., Wan, C. and Zhang, W. (2021) Estimation and inference for multi‐kink quantile regression. Journal of Business & Economic Statistics, https://doi.org/10.1080/07350015.2021.1901720. · Zbl 07928242 · doi:10.1080/07350015.2021.1901720 |
This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. In some cases that data have been complemented/enhanced by data from zbMATH Open. This attempts to reflect the references listed in the original paper as accurately as possible without claiming completeness or a perfect matching.
