This article proposes a robust Bayesian approach to regression for modelling continuous, strictly positive, and asymmetric biomedical data. The methodology is based on log-symmetric distributions, offering flexibility in capturing skewness and accommodating heavy-tailed behaviour. Robustness is achieved through the careful specification of prior distributions and full posterior inference is conducted using Markov Chain Monte Carlo (MCMC) techniques. This allows for accurate estimation, comprehensive uncertainty quantification, and resilience to outliers. Model performance is evaluated through both classical and fully Bayesian selection criteria, including AIC, BIC, DIC, ICOMP, WAIC, and PSIS-LOO, providing a thorough assessment of fit and predictive ability. The effectiveness and adaptability of the proposed approach are demonstrated through extensive simulation studies and applications to real biomedical datasets involving physiological and diagnostic measurements. These results highlight the practical value of robust Bayesian regression for modern biomedical research, especially when distributional asymmetry and inferential reliability are of primary concern.
Cengiz et al. (Tue,) studied this question.