[摘要] There is a growing interest in using fMRI measurements and analyses as tools for pre-surgical planning. For such applications, spatial precision and control over false negatives and false positives are vital, requiring careful design of an image smoothing method and a classification procedure. This dissertation seeks computationally efficient approaches to overcome the limitation of existing methods and address new challenges in pre-surgical fMRI analyses.In the first study, we develop a Bayesian solution for the pre-surgical analysis of a single fMRI brain image. Specifically, we propose a novel spatially adaptive conditionally autoregressive model (CWAS) that adaptively and locally smoothes the fMRI data. We introduce a Bayesian theoretical decision approach that allows control of both false positives and false negatives to identify activated and deactivated brain regions. We benchmark the proposed solution to two existing spatially adaptive smoothing models, through simulation studies and two patients;; pre-surgical fMRI datasets. In the second study, we extend the idea of spatially adaptive smoothing to multiple fMRI brain images in order to leverage spatial correlations across multiple images. In particular, we propose three spatially adaptive multivariate conditional autoregressive models that can be considered as extensions of the multivariate conditional autoregressive (MCAR) model (Gelfand and Vounatsou, 2003), the CWAS model, and the model of Reich and Hodges (2008), respectively, and one mixed-effects model assuming that all observed fMRI images originate from one common image. We compare the performance of the proposed models with those from the MCAR and CWAS models using simulation studies and two sets of fMRI brain images, acquired either from the same patient, same paradigm or same patient, different paradigms.The last study is motivated by fMRI brain images acquired at two different spatial resolutions from the same patient. We develop a Bayesian hierarchical model with spatially varying coefficients to retain the spatial precision from the high resolution image while utilizing information from the low resolution image to improve estimation and inference. Comparisons between the proposed model and the CWAS model, which operates at a single spatial resolution, are performed on simulated data and a patient;;s multi-resolution pre-surgical fMRI data.