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Interactive Segmentation in Multimodal Medical Imagery Using a Bayesian Transductive Learning Approach

Noah Lee; Jesus Caban; Shahram Ebadollahi; Andrew F. Laine

Title:
Interactive Segmentation in Multimodal Medical Imagery Using a Bayesian Transductive Learning Approach
Author(s):
Lee, Noah
Caban, Jesus
Ebadollahi, Shahram
Laine, Andrew F.
Date:
Type:
Articles
Department:
Biomedical Engineering
Permanent URL:
Book/Journal Title:
Medical Imaging 2009: Computer-aided Diagnosis: 10-12 February 2009, Lake Buena Vista, Florida, United States ; Proceedings of SPIE, vol. 7260
Book Author:
Karssemeijer, Nico
Publisher:
SPIE
Publisher Location:
Bellingham, Wash.
Abstract:
Labeled training data in the medical domain is rare and expensive to obtain. The lack of labeled multimodal medical image data is a major obstacle for devising learning-based interactive segmentation tools. Transductive learning (TL) or semi-supervised learning (SSL) offers a workaround by leveraging unlabeled and labeled data to infer labels for the test set given a small portion of label information. In this paper we propose a novel algorithm for interactive segmentation using transductive learning and inference in conditional mixture nave Bayes models (T-CMNB) with spatial regularization constraints. T-CMNB is an extension of the transductive nave Bayes algorithm [1, 20]. The multimodal Gaussian mixture assumption on the class-conditional likelihood and spatial regularization constraints allow us to explain more complex distributions required for spatial classification in multimodal imagery. To simplify the estimation we reduce the parameter space by assuming nave conditional independence between the feature space and the class label. The nave conditional independence assumption allows efficient inference of marginal and conditional distributions for large scale learning and inference [19]. We evaluate the proposed algorithm on multimodal MRI brain imagery using ROC statistics and provide preliminary results. The algorithm shows promising segmentation performance with a sensitivity and specificity of 90.37% and 99.74% respectively and compares competitively to alternative interactive segmentation schemes.
Subject(s):
Biomedical engineering
Publisher DOI:
10.1117/12.811675
Item views:
257
Metadata:
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