Abstract
Multi-atlas segmentation has been widely used to segment various anatomical structures. The success of this technique partly relies on the selection of atlases that are best mapped to a new target image after registration. Recently, manifold learning has been proposed as a method for atlas selection. Each manifold learning technique seeks to optimize a unique objective function. Therefore, different techniques produce different embeddings even when applied to the same data set. Previous studies used a single technique in their method and gave no reason for the choice of the manifold learning technique employed nor the theoretical grounds for the choice of the manifold parameters. In this study, we compare side-by-side the results given by 3 manifold learning techniques (Isomap, Laplacian Eigenmaps and Locally Linear Embedding) on the same data set. We assess the ability of those 3 different techniques to select the best atlases to combine in the framework of multi-atlas segmentation. First, a leave-one-out experiment is used to optimize our method on a set of 110 manually segmented atlases of hippocampi and find the manifold learning technique and associated manifold parameters that give the best segmentation accuracy. Then, the optimal parameters are used to automatically segment 30 subjects from the Alzheimer’s Disease Neuroimaging Initiative (ADNI). For our dataset, the selection of atlases with Locally Linear Embedding gives the best results. Our findings show that selection of atlases with manifold learning leads to segmentation accuracy close to or significantly higher than the state-of-the-art method and that accuracy can be increased by fine tuning the manifold learning process.
Highlights
Multi-atlas segmentation is an automated segmentation method that shows good robustness and accuracy in segmenting various anatomical structures [1,2,3,4]
The best combination of manifold learning technique and parameters is Locally Linear Embedding with a manifold dimension of d~11, a neighbourhood size kD~23 and combining the top kd ~7 matches in STAPLE, giving a mean (SD) Dice’s similarity index DSmax of 0.9077 (0.0211)
The difference in accuracy compared to the previous experiment can be explained by the fact that the atlases and the 30 Alzheimer’s Disease Neuroimaging Initiative (ADNI) subjects belong to different data sets
Summary
Multi-atlas segmentation is an automated segmentation method that shows good robustness and accuracy in segmenting various anatomical structures [1,2,3,4]. In this framework, a segmentation of a target image is obtained through the propagation and fusion of multiple atlas images by mean of registration. In [12], manifold learning is used to select atlases which are located in the neighbourhood of the target on the manifold.
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