Non-Local Means Inpainting of MS Lesions in Longitudinal Image Processing

In medical imaging, multiple sclerosis (MS) lesions can lead to confounding effects in automatic morphometric processing tools such as registration, segmentation and cortical extraction, and subsequently alter individual longitudinal measurements. Multiple magnetic resonance imaging (MRI) inpainting...

Full description

Saved in:
Bibliographic Details
Published in:Frontiers in aging neuroscience 2015-12, Vol.9, p.456-456
Main Authors: Guizard, Nicolas, Nakamura, Kunio, Coupé, Pierrick, Fonov, Vladimir S, Arnold, Douglas L, Collins, D Louis
Format: Article
Language:English
Subjects:
Allium cepa
Atrophy
Automation
Brain research
Classification
Computer Science
Cortex
Image processing
Inpainting
Lesions
Magnetic resonance imaging
Medical Imaging
Methods
MRI
Multiple sclerosis
Neuroimaging
Neuroscience
NMR
non-local
Nuclear magnetic resonance
Segmentation
Substantia alba
Ventricle
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:In medical imaging, multiple sclerosis (MS) lesions can lead to confounding effects in automatic morphometric processing tools such as registration, segmentation and cortical extraction, and subsequently alter individual longitudinal measurements. Multiple magnetic resonance imaging (MRI) inpainting techniques have been proposed to decrease the impact of MS lesions in medical image processing, however, most of these methods make the assumption that lesions only affect white matter. Here, we propose a method to fill lesion regions using the patch-based non-local mean (NLM) strategy. The method consists of a hierarchical concentric filling strategy after identification of the lesion region. The lesion is filled iteratively, based on the surrounding tissue intensity, using an onion peel strategy. This concentric technique presents the advantage of preserving the local information and therefore the continuity of the anatomy and does not require identification of any a priori normal brain tissues. The method is first evaluated on 20 healthy subjects with simulated artificial MS lesions where we assessed our technique by measuring the peak signal-to-noise ratio (PSNR) of the images with inpainted lesion and the original healthy images. Second, in order to assess the impact of lesion filling on longitudinal image analyses, we performed a power analysis with sample size estimation to evaluate brain atrophy and ventricular growth in patients with MS. The method was compared to two different publicly available methods (FSL lesion fill and Lesion LEAP) and a more classic method, which fills the region with intensities similar to that of the surrounding healthy white matter tissue or mask the lesions. The proposed method was shown to exceed the other methods in reproducing the fidelity of healthy subject images where the lesions were inpainted. The method also improved the power to detect brain atrophy or ventricular growth by decreasing the sample size by 25% in the presence of MS lesions.
ISSN:1662-4548
1662-453X
1663-4365
1662-453X
1663-4365
DOI:10.3389/fnins.2015.00456