Multi-scale semi-supervised clustering of brain images: deriving disease subtypes

Disease heterogeneity is a significant obstacle to understanding pathological processes and delivering precision diagnostics and treatment. Clustering methods have gained popularity in stratifying patients into subpopulations (i.e., subtypes) of brain diseases using imaging data. However, unsupervised clustering approaches are often confounded by anatomical and functional variations not related to a disease or pathology of interest. Semi-supervised clustering techniques have been proposed to overcome this and, therefore, capture disease-specific patterns more effectively. An additional limitation of both unsupervised and semi-supervised conventional machine learning methods is that they typically model, learn and infer from data at a basis of feature sets pre- defined at a fixed scale or scales (e.g, an atlas-based regions of interest). Herein we propose a novel method, Multi-scAle heteroGeneity analysIs and Clustering (MAGIC), to depict the multi-scale presentation of disease heterogeneity, which builds on a previously proposed semi-supervised clustering method, HYDRA. It derives multi-scale and clinically interpretable feature representations and exploits a double-cyclic optimization procedure to drive inter-scale-consistent disease subtypes or neuroanatomical dimensions effectively. More importantly, to fill in the gap of understanding under what conditions the clustering model can estimate true heterogeneity related to diseases, we conducted extensive and systematic semi-simulated experiments to evaluate the proposed method on a sizeable healthy control sample from the UK Biobank (N=4403). We then applied MAGIC to real imaging data of Alzheimers disease (ADNI, N=1728) to demonstrate its potential and challenges in dissecting the neuroanatomical heterogeneity of brain diseases. Taken together, we aim to provide guidelines on when such analyses can succeed or should be taken with caution. The code of the proposed method is publicly available at https://github.com/anbai106/MAGIC.

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Fully Automatic Segmentation of MRI Brain Images Using Probabilistic Anisotropic Diffusion and Multi-scale Watersheds

Scale Space Methods in Computer Vision - Lecture Notes in Computer Science ◽

10.1007/3-540-44935-3_45 ◽

2003 ◽

pp. 641-656 ◽

Cited By ~ 4

Author(s):

Carl Undeman ◽

Tony Lindeberg

Keyword(s):

Anisotropic Diffusion ◽

Automatic Segmentation ◽

Brain Images ◽

Multi Scale ◽

Mri Brain ◽

Fully Automatic ◽

Mri Brain Images

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A Multi-Scale Framework for Bias Field Estimation in MRI Brain Images

International Journal of Engineering & Technology ◽

10.14419/ijet.v7i4.10.20835 ◽

2018 ◽

Vol 7 (4.10) ◽

pp. 197

Author(s):

Maryjo M George ◽

Kalaivani S

Keyword(s):

Intensity Variation ◽

Bias Field ◽

Intensity Inhomogeneity ◽

Brain Images ◽

Multi Scale ◽

Field Estimation ◽

Corrected Data ◽

Quantitative Analyses ◽

Mr Brain Images ◽

Mr Brain

Intensity inhomogeneity is an artifact in MR brain images and causes intensity variation of same tissues on the basis of location of the tissue within the image. It is crucial to minimize this phenomenon to improve the accuracy of the computer-aided diagnosis. Unlike the several methods proposed in the past to minimize intensity inhomogeneity, this proposed method uses a pyramidal decomposition strategy to estimate the bias field in MR brain images. The bias field estimated from the proposed multi-scale framework can be effectively used for intensity inhomogeneity correction of the acquired MR data. The proposed methodology has been tested on simulated database and quantitative analyses in terms of coefficient of variation in grey matter and white matter tissue regions separately and combined coefficient of joint variation are assessed. The qualitative and quantitative analyses on the corrected data indicate that the method is effective for intensity inhomogeneity on brain MR images.

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3DMSNET: 3D CNN Based Brain MRI Segmentation

International Journal of Engineering and Advanced Technology - Regular Issue ◽

10.35940/ijeat.e1027.0785s319 ◽

2019 ◽

Vol 8 (5S3) ◽

pp. 107-110

Keyword(s):

Nearest Neighbor ◽

Automatic Segmentation ◽

Brain Mri ◽

Self Similarity ◽

Brain Images ◽

Multi Scale ◽

Segmentation Methods ◽

Scale Network ◽

Automatic Methods ◽

3D Cnn

Segmentation of the brain images has become an important task to analyze the abnormality in infants. Automatic methods are important as the infant brain growth has to be tracked and it is almost impossible for an individual to manually segment the MRI data on particular intervals. The manual segmentation tasks are time-consuming and require highly skilled professionals to segment images. Automatic segmentation methods have gained huge support for segmenting MRI images. Several segmentation methods lack accuracies due to nearest neighbor or self-similarity problems. The CNNs have outperformed the traditional methods and are proving to be more reliable day by day. The proposed method is a patch-based method which uses 3DMSnet (3D Multi-Scale Network) for segmentation. The model is evaluated on BrainWeb and other publicly available datasets.

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