Your search keyword '"Jodoin PM"' showing total 4 results

1. Tractography and machine learning: Current state and open challenges.

Author

Poulin P, Jörgens D, Jodoin PM, and Descoteaux M

Subjects

Algorithms, Humans, Brain anatomy & histology, Diffusion Tensor Imaging methods, Image Processing, Computer-Assisted methods, Machine Learning

Abstract

Supervised machine learning (ML) algorithms have recently been proposed as an alternative to traditional tractography methods in order to address some of their weaknesses. They can be path-based and local-model-free, and easily incorporate anatomical priors to make contextual and non-local decisions that should help the tracking process. ML-based techniques have thus shown promising reconstructions of larger spatial extent of existing white matter bundles, promising reconstructions of less false positives, and promising robustness to known position and shape biases of current tractography techniques. But as of today, none of these ML-based methods have shown conclusive performances or have been adopted as a de facto solution to tractography. One reason for this might be the lack of well-defined and extensive frameworks to train, evaluate, and compare these methods. In this paper, we describe several datasets and evaluation tools that contain useful features for ML algorithms, along with the various methods proposed in the recent years. We then discuss the strategies that are used to evaluate and compare those methods, as well as their shortcomings. Finally, we describe the particular needs of ML tractography methods and discuss tangible solutions for future works., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

2. A test-retest study on Parkinson's PPMI dataset yields statistically significant white matter fascicles.

Author

Cousineau M, Jodoin PM, Morency FC, Rozanski V, Grand'Maison M, Bedell BJ, and Descoteaux M

Subjects

Biomarkers, Brain diagnostic imaging, Data Mining, Databases, Factual, Female, Humans, Male, Middle Aged, Neural Pathways diagnostic imaging, Neural Pathways pathology, Reproducibility of Results, White Matter diagnostic imaging, Brain pathology, Diffusion Magnetic Resonance Imaging methods, Parkinson Disease diagnostic imaging, Parkinson Disease pathology, White Matter pathology

Abstract

In this work, we propose a diffusion MRI protocol for mining Parkinson's disease diffusion MRI datasets and recover robust disease-specific biomarkers. Using advanced high angular resolution diffusion imaging (HARDI) crossing fiber modeling and tractography robust to partial volume effects, we automatically dissected 50 white matter (WM) fascicles. These fascicles connect deep nuclei (thalamus, putamen, pallidum) to different cortical functional areas (associative, motor, sensorimotor, limbic), basal forebrain and substantia nigra. Then, among these 50 candidate WM fascicles, only the ones that passed a test-retest reproducibility procedure qualified for further tractometry analysis. Leveraging the unique 2-timepoints test-retest Parkinson's Progression Markers Initiative (PPMI) dataset of over 600 subjects, we found statistically significant differences in tract profiles along the subcortico-cortical pathways between Parkinson's disease patients and healthy controls. In particular, significant increases in FA, apparent fiber density, tract-density and generalized FA were detected in some locations of the nigro-subthalamo-putaminal-thalamo-cortical pathway. This connection is one of the major motor circuits balancing the coordination of motor output. Detailed and quantifiable knowledge on WM fascicles in these areas is thus essential to improve the quality and outcome of Deep Brain Stimulation, and to target new WM locations for investigation.

Published

2017

3. Within-brain classification for brain tumor segmentation.

Author

Havaei M, Larochelle H, Poulin P, and Jodoin PM

Subjects

Humans, Machine Learning, Magnetic Resonance Imaging methods, Algorithms, Brain diagnostic imaging, Brain Neoplasms diagnostic imaging, Image Processing, Computer-Assisted methods

Abstract

Purpose: In this paper, we investigate a framework for interactive brain tumor segmentation which, at its core, treats the problem of interactive brain tumor segmentation as a machine learning problem., Methods: This method has an advantage over typical machine learning methods for this task where generalization is made across brains. The problem with these methods is that they need to deal with intensity bias correction and other MRI-specific noise. In this paper, we avoid these issues by approaching the problem as one of within brain generalization. Specifically, we propose a semi-automatic method that segments a brain tumor by training and generalizing within that brain only, based on some minimum user interaction., Conclusion: We investigate how adding spatial feature coordinates (i.e., i, j, k) to the intensity features can significantly improve the performance of different classification methods such as SVM, kNN and random forests. This would only be possible within an interactive framework. We also investigate the use of a more appropriate kernel and the adaptation of hyper-parameters specifically for each brain., Results: As a result of these experiments, we obtain an interactive method whose results reported on the MICCAI-BRATS 2013 dataset are the second most accurate compared to published methods, while using significantly less memory and processing power than most state-of-the-art methods.

Published

2016

4. A new compression format for fiber tracking datasets.

Author

Presseau C, Jodoin PM, Houde JC, and Descoteaux M

Subjects

Algorithms, Connectome, Humans, Brain anatomy & histology, Data Compression, Diffusion Magnetic Resonance Imaging methods, Diffusion Tensor Imaging methods, White Matter anatomy & histology

Abstract

A single diffusion MRI streamline fiber tracking dataset may contain hundreds of thousands, and often millions of streamlines and can take up to several gigabytes of memory. This amount of data is not only heavy to compute, but also difficult to visualize and hard to store on disk (especially when dealing with a collection of brains). These problems call for a fiber-specific compression format that simplifies its manipulation. As of today, no fiber compression format has yet been adopted and the need for it is now becoming an issue for future connectomics research. In this work, we propose a new compression format, .zfib, for streamline tractography datasets reconstructed from diffusion magnetic resonance imaging (dMRI). Tracts contain a large amount of redundant information and are relatively smooth. Hence, they are highly compressible. The proposed method is a processing pipeline containing a linearization, a quantization and an encoding step. Our pipeline is tested and validated under a wide range of DTI and HARDI tractography configurations (step size, streamline number, deterministic and probabilistic tracking) and compression options. Similar to JPEG, the user has one parameter to select: a worst-case maximum tolerance error in millimeter (mm). Overall, we find a compression factor of more than 96% for a maximum error of 0.1mm without any perceptual change or change of diffusion statistics (mean fractional anisotropy and mean diffusivity) along bundles. This opens new opportunities for connectomics and tractometry applications., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2015