This repository contains a PyTorch implementation of the paper:
Change Towards optimal sampling in diffusion MRI for accelerated fiber tractography.
Tomer Weiss (tomer196@gmail.com), Ortal Senouf, Sanketh Vedula, Oleg Michailovich, Michael Zibulevsky, Alex Bronstein
Tractography is an important tool in neuroscience that enables reconstructing 3D structure of the white matter. Tractograhpy algorithms use diffusion-weighted Magnetic Resonance Imaging (DWI or dMRI), DWI data contains multiple volumes acquired with different diffusion gradient directions. The prohibitively long acquisition time needed for acquiring multiple diffusion directions limits the resolution and its practical use in clinical setting. In this work, we propose an algorithm to simultaneously learn the diffusion directions with the reconstruction model. We demonstrate that the learned directions, together with the reconstruction network, lead to further improvements on the obtained tractography. We conduct a thorough quantitative study on the data obtained from the human connectome project using a variety of metrics to objectively evaluate the obtained tractography. Although using neural network for reconstruction is a powerful tool it is not yet accepted as a valid tool in many applications, we claim that our learned directions can deployed and used directly even without neural network reconstruction. We showed that this approch can also lead to sizeable improvements in the tractography; we also showed that our sampling patterns generalize to datasets outside of the human connectome project.
This repo contains the codes to replicate our experiment for reconstruction.
Learned directions for few acceleration factors aviliable in bvecs/
folder.
To install other requirements through $ pip install -r requirements.txt
.
First you should download the Diffusion Preprocessed datset from the Humman Connectome Project (HCP) HCP pre-process the dataset by running (first update the location of the downloaded dataset in the file):
python data/create_dataset.py
See 'exp.py' for basic use.
Please cite our work if you find this approach useful in your research:
@ARTICLE{2020arXiv200903008W,
author = {{Weiss}, Tomer and {Vedula}, Sanketh and {Senouf}, Ortal and
{Michailovich}, Oleg and {AlexBronstein}},
title = "{Towards learned optimal q-space sampling in diffusion MRI}",
journal = {arXiv e-prints},
year = 2020,
eprint = {2009.03008},
}