Enhancing Fiber Orientation Distributions using convolutional Neural Networks

TL;DR

This paper develops convolutional neural network models to improve fiber orientation distribution estimation from single-shell diffusion MRI data, enabling faster scans and better clinical applicability.

Contribution

It introduces CNN-based methods, specifically U-Net and HighResNet architectures, to regress multi-shell FODs from single-shell data, addressing acquisition limitations.

Findings

CNN models accurately predict multi-shell FODs from single-shell data.

Models generalize across different datasets and acquisition protocols.

The approach reduces scan time while maintaining FOD estimation quality.

Abstract

Accurate local fiber orientation distribution (FOD) modeling based on diffusion magnetic resonance imaging (dMRI) capable of resolving complex fiber configurations benefits from specific acquisition protocols that sample a high number of gradient directions (b-vecs), a high maximum b-value(b-vals), and multiple b-values (multi-shell). However, acquisition time is limited in a clinical setting and commercial scanners may not provide such dMRI sequences. Therefore, dMRI is often acquired as single-shell (single b-value). In this work, we learn improved FODs for commercially acquired MRI. We evaluate patch-based 3D convolutional neural networks (CNNs)on their ability to regress multi-shell FOD representations from single-shell representations, where the representation is a spherical harmonics obtained from constrained spherical deconvolution (CSD) to model FODs. We evaluate U-Net and HighResNet 3D CNN architectures on data from the Human Connectome Project and an in-house dataset. We evaluate how well each CNN model can resolve local fiber orientation 1) when training and testing on datasets with the same dMRI acquisition protocol; 2) when testing on a dataset with a different dMRI acquisition protocol than used to train the CNN models; and 3) when testing on a dataset with a fewer number of gradient directions than used to train the CNN models. Our approach may enable robust CSD model estimation on single-shell dMRI acquisition protocols with few gradient directions, reducing acquisition times, facilitating translation of improved FOD estimation to time-limited clinical environments.