Parameter estimation for WMTI-Watson model of white matter using encoder-decoder recurrent neural network

TL;DR

This paper introduces an encoder-decoder RNN approach for estimating white matter microstructural parameters from diffusion MRI, offering faster, more robust, and adaptable results compared to traditional methods.

Contribution

It presents a novel RNN-based solver for the WMTI-Watson model that improves speed, robustness, and transferability over existing nonlinear and neural network methods.

Findings

RNN method reduces computation time from hours to seconds

Achieves similar accuracy and precision as NLLS

Demonstrates superior robustness and transferability

Abstract

Biophysical modelling of the diffusion MRI signal provides estimates of specific microstructural tissue properties. Although nonlinear optimization such as non-linear least squares (NLLS) is the most widespread method for model estimation, it suffers from local minima and high computational cost. Deep Learning approaches are steadily replacing NL fitting, but come with the limitation that the model needs to be retrained for each acquisition protocol and noise level. The White Matter Tract Integrity (WMTI)-Watson model was proposed as an implementation of the Standard Model of diffusion in white matter that estimates model parameters from the diffusion and kurtosis tensors (DKI). Here we proposed a deep learning approach based on the encoder-decoder recurrent neural network (RNN) to increase the robustness and accelerate the parameter estimation of WMTI-Watson. We use an embedding approach to render the model insensitive to potential differences in distributions between training data and experimental data. This RNN-based solver thus has the advantage of being highly efficient in computation and more readily translatable to other datasets, irrespective of acquisition protocol and underlying parameter distributions as long as DKI was pre-computed from the data. In this study, we evaluated the performance of NLLS, the RNN-based method and a multilayer perceptron (MLP) on synthetic and in vivo datasets of rat and human brain. We showed that the proposed RNN-based fitting approach had the advantage of highly reduced computation time over NLLS (from hours to seconds), with similar accuracy and precision but improved robustness, and superior translatability to new datasets over MLP.