Abstract
Conventional magnetic resonance imaging (cMRI) in multiple sclerosis (MS) patients provides measures of focal brain damage and activity, which are fundamental for disease diagnosis, prognosis, and the evaluation of response to therapy. However, cMRI is insensitive to the damage to the microenvironment of the brain tissue and the heterogeneity of MS lesions. In contrast, the damaged tissue can be characterized by mathematical models on multishell diffusion imaging data, which measure different compartmental water diffusion. In this work, we obtained 12 diffusion measures from eight diffusion models, and we applied a deep-learning attention-based convolutional neural network (CNN) (GAMER-MRI) to select the most discriminating measures in the classification of MS lesions and the perilesional tissue by attention weights. Furthermore, we provided clinical and biological validation of the chosen metrics—and of their most discriminative combinations—by correlating their respective mean values in MS patients with the corresponding Expanded Disability Status Scale (EDSS) and the serum level of neurofilament light chain (sNfL), which are measures of disability and neuroaxonal damage. Our results show that the neurite density index from neurite orientation and dispersion density imaging (NODDI), the measures of the intra-axonal and isotropic compartments from microstructural Bayesian approach, and the measure of the intra-axonal compartment from the spherical mean technique NODDI were the most discriminating (respective attention weights were 0.12, 0.12, 0.15, and 0.13). In addition, the combination of the neurite density index from NODDI and the measures for the intra-axonal and isotropic compartments from the microstructural Bayesian approach exhibited a stronger correlation with EDSS and sNfL than the individual measures. This work demonstrates that the proposed method might be useful to select the microstructural measures that are most discriminative of focal tissue damage and that may also be combined to a unique contrast to achieve stronger correlations to clinical disability and neuroaxonal damage.
Highlights
Conventional magnetic resonance imaging in multiple sclerosis (MS) plays a major role in MS diagnosis, prognosis, and in the evaluation of patients’ therapeutic response (Rovira et al, 2015; Wattjes et al, 2015)
In this study, we have explored the relationship between the chosen measures, or their combinations, with the Expanded Disability Status Scale (EDSS) and the neurofilament light chain in the serum, which are respectively (i) a clinical measure of disability in MS patients and (ii) a biological measure of neuroaxonal damage (Barro et al, 2018; Siller et al, 2019)
The significance controlled by false discovery rate (FDR) is indicated by an asterisk
Summary
Conventional magnetic resonance imaging (cMRI) in multiple sclerosis (MS) plays a major role in MS diagnosis, prognosis, and in the evaluation of patients’ therapeutic response (Rovira et al, 2015; Wattjes et al, 2015). MDWI measures signal changes that are related to the diffusion of water molecules within central nervous system (CNS) tissue (Novikov et al, 2019; Lakhani et al, 2020), which is constrained by the local microenvironment (Novikov et al, 2019) This enables diffusion measures of biophysical microstructure models derived from mDWI to decode the information specific to different water compartments (e.g., intra-axonal and isotropic compartments) within the CNS tissue (Novikov et al, 2019). These two compartments can describe the two pathological presentations of MS lesions, demyelination, and axonal injury and are commonly modeled by various biophysical microstructure models (Lakhani et al, 2020)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
