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A simulation-driven supervised learning framework to estimate brain microstructure using diffusion MRI.

Chengran Fang1, Zheyi Yang2, Demian Wassermann3

  • 1INRIA Saclay, Equipe IDEFIX, UMA, ENSTA Paris, 828, Boulevard des Maréchaux, 91762 Palaiseau, France; INRIA Saclay, Equipe MIND, 1 Rue Honoré d'Estienne d'Orves, 91120 Palaiseau, France.

Medical Image Analysis
|October 12, 2023
PubMed
Summary
This summary is machine-generated.

We developed a framework using synthetic data to estimate brain microstructure from diffusion MRI. This approach shows promising results for in-vivo imaging and provides valuable data for future research.

Keywords:
Bloch–Torrey equationDiffusion magnetic resonance imagingFinite elementsMachine learningMatrix formalismNeuron modelingSupervised learningdMRI

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Area of Science:

  • Neuroimaging
  • Computational Neuroscience
  • Biophysics

Background:

  • Diffusion magnetic resonance imaging (dMRI) is crucial for non-invasively probing brain microstructure.
  • Estimating tissue microstructure parameters from dMRI signals is challenging due to complex signal variations.
  • Current methods often require extensive validation and may lack diffusion time independence.

Purpose of the Study:

  • To introduce a novel framework for training supervised learning models on synthetic dMRI data.
  • To generate a comprehensive synthetic dataset for microstructure estimation.
  • To validate the framework's ability to estimate key microstructural parameters with diffusion time independence.

Main Methods:

  • Generated synthetic dMRI signals from over 1,000 digital neuronal reconstructions using an optimized simulator.
  • Created a large synthetic dataset (1.45 million voxels) with 40 microstructure parameters by combining simulated neuron signals and free diffusion.
  • Trained multilayer perceptrons (MLPs) on the synthetic data to estimate volume and area fractions of cellular components.

Main Results:

  • Trained MLPs demonstrated satisfactory performance on synthetic test data.
  • The framework produced promising in-vivo parameter maps on the MGH Connectome Diffusion Microstructure Dataset (CDMD).
  • Estimated volume fractions exhibited low dependence on diffusion time, a key characteristic for quantitative imaging.

Conclusions:

  • The proposed framework offers a robust method for microstructure estimation using supervised learning on synthetic dMRI data.
  • The generated synthetic dataset and neuron models are valuable resources for validating dMRI microstructure mapping techniques.
  • This approach advances quantitative microstructure imaging by providing diffusion time-independent parameter estimates.