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BLENDS: Augmentation of Functional Magnetic Resonance Images for Machine Learning Using Anatomically Constrained

Kevin P Nguyen1, Vyom Raval1,2, Abu Minhajuddin3

  • 1Lyda Hill Department of Bioinformatics, University of Texas Southwestern Medical Center, Dallas, Texas, USA.

Brain Connectivity
|September 13, 2022
PubMed
Summary
This summary is machine-generated.

Data augmentation using the new BLENDS method synthesizes realistic four-dimensional (4D) neuroimaging data, significantly improving deep learning model accuracy for predicting antidepressant response and Parkinson's disease progression.

Keywords:
data augmentationdeep learningfMRImachine learningsimulation

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Area of Science:

  • Neuroimaging
  • Deep Learning
  • Medical Image Analysis

Background:

  • Data augmentation is crucial for deep learning models with limited training data.
  • Existing methods for synthesizing four-dimensional (4D) neuroimaging data, like functional magnetic resonance imaging (fMRI), are limited.
  • There is a need for validated augmentation techniques to create anatomically realistic 4D fMRI data.

Purpose of the Study:

  • To propose and validate a novel data augmentation method for synthesizing realistic 4D fMRI images.
  • To enhance the performance of deep learning models in neuroimaging tasks by addressing data scarcity.
  • To improve the accuracy of predictive models for clinical applications in neurology.

Main Methods:

  • Introduced Brain Library Enrichment through Nonlinear Deformation Synthesis (BLENDS), a new augmentation method.
  • BLENDS generates new nonlinear warp fields by spatially blending intersubject coregistration maps.
  • Applied generated warp fields to existing 4D fMRI data to create augmented datasets.

Main Results:

  • BLENDS successfully generated hundreds of new fMRI images with unique anatomical variations.
  • Augmentation significantly improved prediction performance in two neuroimaging tasks.
  • For antidepressant response prediction, R-squared increased from 0.055 to 0.103 with 10x augmentation.
  • For Parkinson's disease trajectory prediction, R-squared improved from -0.044 to 0.472 with 10x augmentation.

Conclusions:

  • The BLENDS method effectively augments fMRI data through nonlinear transformations.
  • This augmentation significantly enhances deep learning model performance on clinically relevant predictive tasks.
  • BLENDS offers a valuable tool for neuroimaging researchers to overcome data limitations and build more accurate predictive models.