Mapping fNIRS to fMRI with Neural Data Augmentation and Machine Learning
Models
- URL: http://arxiv.org/abs/2206.06486v1
- Date: Mon, 13 Jun 2022 21:32:30 GMT
- Title: Mapping fNIRS to fMRI with Neural Data Augmentation and Machine Learning
Models
- Authors: Jihyun Hur, Jaeyeong Yang, Hoyoung Doh, Woo-Young Ahn
- Abstract summary: Functional magnetic resonance imaging (fMRI) is the most popular and widely used neuroimaging technique.
There is growing interest in fMRI-based markers of individual differences.
We used machine learning models and data augmentation to predict fMRI markers of human cognition.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Advances in neuroimaging techniques have provided us novel insights into
understanding how the human mind works. Functional magnetic resonance imaging
(fMRI) is the most popular and widely used neuroimaging technique, and there is
growing interest in fMRI-based markers of individual differences. However, its
utility is often limited due to its high cost and difficulty acquiring from
specific populations, including children and infants. Surrogate markers, or
neural correlates of fMRI markers, would have important practical implications,
but we have few stand-alone predictors for the fMRI markers. Here, using
machine learning (ML) models and data augmentation, we predicted well-validated
fMRI markers of human cognition from multivariate patterns of functional
near-infrared spectroscopy (fNIRS), a portable and relatively inexpensive
optical neuroimaging technique. We recruited 50 human participants who
performed two cognitive tasks (stop signal task and probabilistic reversal
learning task), while neural activation was measured with either fNIRS or fMRI
at each of the total two visits. Using ML models and data augmentation, we
could predict the well-established fMRI markers of response inhibition or
prediction error signals from 48-channel fNIRS activation in the prefrontal
cortex. These results suggest that fNIRS might offer a surrogate marker of fMRI
activation, which would broaden our understanding of various populations,
including infants.
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