Robust Brain State Decoding using Bidirectional Long Short Term Memory Networks in functional MRI

Decoding brain states of the underlying cognitive processes via learning discriminative feature representations has recently gained a lot of interest in brain imaging studies. Particularly, there has been an impetus to encode the dynamics of brain functioning by analyzing temporal information available in the fMRI data. Long-short term memory (LSTM), a class of machine learning model possessing a "memory" component, to retain previously seen temporal information, is increasingly being observed to perform well in various applications with dynamic temporal behavior, including brain state decoding. Because of the dynamics and inherent latency in fMRI BOLD responses, future temporal context is crucial. However, it is neither encoded nor captured by the conventional LSTM model. This paper performs robust brain state decoding via information encapsulation from both the past and future instances of fMRI data via bi-directional LSTM. This allows for explicitly modeling the dynamics of BOLD response without any delay adjustment. To this end, we utilize a bidirectional LSTM, wherein, the input sequence is fed in normal time-order for one LSTM network, and in the reverse time-order, for another. The two hidden activations of forward and reverse directions in bi-LSTM are collated to build the "memory" of the model and are used to robustly predict the brain states at every time instance. Working memory data from the Human Connectome Project (HCP) is utilized for validation and was observed to perform 18% better than it's unidirectional counterpart in terms of accuracy in predicting the brain states.

[1]  Russell A. Poldrack,et al.  Deconvolving BOLD activation in event-related designs for multivoxel pattern classification analyses , 2012, NeuroImage.

[2]  Mark Jenkinson,et al.  The minimal preprocessing pipelines for the Human Connectome Project , 2013, NeuroImage.

[3]  D. V. von Cramon,et al.  Temporal properties of the hemodynamic response in functional MRI , 1999, Human brain mapping.

[4]  Benjamin J. Tamber-Rosenau,et al.  Decoding cognitive control in human parietal cortex , 2009, Proceedings of the National Academy of Sciences.

[5]  Jesper Andersson,et al.  A multi-modal parcellation of human cerebral cortex , 2016, Nature.

[6]  Jean-Baptiste Poline,et al.  Inferring behavior from functional brain images , 1998, Nature Neuroscience.

[7]  R. Poldrack Inferring Mental States from Neuroimaging Data: From Reverse Inference to Large-Scale Decoding , 2011, Neuron.

[8]  Vince D. Calhoun,et al.  Task-specific feature extraction and classification of fMRI volumes using a deep neural network initialized with a deep belief network: Evaluation using sensorimotor tasks , 2017, NeuroImage.

[9]  F Kruggel,et al.  Modeling the hemodynamic response in single‐trial functional MRI experiments , 1999, Magnetic resonance in medicine.

[10]  David D. Cox,et al.  Functional magnetic resonance imaging (fMRI) “brain reading”: detecting and classifying distributed patterns of fMRI activity in human visual cortex , 2003, NeuroImage.

[11]  G. Rees,et al.  Neuroimaging: Decoding mental states from brain activity in humans , 2006, Nature Reviews Neuroscience.

[12]  Ron Kohavi,et al.  A Study of Cross-Validation and Bootstrap for Accuracy Estimation and Model Selection , 1995, IJCAI.

[13]  Yong Fan,et al.  Brain Decoding from Functional MRI Using Long Short-Term Memory Recurrent Neural Networks , 2018, MICCAI.

[14]  Gaël Varoquaux,et al.  Scikit-learn: Machine Learning in Python , 2011, J. Mach. Learn. Res..

[15]  Klaus-Robert Müller,et al.  Introduction to machine learning for brain imaging , 2011, NeuroImage.

[16]  Joseph JáJá,et al.  Brain dynamics and temporal trajectories during task and naturalistic processing , 2018, NeuroImage.

[17]  R W Cox,et al.  AFNI: software for analysis and visualization of functional magnetic resonance neuroimages. , 1996, Computers and biomedical research, an international journal.

[18]  E. DeYoe,et al.  Analysis and use of FMRI response delays , 2001, Human brain mapping.

[19]  Ronald J. Williams,et al.  A Learning Algorithm for Continually Running Fully Recurrent Neural Networks , 1989, Neural Computation.

[20]  Dennis J. McFarland,et al.  Brain–computer interfaces for communication and control , 2002, Clinical Neurophysiology.

[21]  A. Ishai,et al.  Distributed and Overlapping Representations of Faces and Objects in Ventral Temporal Cortex , 2001, Science.

[22]  J. -B. Poline,et al.  Estimating the Delay of the fMRI Response , 2002, NeuroImage.

[23]  Priya Aggarwal,et al.  Multivariate brain network graph identification in functional MRI , 2017, Medical Image Anal..

[24]  Priya Aggarwal,et al.  Group-fused multivariate regression modeling for group-level brain networks , 2019, Neurocomputing.

[25]  Kuldip K. Paliwal,et al.  Bidirectional recurrent neural networks , 1997, IEEE Trans. Signal Process..

[26]  R. Buxton,et al.  Dynamics of blood flow and oxygenation changes during brain activation: The balloon model , 1998, Magnetic resonance in medicine.

[27]  Herbert Jaeger,et al.  The''echo state''approach to analysing and training recurrent neural networks , 2001 .

[28]  Priya Aggarwal,et al.  Multivariate graph learning for detecting aberrant connectivity of dynamic brain networks in autism , 2019, Medical Image Anal..

[29]  Priya Aggarwal,et al.  Joint estimation of activity signal and HRF in fMRI using fused LASSO , 2015, 2015 IEEE Global Conference on Signal and Information Processing (GlobalSIP).