Causal inference of brain connectivity from fMRI with $\psi$-Learning
Incorporated Linear non-Gaussian Acyclic Model ($\psi$-LiNGAM)
- URL: http://arxiv.org/abs/2006.09536v1
- Date: Tue, 16 Jun 2020 21:56:40 GMT
- Title: Causal inference of brain connectivity from fMRI with $\psi$-Learning
Incorporated Linear non-Gaussian Acyclic Model ($\psi$-LiNGAM)
- Authors: Aiying Zhang, Gemeng Zhang, Biao Cai, Wenxing Hu, Li Xiao, Tony W.
Wilson, Julia M. Stephen, Vince D. Calhoun and Yu-Ping Wang
- Abstract summary: We propose a $psi$-learning incorporated a linear non-Gaussian acyclic model ($psi$-LiNGAM) to facilitate causal inferences.
We use the association model ($psi$-learning) to facilitate causal inferences and the model works well especially for high-dimensional cases.
- Score: 27.32225635737671
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Functional connectivity (FC) has become a primary means of understanding
brain functions by identifying brain network interactions and, ultimately, how
those interactions produce cognitions. A popular definition of FC is by
statistical associations between measured brain regions. However, this could be
problematic since the associations can only provide spatial connections but not
causal interactions among regions of interests. Hence, it is necessary to study
their causal relationship. Directed acyclic graph (DAG) models have been
applied in recent FC studies but often encountered problems such as limited
sample sizes and large number of variables (namely high-dimensional problems),
which lead to both computational difficulty and convergence issues. As a
result, the use of DAG models is problematic, where the identification of DAG
models in general is nondeterministic polynomial time hard (NP-hard). To this
end, we propose a $\psi$-learning incorporated linear non-Gaussian acyclic
model ($\psi$-LiNGAM). We use the association model ($\psi$-learning) to
facilitate causal inferences and the model works well especially for
high-dimensional cases. Our simulation results demonstrate that the proposed
method is more robust and accurate than several existing ones in detecting
graph structure and direction. We then applied it to the resting state fMRI
(rsfMRI) data obtained from the publicly available Philadelphia
Neurodevelopmental Cohort (PNC) to study the cognitive variance, which includes
855 individuals aged 8-22 years. Therein, we have identified three types of hub
structure: the in-hub, out-hub and sum-hub, which correspond to the centers of
receiving, sending and relaying information, respectively. We also detected 16
most important pairs of causal flows. Several of the results have been verified
to be biologically significant.
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