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Is Granger causality a viable technique for analyzing fMRI data?格兰杰因果关系分析技术是否可用于 fMRI 数据分析?
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Granger causality analysis of fMRI BOLD signals is invariant to hemodynamic convolution but not downsampling.功能磁共振成像(fMRI)BOLD 信号的格兰杰因果分析不受血流动力学卷积影响,但受下采样影响。
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用于从功能磁共振成像推断刺激诱发的亚100毫秒时间差异的动态格兰杰因果关系的实验验证

Experimental Validation of Dynamic Granger Causality for Inferring Stimulus-Evoked Sub-100 ms Timing Differences from fMRI.

作者信息

Wang Yunzhi, Katwal Santosh, Rogers Baxter, Gore John, Deshpande Gopikrishna

出版信息

IEEE Trans Neural Syst Rehabil Eng. 2017 Jun;25(6):539-546. doi: 10.1109/TNSRE.2016.2593655. Epub 2016 Jul 20.

DOI:10.1109/TNSRE.2016.2593655
PMID:27448367
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5570592/
Abstract

Decoding the sequential flow of events in the human brain non-invasively is critical for gaining a mechanistic understanding of brain function. In this study, we propose a method based on dynamic Granger causality analysis to measure timing differences in brain responses from fMRI. We experimentally validate this method by detecting sub-100 ms timing differences in fMRI responses obtained from bilateral visual cortex using fast sampling, ultra-high field and an event-related visual hemifield paradigm with known timing difference between the hemifields. Classical Granger causality was previously shown to be able to detect sub-100 ms timing differences in the visual cortex. Since classical Granger causality does not differentiate between spontaneous and stimulus-evoked responses, dynamic Granger causality has been proposed as an alternative, thereby necessitating its experimental validation. In addition to detecting timing differences as low as 28 ms using dynamic Granger causality, the significance of the inference from our method increased with increasing delay both in simulations and experimental data. Therefore, it provides a methodology for understanding mental chronometry from fMRI in a data-driven way.

摘要

非侵入性地解码人类大脑中事件的顺序流对于深入理解大脑功能的机制至关重要。在本研究中,我们提出了一种基于动态格兰杰因果分析的方法,用于测量功能磁共振成像(fMRI)中大脑反应的时间差异。我们通过使用快速采样、超高场以及具有已知半视野时间差异的事件相关视觉半视野范式,从双侧视觉皮层获得fMRI反应,检测低于100毫秒的时间差异,对该方法进行了实验验证。先前已证明经典格兰杰因果关系能够检测视觉皮层中低于100毫秒的时间差异。由于经典格兰杰因果关系无法区分自发反应和刺激诱发反应,因此提出了动态格兰杰因果关系作为替代方法,从而需要对其进行实验验证。除了使用动态格兰杰因果关系检测低至28毫秒的时间差异外,在模拟和实验数据中,我们方法推断的显著性都随着延迟的增加而增加。因此,它提供了一种以数据驱动的方式从fMRI理解心理时间测量的方法。