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

Anant Mittal, Priya Aggarwal, Luiz Pessoa, Anubha Gupta
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Abstract

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.

Abstract Image

Abstract Image

利用功能性核磁共振成像中的双向长短期记忆网络进行稳健的大脑状态解码
通过学习辨别特征表征来解码潜在认知过程的大脑状态最近在脑成像研究中获得了广泛关注。特别是,通过分析 fMRI 数据中的时间信息来编码大脑功能的动态变化已成为一种推动力。长短期记忆(LSTM)是一类具有 "记忆 "成分的机器学习模型,可以保留以前看到的时间信息,越来越多的人观察到它在各种具有动态时间行为的应用中表现出色,包括大脑状态解码。由于 fMRI BOLD 反应的动态性和固有延迟性,未来的时间背景至关重要。然而,传统的 LSTM 模型既不能对其进行编码,也不能捕捉到它。本文通过双向 LSTM 对过去和未来的 fMRI 数据实例进行信息封装,从而实现稳健的大脑状态解码。这样就能明确地模拟 BOLD 响应的动态变化,而无需进行任何延迟调整。为此,我们使用了双向 LSTM,其中一个 LSTM 网络按正常时序输入输入序列,而另一个 LSTM 网络则按相反时序输入输入序列。在双向 LSTM 中,正向和反向的两个隐藏激活将被整理以建立模型的 "记忆",并用于稳健地预测每个时间实例的大脑状态。来自人类连接组项目(HCP)的工作记忆数据被用来进行验证,结果显示,在预测大脑状态的准确性方面,它比单向模型高出 18%。
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