GLACIER: GLASS-BOX TRANSFORMER FOR INTERPRETABLE DYNAMIC NEUROIMAGING.

Proceedings of the ... IEEE International Conference on Acoustics, Speech, and Signal Processing. ICASSP (Conference) Pub Date : 2023-06-01 Epub Date: 2023-05-05 DOI:10.1109/icassp49357.2023.10097126

Usman Mahmood, Zening Fu, Vince Calhoun, Sergey Plis

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Abstract

Deep learning models can perform as well or better than humans in many tasks, especially vision related. Almost exclusively, these models are used to perform classification or prediction. However, deep learning models are usually of black-box nature, and it is often difficult to interpret the model or the features. The lack of interpretability causes a restrain from applying deep learning to fields such as neuroimaging, where the results must be transparent, and interpretable. Therefore, we present a 'glass-box' deep learning model and apply it to the field of neuroimaging. Our model mixes spatial and temporal dimensions in succession to estimate dynamic connectivity between the brain's intrinsic networks. The interpretable connectivity matrices produced by our model result in beating state-of-the-art models on many tasks using multiple functional MRI datasets. More importantly, our model estimates task-based flexible connectivity matrices, unlike static methods such as Pearson's correlation coefficients.

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冰川：用于可解释动态神经成像的玻璃盒转换器。

深度学习模型可以在许多任务中，尤其是与视觉相关的任务中，表现得与人类一样好，甚至更好。这些模型几乎都用于进行分类或预测。然而，深度学习模型通常是黑箱性质的，通常很难解释模型或特征。由于缺乏可解释性，深度学习在神经成像等领域的应用受到限制，因为这些领域的结果必须是透明和可解释的。因此，我们提出了一个 "玻璃箱 "深度学习模型，并将其应用于神经成像领域。我们的模型连续混合了空间和时间维度，以估算大脑固有网络之间的动态连接性。我们的模型产生的可解释连通性矩阵在使用多个功能性核磁共振成像数据集的许多任务中战胜了最先进的模型。更重要的是，与皮尔逊相关系数等静态方法不同，我们的模型能估算出基于任务的灵活连接矩阵。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the ... IEEE International Conference on Acoustics, Speech, and Signal Processing. ICASSP (Conference)

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