用于研究神经精神疾病的成像-基因组空间-模态注意融合。

IF 3.5 2区 医学 Q1 NEUROIMAGING
Md Abdur Rahaman, Yash Garg, Armin Iraji, Zening Fu, Peter Kochunov, L. Elliot Hong, Theo G. M. Van Erp, Adrian Preda, Jiayu Chen, Vince Calhoun
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引用次数: 0

摘要

多模态学习已成为一种强大的技术,可利用不同的数据源来增强学习和决策过程。将这种方法用于分析从不同生物领域收集到的数据是非常直观的,尤其是在研究神经精神疾病时。像精神分裂症(SZ)这样复杂的神经精神疾病会影响大脑和生物的多个方面。这些生物来源各自呈现出受试者潜在生理过程的不同但又相互关联的表现形式。从这些数据源中进行联合学习可以提高我们对该疾病的理解。然而,由于以下几个原因,将这些生物来源结合起来具有挑战性:(i) 观察结果具有特定领域,导致数据在不同的子空间中表示;(ii) 融合后的数据通常具有噪声和高维性,使得识别相关信息具有挑战性。为了应对这些挑战,我们提出了一种多模态人工智能模型,该模型具有一个新颖的融合模块,其灵感来自瓶颈注意力模块。我们使用深度神经网络来学习输入流的潜在空间表示。接下来,我们引入一个二维(空间-模态)注意力模块来调节 SZ 分类的中间融合。我们通过扩张卷积神经网络实现空间注意力,该网络可创建大型感受野以提取重要的上下文模式。由此产生的联合学习框架最大限度地提高了互补性,使我们能够探索模态之间的对应关系。我们在多模态成像遗传数据集上测试了我们的模型,SZ 预测准确率达到 94.10%(p
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Imaging-genomic spatial-modality attentive fusion for studying neuropsychiatric disorders

Imaging-genomic spatial-modality attentive fusion for studying neuropsychiatric disorders

Multimodal learning has emerged as a powerful technique that leverages diverse data sources to enhance learning and decision-making processes. Adapting this approach to analyzing data collected from different biological domains is intuitive, especially for studying neuropsychiatric disorders. A complex neuropsychiatric disorder like schizophrenia (SZ) can affect multiple aspects of the brain and biologies. These biological sources each present distinct yet correlated expressions of subjects' underlying physiological processes. Joint learning from these data sources can improve our understanding of the disorder. However, combining these biological sources is challenging for several reasons: (i) observations are domain specific, leading to data being represented in dissimilar subspaces, and (ii) fused data are often noisy and high-dimensional, making it challenging to identify relevant information. To address these challenges, we propose a multimodal artificial intelligence model with a novel fusion module inspired by a bottleneck attention module. We use deep neural networks to learn latent space representations of the input streams. Next, we introduce a two-dimensional (spatio-modality) attention module to regulate the intermediate fusion for SZ classification. We implement spatial attention via a dilated convolutional neural network that creates large receptive fields for extracting significant contextual patterns. The resulting joint learning framework maximizes complementarity allowing us to explore the correspondence among the modalities. We test our model on a multimodal imaging-genetic dataset and achieve an SZ prediction accuracy of 94.10% (p < .0001), outperforming state-of-the-art unimodal and multimodal models for the task. Moreover, the model provides inherent interpretability that helps identify concepts significant for the neural network's decision and explains the underlying physiopathology of the disorder. Results also show that functional connectivity among subcortical, sensorimotor, and cognitive control domains plays an important role in characterizing SZ. Analysis of the spatio-modality attention scores suggests that structural components like the supplementary motor area, caudate, and insula play a significant role in SZ. Biclustering the attention scores discover a multimodal cluster that includes genes CSMD1, ATK3, MOB4, and HSPE1, all of which have been identified as relevant to SZ. In summary, feature attribution appears to be especially useful for probing the transient and confined but decisive patterns of complex disorders, and it shows promise for extensive applicability in future studies.

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来源期刊
Human Brain Mapping
Human Brain Mapping 医学-核医学
CiteScore
8.30
自引率
6.20%
发文量
401
审稿时长
3-6 weeks
期刊介绍: Human Brain Mapping publishes peer-reviewed basic, clinical, technical, and theoretical research in the interdisciplinary and rapidly expanding field of human brain mapping. The journal features research derived from non-invasive brain imaging modalities used to explore the spatial and temporal organization of the neural systems supporting human behavior. Imaging modalities of interest include positron emission tomography, event-related potentials, electro-and magnetoencephalography, magnetic resonance imaging, and single-photon emission tomography. Brain mapping research in both normal and clinical populations is encouraged. Article formats include Research Articles, Review Articles, Clinical Case Studies, and Technique, as well as Technological Developments, Theoretical Articles, and Synthetic Reviews. Technical advances, such as novel brain imaging methods, analyses for detecting or localizing neural activity, synergistic uses of multiple imaging modalities, and strategies for the design of behavioral paradigms and neural-systems modeling are of particular interest. The journal endorses the propagation of methodological standards and encourages database development in the field of human brain mapping.
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