AmygdalaGo-BOLT3D: A boundary learning transformer for tracing human amygdala

Bo Dong, Quan Zhou, Peng Gao, Wei Jintao, Jiale Xiao, Wei Wang, Peipeng Liang, Danhua Lin, Hongjian He, Xi-Nian Zuo
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Abstract

Automated amygdala segmentation is one of the most common tasks in human neuroscience research. However, due to the small volume of the human amygdala, especially in developing brains, the precision and consistency of the segmentation results are often affected by individual differences and inconsistencies in data distribution. To address these challenges, we propose an algorithm for learning boundary contrast of 427 manually traced amygdalae in children and adolescents to generate a transformer, AmygdalaGo-BOLT3D, for automatic segmentation of human amygdala. This method focuses on the boundary to effectively address the issue of false positive recognition and inaccurate edges due to small amygdala volume. Firstly, AmygdalaGo-BOLT3D develops a basic architecture for an adaptive cooperation network with multiple granularities. Secondly, AmygdalaGo-BOLT3D builds the self-attention-based consistency module to address generalizability problems arising from individual differences and inconsistent data distributions. Third, AmygdalaGo-BOLT3D adapts the original sample-mask model for the amygdala scene, which consists of three parts, namely a lightweight volumetric feature encoder, a 3D cue encoder, and a volume mask decoder, to improve the generalized segmentation of the model. Finally, AmygdalaGo-BOLT3D implements a boundary contrastive learning framework that utilizes the interaction mechanism between a prior cue and the embedded magnetic resonance images to achieve effective integration between the two. Experimental results demonstrate that predictions of the overall structure and boundaries of the human amygdala exhibit highly improved precision and help maintain stability in multiple age groups and imaging centers. This verifies the stability and generalization of the algorithm designed for multiple tasks. AmygdalaGo-BOLT3D has been deployed for the community (GITHUB\_LINK) to provide an open science foundation for its applications in population neuroscience.
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AmygdalaGo-BOLT3D:用于追踪人类杏仁核的边界学习转换器
杏仁核自动分割是人类神经科学研究中最常见的任务之一。然而,由于人类杏仁核体积小,尤其是发育中的大脑,分割结果的精确性和一致性往往受到个体差异和数据分布不一致的影响。为了应对这些挑战,我们提出了一种算法,用于学习 427 个人工追踪的儿童和青少年杏仁核的边界对比,从而生成一个转换器 AmygdalaGo-BOLT3D,用于人类杏仁核的自动分割。该方法以边界为重点,有效解决了杏仁核体积小导致的假阳性识别和边缘不准确的问题。首先,AmygdalaGo-BOLT3D 开发了多粒度自适应合作网络的基本架构。其次,AmygdalaGo-BOLT3D 建立了基于自我注意的一致性模块,以解决因个体差异和数据分布不一致而产生的普适性问题。第三,AmygdalaGo-BOLT3D 对原有的杏仁核场景样本掩码模型进行了调整,该模型由三部分组成,即轻量级体积特征编码器、三维线索编码器和体积掩码解码器,以提高模型的泛化分割能力。最后,AmygdalaGo-BOLT3D 实现了边界对比学习框架,利用先验线索与嵌入式磁共振图像之间的交互机制,实现两者之间的有效整合。实验结果表明,对人类杏仁核整体结构和边界的预测显示出高度的精确性,并有助于在多个年龄组和成像中心保持稳定。这验证了针对多种任务设计的算法的稳定性和通用性。AmygdalaGo-BOLT3D已经部署到社区(GITHUB/_LINK),为其在群体神经科学中的应用提供了一个开放的科学基础。
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