计算机科学
人工智能
空间分析
计算机视觉
模式识别(心理学)
方向(向量空间)
特征(语言学)
地标
桥接(联网)
破译
可视化
图像分辨率
领域(数学分析)
空间智能
空间生态学
弹道
计算模型
深度学习
黄色粘球菌
鉴定(生物学)
代表(政治)
交叉口(航空)
距离变换
合并(版本控制)
空间语境意识
跟踪(教育)
空间组织
杠杆(统计)
作者
Bingjie Dai,Litai Yi,Peng Wang,Hanshuang Li,Pengwei Hu,Yancheng Song,Jixiang Xing,Zhenxing Feng,Zhiyuan Yuan,Yongchun Zuo
标识
DOI:10.1038/s41592-026-03034-9
摘要
The rapid advancement of spatial multi-omics technologies has unveiled opportunities for deciphering the intricate spatial heterogeneity; however, current computational approaches struggle to comprehensively integrate diverse molecular and spatial information. Here we propose 3d-OT, a deep geometry-aware framework that leverages spatial geometric and multi-omics information for feature extraction, spatial domains identification and heterogeneous slices alignment. 3d-OT utilizes modality fusion representation to align spatial slices, bridging the gap in spatial multi-omics alignment methods. Meanwhile, we handle nonrigid deformations in heterogeneous slice alignment through soft correspondence optimal transport, and the chamfer distance is introduced to quantify its performance. 3d-OT outperforms existing methods in capturing anatomical details of mouse brain cortex layers and tracking nonrigid deformations of heart and neural crest tissues at different resolutions. Finally, we construct the 3D spatiotemporal trajectory of mouse embryonic development. Overall, 3d-OT enables comprehensive understanding of existing spatial multi-omics data, offering a powerful computational tool to decipher the spatial complexity of biological tissues.
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