Advanced Cross-Graph Cycle Attention Model for Dissecting Complex Structures in Mass Spectrometry Imaging

Joint analysis of multimodalities in spatial mass spectrometry imaging (SMSI) data, including histology, spatial location, and molecule data, allows us to gain novel insights into tissue structures. However, the significant differences in characteristics such as scale and heterogeneity among the mul...

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Bibliographic Details
Published inJournal of computer science and technology Vol. 40; no. 3; pp. 766 - 779
Main Authors Cui, Jiang-Nan, Gao, Yang, Wang, Qiu, Li, Xuan, Xu, Ke-Ren, Huang, Zhen-Yu, Zhang, Jing-Song, Zuo, Chun-Man
Format Journal Article
LanguageEnglish
Published Singapore Springer Nature Singapore 01.05.2025
Springer Nature B.V
Subjects
Artificial Intelligence
Computer Science
Data Structures and Information Theory
Graph neural networks
Heterogeneity
Histology
Information Systems Applications (incl.Internet)
Mass spectrometry
Noise levels
Regular Paper
Scientific imaging
Software Engineering
Spatial data
Theory of Computation
graph attention autoencoder
mass spectrometry imaging
multimodal data integration
cross-graph cycle attention
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Summary:Joint analysis of multimodalities in spatial mass spectrometry imaging (SMSI) data, including histology, spatial location, and molecule data, allows us to gain novel insights into tissue structures. However, the significant differences in characteristics such as scale and heterogeneity among the multimodal data, coupled with the high noise levels and uneven quality of MSI data, severely hinder their comprehensive analysis. Here, we introduce a cross-graph cycle attention model, MSCG, to learn efficient joint embeddings for multimodalities of SMSI data by integrating graph attention autoencoders and attention-transfer. Specifically, MSCG enables leveraging one modality (e.g., histology) to fine-tune the graph neural network trained for another modality (e.g., MSI). Our study on real datasets from different platforms highlights the superior capacities of MSCG in dissecting cellular heterogeneity, as well as in denoising and aggregating MSI data. Notably, MSCG demonstrates versatile applicability across MSI data from various platforms, showcasing its potential for broad utility in this field.
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ISSN:1000-9000
1860-4749
DOI:10.1007/s11390-025-4342-2