自编码
计算机科学
人工智能
模式识别(心理学)
反褶积
特征(语言学)
水准点(测量)
粒度
转录组
空间分析
图像(数学)
表达式(计算机科学)
模态(人机交互)
光学(聚焦)
计算机视觉
编码器
工件(错误)
特征向量
标杆管理
图像处理
相关性(法律)
空间生态学
特征提取
依赖关系(UML)
感知
机器学习
可视化
深度学习
作者
Tianyi Chen,Wen Xue,Yunfei Zhang,Yongcan Luo,Cheng Liu,Wenjun Shen,Si Wu,Hau-San Wong
摘要
Spatial transcriptomics (ST) technologies have significantly advanced our ability to discern gene expression patterns within intact tissue structures, enabling unprecedented insights into cellular heterogeneity and tissue architecture. However, accurately determining cell-type proportions within spatially aggregated transcriptomic spots remains challenging due to inherent granularity discrepancies, batch effects, and spatial heterogeneity. To address these challenges, we introduce S$^{2}$potAE, a novel spatial spot autoencoder framework that integrates gene expression data, spatial coordinates, and morphological features from histology images for precise spot-level deconvolution. S$^{2}$potAE employs a multilevel feature aggregation strategy, systematically extracting and fusing spatially-aware features through a graph-based spatial encoder and perceptual image embeddings from histological patches. Furthermore, an auxiliary pathological classification task enhances biological relevance and model interpretability. Comprehensive benchmarking across multiple simulated and real datasets-including human breast cancer, mouse brain anterior, and human dorsolateral prefrontal cortex-demonstrates that S$^{2}$potAE consistently surpasses state-of-the-art methods in accuracy, robustness, and biological interpretability. Our approach effectively resolves complex cellular compositions, accurately identifies tumor boundaries, and captures nuanced cell-type distributions, significantly enhancing the utility of ST in biological research and clinical applications.
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