TopoLa: A Universal Framework to Enhance Cell Representations for Single-cell and Spatial Omics through Topology-encoded Latent Hyperbolic Geometry

2025 · doi:10.1101/2025.07.23.666288
preprint OA: closed
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The paper introduces Topology-encoded Latent Hyperbolic Geometry (TopoLa), a computational framework for improving cell representations in both single-cell RNA-seq and spatial transcriptomics by encoding fine-grained intercellular topological relationships. Using a new metric called TopoLa distance (TLd) to measure geometric distance between cells in latent hyperbolic space, the method enhances representations by convolving over neighboring cells. Across seven biological tasks, including scRNA-seq clustering and spatial transcriptomics domain identification, TopoLa reportedly improves performance of several existing state-of-the-art models. The paper does not explicitly state limitations in the provided text, and it presents results focused on computational evaluation rather than biological interpretation. The paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract Recent advances in cellular research demonstrate that scRNA-seq characterizes cellular heterogeneity, while spatial transcriptomics reveals the spatial distribution of gene expression. Cell representation is the fundamental issue in the two fields. Here, we propose Topology-encoded Latent Hyperbolic Geometry (TopoLa), a computational framework enhancing cell representations by capturing fine-grained intercellular topological relationships. The framework introduces a new metric, TopoLa distance (TLd), which quantifies the geometric distance between cells within latent hyperbolic space, capturing the network’s topological structure more effectively. With this framework, the cell representation can be enhanced considerably by performing convolution on its neighboring cells. Performance evaluation across seven biological tasks, including scRNA-seq data clustering and spatial transcriptomics domain identification, shows that TopoLa significantly improves the performance of several state-of-the-art models. These results underscore the generalizability and robustness of TopoLa, establishing it as a valuable tool for advancing both biological discovery and computational methodologies. Competing Interest Statement The authors have declared no competing interest.

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