Publications by authors named "Zhencheng Tu"
The development of a multicellular organism is a highly intricate process tightly regulated by numerous genes and pathways in both spatial and temporal manners. Here, we present Flysta3D-v2, a comprehensive multi-omics atlas of the model organism Drosophila spanning its developmental lifespan from embryo to pupa. Our datasets encompass 3D single-cell spatial transcriptomic, single-cell transcriptomic, and single-cell chromatin accessibility information.
View Article and Find Full Text PDFIntracerebral hemorrhage (ICH) is a prevalent disease with high mortality. Despite advances in clinical care, the prognosis of ICH remains poor due to an incomplete understanding of the complex pathological processes. To address this challenge, we generated single-cell-resolution spatiotemporal transcriptomic maps of the mouse brain following ICH.
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- Understanding spatiotemporal dynamics in embryogenesis is key to addressing congenital diseases, prompting the development of Spateo, a 3D modeling framework for analyzing cell data in mouse embryos.
- Spateo captures detailed cellular information and employs innovative techniques for alignment and mesh correction to create comprehensive molecular holograms of embryos, revealing biological patterns across different levels.
- By modeling interactions and cell migration, Spateo uncovers molecular mechanisms involved in organ development, particularly highlighting the link between macroscopic organ changes and underlying molecular processes.
Drosophila has long been a successful model organism in multiple biomedical fields. Spatial gene expression patterns are critical for the understanding of complex pathways and interactions, whereas temporal gene expression changes are vital for studying highly dynamic physiological activities. Systematic studies in Drosophila are still impeded by the lack of spatiotemporal transcriptomic information.
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