Spatial biology captures molecular complexity by preserving the physical context of cells in their native environments. From deciphering RNA dynamics within stress granules to scaling molecular ...

Tissues are where most biological functions, drug effects and diseases occur, and are often considered a homogenous entity where different types of cells are woven in regularly repeated patterns.

Single-cell and spatial techniques have evolved in leaps and bounds over the last decade, spreading from genomics into each omic realm. The latest developments for spatial techniques in the proteomics ...

To study biological processes, scientists often take snapshots of the molecules in cells, such as proteins and nucleotides, at specific points in time. In spatial biology, they can leverage molecular ...

Traveling time forecasting, the core component in GPS navigation systems and taxi-hailing apps, has attracted widespread attention. Existing research mostly focuses on independent points like traffic ...

Head and neck cancers display notable heterogeneity in their immune cell infiltrates, which reflect intricate spatial arrangements and dynamic networks of ...

Tumors contain many different types of cells organized in complex spatial patterns that can influence how the disease progresses. Because of this, it is hard to predict how a tumor will develop and ...

In a recent study posted to the medRxiv* preprint server, researchers used in situ sequencing and spatial single-cell transcriptome analysis (SSCTA) to examine postmortem coronavirus disease 2019 ...