Spatial proteomics has emerged as a transformative approach in modern biomedical research. Unlike conventional proteomics, spatial proteomics preserves spatial context, enabling high-resolution ...

Researchers use multiomic spatial maps to understand complex biological processes, including neovascularization and immune cell activation for cardiac remodeling after myocardial infarction. Mapping ...

BUFFALO, N.Y. – A groundbreaking technique for in-depth mapping of protein localizations in whole tissue developed by researchers in the University at Buffalo School of Pharmacy and Pharmaceutical ...

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 ...

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.

Spatial maps of various tissues and organs in aging mice have revealed new insights into the aging process. Aging is a process common to many animals; however, the complexity of aging means that there ...