The Whole Transcriptome Panel for Bruker’s CosMx Spatial Molecular Imager (SMI) represents a breakthrough in spatial biology. With the ability to detect and quantify over 18,000 RNA transcripts at ...

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 has emerged as a highly valuable field of study, examining the relationships between biological cells and molecules in their native spatial orientation, which can occur in both ...

Understanding cellular function within a given microenvironment is currently an expectation rather than the exception in life sciences research. Cell- and tissue-specific relationships determine ...

Spatial biology first entered the omics scene about a decade ago. Since then, the technology has generated significant buzz both inside and outside of the lab—beyond its contributions to science. The ...

Spatial proteomics is a spatial biology method that helps study the spatial distribution of the proteins within cells and tissues. The subcellular localization of proteins is intrinsic to cellular ...

Come learn how AI-powered segmentation, spatial analysis, and phenotyping can help you gain new insights for 3D images with complex morphological features and multiple biomarkers. With Aivia you can ...

Many spatial biology researchers rely on two-dimensional tools, which section the cellular architecture and processes occurring within 3D tissues into flat layers. Three-dimensional multiomic analysis ...

Advancements to include CosMx® Whole Transcriptome Panel; enhanced technology engine to power CellScape™ for spatial proteomics; expansion to 1000-plex protein assay on GeoMx® DSP; and launch of ...