This three-part webinar series brings together leading researchers to explore how spatial biology is evolving - from data ...
Spatial transcriptomics technologies opened the door for new kinds of biological measurements, allowing scientists to generate detailed maps of where genes are expressed in tissue. But most methods ...
New simulator and computational tools generate realistic ‘virtual tissues’ and map cell-to-cell ‘conversations’ from spatial transcriptomics data, potentially accelerating AI-driven discoveries in ...
Researchers at the Max Delbrück Center have developed an open-source spatial transcriptomics (ST) platform, called Open-ST, that creates 3D molecular maps from patient tissue samples with subcellular ...
Knowing the location of a gene within intact tissue or a single cell allows scientists to unlock unknown cellular functions. This information is often lost in most genetic sequencing techniques, but ...
Biological systems are inherently three-dimensional—tissues form intricate layers, networks, and architectures where cells interact in ways that extend far beyond a flat plane. To capture the true ...
Complete the form below to receive the poster. Spatial transcriptomics has transformed our ability to map gene expression within intact tissues, yet most existing approaches require specialized ...
A whole developing wheat spike, 1mm scale. The blue represents fluorescent staining for DNA withing the nuclei. There are different coloured spots showing gene expression detected using the probes in ...
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 ...
From left to right and top to bottom: the researchers from IN CSIC-UMH Joan Galcerán, Berta L. Sánchez-Laorden, Khalil Kass Youssef, Raúl Jiménez Castaño, Ángela Nieto, and Nitin Narwade.
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