This article explores how single-cell multiomics and spatial transcriptomics are illuminating early pregnancy, uncovering ...

Using sophisticated RNA sequencing technology, biomedical researchers can measure the activity of our genes across millions of single cells, creating detailed maps of tissues, organs, and diseases.

The world of cells is surprisingly noisy. Each cell carries unique genetic information, but when we try to measure cellular activity, signals can be lost or blurred, and differences between ...

Capturing spatial information is essential to elucidate how cells function and interact within their native tissue environment. However, the initial spatial transcriptomics techniques have several ...

Triglia discusses her research at the intersection of genetics, epigenetics, single-cell genomics and computational biology.

Single-cell RNA-seq (scRNA-seq) has spent the past decade maturing into a foundational technology. Over that time, the technology has both laid the foundation for building cell atlases and allowed ...

Over the past decades, large-scale human genetic studies have identified numerous risk genes and variants associated with complex diseases and traits.

Arc Institute continues its work to generate and share large-scale, high-quality datasets of cell state before and after chemical or genetic perturbations to enable "virtual cell" models and other ...

An interdisciplinary team of University of Tennessee, Knoxville researchers recently published in Biophysical Journal on ...