Until now, conventional 3D cell cultures have often been either too rigid or too unstable to realistically reproduce the ...

Scientists usually study the molecular machinery that controls gene expression from the perspective of a linear, two-dimensional genome—even though DNA and its bound proteins function in three ...

By simulating the life cycle of a minimal bacterial cell—from DNA replication to protein translation to metabolism and cell ...

This whitepaper explores how integrated live-cell confocal imaging enables precise quantification, real-time kinetic insight, ...

A team led by Professor Inkyung Jung from the Department of Biological Sciences at KAIST, working with Professor Yarui Diao’s ...

The brain relies on real-time delivery of oxygen and nutrients through its microvasculature, which threads through neural ...

A remarkably small bacterium containing fewer than 500 genes serves as the basis for one of the most detailed digital life ...

Dr Priyanka Dey has secured funding to develop a new technique that will give us a richer understanding of what cancer cells are made of and how they change as disease progresses ...

Miniature organs grown in the lab can organize themselves into complex shapes, which enables scientists to use them to study disease. The trouble is they never do it the same way twice, which has made ...

It’s far less gross than it sounds (we promise) and could have major implications for how we understand anatomy and disease ...

The origin of many diseases begins at the cellular level and involves multiple molecular interactions. However, previous methods have struggled to accurately observe changes in individual cells.