Living organisms are made up of hundreds of thousands of cells that cooperate to create the organs and systems that breathe, eat, move, and think. Now, researchers from Japan have developed a new way ...

The overarching experimental design is depicted in Figure . On day 1, each cell type was seeded on uniquely colored cell carriers (Huh7 on white, THP1 on red, and LX2 on blue). On day 2, the Huh7 ...

The cell-surface proteome is spatially dynamic and changes with the state of the cell, which in turn determines its activity in health and disease. Protein spatial architecture enables cell-cell ...

AI meets cell biology: RegVelo fuses dynamic cell-state modeling with regulatory network mapping to predict developmental paths. Early driver detection: The model pinpointed known and novel pigment ...

Single-cell analysis is a ubiquitous laboratory technique that allows researchers to probe the myriad biomolecular states of cells. Single-cell assays can reveal gene and protein expression patterns, ...

A new study by scientists at the University of North Carolina at Chapel Hill reveals that the cells shaping our organs may be far more mobile and coordinated than once believed. The study is published ...

The hiFlow in vitro platform. a Schematic of the hiFlow chip (backside view), with the components of the microfluidic network highlighted in the design. Each chip hosts two microfluidic networks and ...

Cell culture is a fundamental technique in biotechnology and life sciences that involves growing and maintaining living cells outside their natural environment, typically in a controlled laboratory ...