Flow cytometry enables researchers to label proteins of interest using fluorophore-conjugated antibodies and other fluorochromes. Much like immunohistochemistry, which produces two- or ...

Today, flow cytometry users can choose between hundreds of different fluorochromes. On the one hand, this gives them unprecedented flexibility. On the other hand, learning the properties of each ...

Flow cytometry experiments are measuring more variables than ever, pushing the technical limits of conventional flow cytometry. Spectral flow cytometry enables multicolor panels with more parameters ...

Multicolor flow cytometry is beneficial because it allows us to gain deeper insights from a given biological sample, with fewer repeat markers in each tube and quicker results. In this three-part ...

Flow cytometry remains a critical technology for the high-throughput analysis of single cells in complex populations. Attention to good analysis practices is more important than ever due to the recent ...

Flow cytometry is widely used in areas of research that require analysis or isolation of cells from suspension. This technology makes use of fluorescent probes targeted to specific cell-associated ...

With flow cytometry, as with many technologies that enjoy continuous use, we can see an evolution of capabilities. Spectral analysis, image capture, and artificial intelligence are just a few of the ...

Flow cytometry detects and measures the chemical and physical properties and characteristics of particles or cells within a population. Samples are suspended in a liquid, held in a tube, and counted ...

Multicolor flow cytometry is beneficial because it allows us to gain deeper insights from a given biological sample, with fewer repeat markers in each tube and quicker results. In this three-part ...

Flow cytometry is a way to look closely at the features of cells or particles. A sample of blood or tissue goes into a machine called a cytometer. In less than a minute, a computer can analyze ...