This guide examines the core principles that underpin robust flow cytometry workflows, connecting established best practices ...
Developed initially in the field of immunology, flow cytometry now has applications throughout the biological sciences and beyond. A successful flow cytometry experiment begins with good sample ...
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 ...
As high-parameter T-cell profiling becomes increasingly central to translational research and biomarker discovery, there is ...
A large body of research publications covering hematological disorders, such as acute myeloid leukemia (AML) and multiple ...
Housed inside BD Biosciences’ latest cell sorter, the BD FACSymphony™ S6 Cell Sorter*, is an array of sophisticated optical technologies. There is space for up to 9 different lasers, along with ...
Flow cytometry works by illuminating cells, or other types of particle, as they flow in front of a light source, such as a single or dual laser beam. The light source then detects and correlates ...
Flow cytometry uses fluorescent probes to identify and characterize cells or particles in suspension (e.g. cells, nuclei or chromosomes) by virtue of size, granularity and fluorescence ...
The UAB Flow Cytometry Lab is home to a staff of medical laboratory professionals who perform complex testing using state-of-the-art flow cytometry equipment. This testing, through research, education ...
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 ...