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 ...

After five decades of use, flow cytometry is entrenched in biomedical science. Besides enabling the quick processing of cells in suspension, flow cytometry provides quantitative results across ...

Flow-based methods allow researchers to collect multiparameter data from individual cells in their samples, but the fate of samples depends on the instrument. In addition to cell analysis, cell ...

Nearly 35 years since Stanford researcher Leonard Herzenberg and colleagues developed the first fluorescence activated cell sorter (FACS), the instrument has become the immunologists' key tool.

Over the past five years, the FCSC has invested $3.5 million in replacing or updating its instruments, expanding capacity, and developing new services such as multiplex immunofluorescence, Hanumanthu ...

Flow cytometry is an invaluable method for biomedical research. Since its development over 50 years ago, technology for flow cytometry has progressed rapidly, allowing for the detection of more and ...

Flow cytometry offers practical advantages for real-time monitoring of CAR T cell expansion, persistence, and toxicity risk in aggressive large B-cell lymphoma patients. Early CAR T cell expansion is ...

Flow cytometry effectively detects CTCs in melanoma patients, offering a rapid, cost-effective alternative to molecular biology. CTCs are present across all melanoma stages, with a significant ...

Over the past decade, flow cytometry has undergone transformative advancements, notably with the adoption of spectral flow cytometry and the emergence of next-generation imaging cytometers. These ...