1. Light scatter. Light scattering occurs when a particle or cell deflects laser light. Forward-scattered (FSC) light is in line with the laser light beam and represents a measurement of the cell surface size. Side-scattered (SSC) light is collected perpendicular to the laser light beam and analyzes the granularity or internal complexity of a cell. Leukocytes can be separated into different subpopulations using FSC and SSC. For example, lymphocytes will show both a low forward scatter and a low side scatter due to the small size and lack of cytoplasmic granulation. In contrast, neutrophils are larger in size and show granular cytoplasm as well as a complex nucleus, and therefore will show both a high forward and a side scatter (e-Fig. 57.1).^*

2. Fluorescence. Another way to identify particular subpopulations is to conjugate fluorescent dyes to monoclonal antibodies directed toward antigens on a particular cell subset. The staining procedure can be carried out in a direct or indirect staining process. The direct staining procedure involves a single staining incubation, followed by several washes to remove nonspecifically bound antibodies. The indirect staining procedure involves the incubation of cells with a nonfluorescent monoclonal antibody directed toward the specific antigen. After washing to remove nonspecifically bound antibody, there is a second incubation with a fluorescent antibody directed against the monoclonal antibody. Although more time-consuming, the indirect staining procedure is less expensive.

Argon ion lasers are the most common lasers used in flow cytometry because the 488-nm light emitted can be absorbed by more than one fluorochrome. Examples of fluorochromes that are conjugated to antibodies are fluorescein isothiocyanate (FITC) and phycoerythrin (PE). FITC absorbs light in the range of 460 to 510 nm and then fluoresces in the range of 510 to 560 nm, with a peak at ˜525 nm, giving a green fluorescent color. PE absorbs light in the range of 480 to 565 nm and fluoresces at ˜570 nm, giving a red fluorescent color. Although both fluorochromes absorb light at ˜488 nm, the resulting different peak emission wavelengths can be detected by different detectors, which make it possible to use more than one fluorochrome in one sample to simultaneously collect information on the expression of several markers in a specific cell. Combined with the FSC and SSC data, the staining pattern of each subpopulation will aid in delineating which cells are present in a sample and in what percentage they are present (e-Fig. 57.2).