Initial flow cytometric evaluation of the Clearllab lymphoid screen.

INTRODUCTION: Flow cytometric immunophenotyping (FCI) is an integral part in the diagnosis and classification of hematologic malignancies. FCI results also influence therapeutic decisions and disease prognosis. ClearLLab LS is a 12-antibody 10-color cocktail provided in dry format designed as a screen for patients suspected of having hematolymphoid disease. METHODS: A blinded comparison between ClearLLab LS, (CD8-FITC, Kappa-FITC,CD4-PE, Lambda-PE, CD19-ECD, CD56-PE-Cy5.5, CD10-PE-Cy7, CD34-APC, CD5-APC-A700, CD20-APC-A750, CD3-PB, and CD45-KrO), ClearLLab Reagents (five-color, 17-antibodies) and individual Laboratory Developed Tests (LDTs), was conducted at four laboratories. Evaluation of ClearLLab LS was performed on 210 specimens, compared to the five-color ClearLLab Reagents (IVD and CE-IVD), and a subset (n = 167) to LDTs. RESULTS: ClearLLab LS showed good agreement to ClearLLab Reagents in detecting the absence (104/104) or presence (106/106) of abnormal populations. Of specimens with abnormal populations the ClearLLab LS agreed with the ClearLLab Reagent for neoplasm maturity assessment (70/70 mature and 36/36 immature). Out of 167 specimens with LDTs results, 86 contained abnormal population(s), ClearLLab LS detected 82 (95.3%) of cases. Of the 4 cases not detected by ClearLLab LS, 3 were plasma cell neoplasms and 1 was a mature T cell malignancy. Eighty-one samples with no hematological malignancy as analyzed by LDT were also negative by ClearLLab LS (100% agreement). ClearLLab LS agreed with LDTs assessment of neoplasms' maturity (55/55 mature and 27/27 immature). CONCLUSION: ClearLLab LS screening tube showed excellent agreement between ClearLLab Reagents and with LDT's. The presence of CD34 and CD10 in the tube allowed the detection of blast populations in several acute leukemias and myeloid neoplasms that were tested. © 2017 International Clinical Cytometry Society.

Flow cytometry-Recognizing unusual populations in leukemia and lymphoma diagnosis.

Flow cytometry is an invaluable technology in the examination of blood, bone marrow, tissue and body fluids for the presence or absence of hematological disease. It is used in both diagnostic and follow-up testing, with an increasingly important role in the detection of very small residual disease populations (Minimal Residual Disease, MRD) However, flow cytometry immunophenotyping of leukemia and lymphoma is highly dependent on interpretation of results and with the increased complexity of 8-10 color instruments routinely used in clinical laboratories, knowledge of disease-defining populations is increasingly important as is recognizing normal and reactive patterns. This manuscript presents case studies with flow cytometric patterns encountered in routine screening of samples sent for leukemia and lymphoma immunophenotyping, focusing mainly on B-cell disorders which may be missed or incorrectly interpreted by the laboratory (including a hematopathologist) performing the test. Case studies are used to illustrate our laboratory's standardized approach to the interpretation of flow cytometric data. In addition to a standardized approach, these cases emphasize the importance of interpretative skills of technologist and hematopathologists in recognizing abnormal patterns in detecting hematological malignancies.

Technical issues: flow cytometry and rare event analysis.

Flow cytometry has become an essential tool for identification and characterization of hematological cancers and now, due to technological improvements, allows the identification and rapid enumeration of small tumor populations that may be present after induction therapy (minimal residual disease, MRD). The quantitation of MRD has been shown to correlate with relapse and survival rates in numerous diseases and in certain cases, and evidence of MRD is used to alter treatment protocols. Recent improvements in hardware allow for high data rate collection. Improved fluorochromes take advantage of violet laser excitation and maximize signal-to-noise ratio allowing the population of interest to be isolated in multiparameter space. This isolation, together with a low background rate, permits for detection of residual tumor populations in a background of normal cells. When counting such rare events, the distribution is governed by Poisson statistics, with precision increasing with higher numbers of cells collected. In several hematological malignancies, identification of populations at frequencies of 0.01% and lower has been attained. The choice of antibodies used in MRD detection facilitates the definition of a fingerprint to identify abnormal populations throughout treatment. Tumor populations can change phenotype, and an approach that relies on 'different from normal' has proven useful, particularly in the acute leukemias. Flow cytometry can and is used for detection of MRD in many hematological diseases; however, standardized approaches for specific diseases must be developed to ensure precise identification and enumeration that may alter the course of patient treatment.