Berend Houwen

Flow cytometric method for enumeration and classification of reactive immature granulocyte populations.

We developed a flow cytometric method for the enumeration and classification of nonmalignant immature granulocytes (IG). In this study, IG are defined as most immature (IG stage 1: promyelocytes and myelocytes) and as more mature (IG stage 2: metamyelocytes). Blood specimens from 46 patients with documented infectious or inflammatory disease and known presence of IG (by routine manual microscopy) were analyzed. For a reference manual differential count, we used a 400 white blood cell (WBC) differential and separated granulocytes into promyelocytes and myelocytes combined, metamyelocytes, and included band cells in the mature, segmented neutrophil population. The flow cytometric method is based on three-color staining of whole, anticoagulated blood with CD45-PerCP, CD16-FITC, and CD11b-PE-labeled monoclonal antibodies and a three-step gating procedure. The flow cytometric results were confirmed by cell sorting and microscopic evaluation of the sorted cells. A total of 10,000 events, excluding debris, were recorded per specimen and IG stage 1 (CD16-/CD11b-), IG stage 2 (CD16-/CD11b+), and mature neutrophils (CD16+/CD11b+) were categorized. Regression and correlation between flow cytometric IG and the manual differential showed y = 1.34x + 0.95, r(2) = 0.86 for IG stages 1 and 2 combined versus promyelocytes, myelocytes, and metamyelocytes. For IG stage 1 versus microscopic counts of promyelocytes and myelocytes, the results were y = 1.53x + 1.24, r(2) = 0.76; for IG stage 2 versus manual metamyelocyte count, y = 0.77x + 0.21, r(2) = 0.58. Reproducibility of the flow cytometric method showed a coefficient of variation (CV) of 6.8% for all IG combined compared with a CV of 50.2% for manual differential IG count (based on a routine 100 WBC count). Samples were found stable at least 12 h at 25 degrees C and at least 48 h at 4 degrees C for flow cytometry. After staining and lysing, the sample was stable for at least 120 min at room temperature. We analyzed samples from patients with myelodysplastic and myeloproliferative disease separately. We found that CD16- mature neutrophils falsely elevated the flow cytometric IG count. Similar results were obtained in blood from patients treated with granulocyte-colony stimulating factor (G-CSF). Although this restricts the use of the method somewhat, we believe that this flow cytometric method is useful for enumerating reactive IG, as well as for evaluating automated methods for IG identification by hematology analyzers.

An Interlaboratory Study of a Candidate Reference Method for Platelet Counting

A multinational interlaboratory task force explored the important variables of platelet reference counting and developed a candidate flow cytometric reference method based on the RBC/platelet ratio. A multicenter comparison was performed to determine whether the method met the necessary criteria and was precise enough to be recommended as a new reference method. Each laboratory analyzed serial dilutions of normal specimens, stabilized material, and at least 60 patient specimens with a range of platelet counts from 1 to 400 x 10(3)/microL (1-400 x 10(9)/L). Pooled analysis of the serial dilutions showed that RBC-platelet and RBC-RBC coincidence events became negligible at sufficiently high dilutions (i.e., > 1:1,000). All laboratories demonstrated excellent intra-assay and acceptable interlaboratory precision. Two antibodies (CD61 and CD41) were used for identifying platelets and individually gave acceptable results, but in a minority of samples, staining differences were observed. The optimum method thus uses a double-labeling procedure with a final dilution factor of 1:1,000. The study demonstrated that this method meets the criteria for a reference platelet count.

New rapid flow cytometric method for the enumeration of nucleated red blood cells

BACKGROUND Nucleated red blood cells (NRBC) in blood specimens compromise the automated white blood cell (WBC) count on most hematology analyzers. This makes it necessary to correct the WBC count by subtracting separately counted NRBC by manual microscopy. In addition, it is clinically important to establish the non-physiological presence of NRBC in blood specimens because of their association with significant hematological and non-hematological disease. Unfortunately, manual microscopic methods lack sensitivity, specificity and reproducibility required for both. METHODS We have developed a new, rapid flow cytometric method for the detection and enumeration of NRBC, based on two-color staining with anti-CD45-fluorescein-isothiocyanate (CD45-FITC) and propidium iodide (PI). EDTA anticoagulated blood samples are incubated for 30 min with CD45-FITC, followed by 30 sec acid-hypotonic lysis, containing PI and subsequent addition of an alkaline-hypertonic solution. The samples are thus ready for flow cytometric analysis. RESULTS The method typically yields up to four populations, (1) red blood cell (RBC) ghosts, debris, lyse-resistant RBC, reticulocytes and platelets, (2) CD45(+) WBC unstained by PI, (3) CD45(+) WBC stained by PI, and (4) CD45(-)/PI(bright) NRBC. Manual microscopic reference NRBC counts of 25 patient specimens showed excellent correlation with flow cytometric NRBC determinations (y = 0.943x+0. 66; r(2) = 0.982). Performance for precision showed a mean coefficient of variation (CV) for the flow cytometric method of =10%, with a mean CV for manual NRBC counts of 40%. CONCLUSIONS We conclude that this method is suitable for NRBC counting in peripheral blood specimens with improved performance in terms of accuracy, reproducibility when compared to manual microscopic methods.