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Objective:To observe and analyze the morphological characteristic of bone marrow and peripheral blood in patients diagnosed with de novo acute leukemia.Methods:From October 1, 2015 to December 31, 2021, 1151 patients aged 47 (26, 62) years, consisting of 602 males and 549 females with newly diagnosed acute leukemia in the Department of Hematology, Affiliated Hospital of Xuzhou Medical University, were collected to preform the morphological analysis in bone marrow and peripheral blood smears. Based on the comprehensive diagnosis results of morphology, immunology, cytogenetics, and molecular biology, comparison between acute myeloid leukemia (AML) and acute lymphoblastic leukemia (ALL), AML with RUNX1-RUNXITI gene, AML with CBFβ/MYH11 gene, acute promyelocytic leukemia (APL) with PML/RARA gene, AML with NPM1 gene, the rest of the AML, Ph+ALL and Ph-ALL were performed by Chi-square test along with analysis of the differences in the ratio of wood bundle cells, pseudo-Chediak-Higashi (PCH) inclusions, cytoplasmic small particles, nuclear notches, leukemia cells with cup-like changes (cup cells); as well as the differences in the micromeganuclei, early immature granulocytes, plasma cells, high eosinophils and other accompanying cells and the distribution of "grape-like" aggregation. Finally, the morphological characteristics of acute leukemia cells, the appearance and arrangement of accompanying cells were summarized.Results:Between AML and ALL, there were statistically significant differences in cytoplasmic Auer bodies[(45.5%, 0%), χ 2=211.400, P<0.01], PCH inclusion bodies[(28.9%, 0%), χ 2=114.100, P<0.01], cytoplasmic fine particles[(20.7%, 2.9%), χ 2=53.798, P<0.01], nuclear notches[(0.7%, 6.1%), χ 2=30.906, P<0.01], and goblet cells[(4.9%, 0.3%), χ 2=13.495, P<0.01], micromegakaryus [(22.4%, 0.3%), χ 2=80.398, P<0.01], plasma cells[(87.6%, 10.6%), χ 2=604.241, P<0.01], hyperacidophils[(15.3%, 1.0%), χ 2=46.116, P<0.01] showed significant differences in the "grape-like" aggregation distribution. In AML with RUNX1-RUNXITI gene, the changes of vacuoles and PCH inclusion bodies are more obvious; in AML with CBFβ/MYH11 gene, the increase of hypereosinophils is more obvious; in APL with PML/RARA gene, the increase of woodbundle is more obvious. The morphology of nuclei chromatin, nucleolus, and vacuoles were also different among the groups. Comparison between Ph+ALL and Ph-ALL showed that Ph+ALL was more prone to develop early immature granulocytes and plasma cells (all P<0.05). Conclusion:There are significant differences between AML and ALL in the characteristics of leukemia cells, the regularity of accompanying cells, and the aggregation and distribution patterns. The subtypes of AML with specific genetic abnormalities have their own characteristics in the appearance of vacuoles, PCH inclusions, hypereosinophils, woodbundle cells, and goblet cells. Ph+ALL is more prone to present early immature granulocytes and plasma cells.
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Objective:To explore an assay that can concisely, rapidly, and accurately quantify the amount of chimeric antigen receptor (CAR)-T cells in the bone marrow or peripheral blood of patients after CAR-T cell immunotherapy by morphological analysis and flow cytometry assay, providing timely and accurate feedback for clinical treatment.Methods:We analyzed the CAR-T cell detection results in peripheral blood and bone marrow of 256 patients who received CAR-T cell immunotherapy in the Department of Hematology, Affiliated Hospital of Xuzhou Medical University from August 2016 to August 2021. All 256 patients survived more than one month after CAR-T cell infusion. Among them, there were 118 patients with multiple myeloma, 68 patients with acute lymphoblastic leukemia, and 70 patients with lymphoma. The morphological characteristics, positive rate and detection rate of CAR-T cell in peripheral blood and bone marrow were analyzed by morphological methods. The positive rate and detection rate of CAR-T in peripheral blood and bone marrow were analyzed by flow cytometry protein L detection. χ 2 test was used to comprehensively analyze the difference between the detection rate of the combined analysis of the two methods and the detection rate of the single method. Results:CAR-T cells have significant morphological characteristics, and there are obvious morphological differences from normal lymphocytes. The detection rates of CAR-T cells in peripheral blood or bone marrow by morphological methods and flow cytometry were 88.28%(226/256) and 79.29% (203/256), respectively. When the two methods were combined, the detection rate of CAR-T cells can reach 99.22%, with statistically significant difference comparing to that of single method( P<0.05). Through the analysis of the detection results of peripheral blood at different time points, it was found that the average detection rates of morphology and flow cytometry in 118 patients with multiple myeloma were 9.50% and 10.23% on the 7th day, and 13.50% and 15.19% respectively on the 15th day. On the 21st day, the average detection rates of morphology and flow cytometry were 8.00% and 10.07%, respectively. The average detection rates of morphology and flow cytometry in 68 patients with acute lymphoblastic leukemia were 12.00% and 11.22% on the 7th day, and 21.00% and 23.10% respectively on the 15th day. On the 21st day, the average detection rates of morphology and flow cytometry were 13.50% and 10.91%, respectively. The average detection rates of morphology and flow cytometry in 70 lymphoma patients were 7.50% and 10.35% on the 7th day, and 9.00% and 10.35% respectively on the 15th day. The average detection rates of morphology and flow cytometry at 21 days were 6.50% and 5.69%, respectively. The number of CAR-T cells in samples from patients with different diseases reached a peak around the 15th day. Conclusion:The detection rate of CAR-T cells from peripheral blood or bone marrow was significantly higher with the combination of the 2 methods compared to the single method.