Immature and Differentiated Neoplastic Populations in Acute Lymphoid Leukemia of Childhood: Biological and Clinical Implications
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Abstract:
Despite significant improvement in the therapy for acute lymphoid leukemia (ALL) of childhood, approximately 30% of patients relapse. Unfortunately, since no successful treatment for recurrent disease has been developed, the majority of these patients die. Recently, we presented evidence consistent with the presence of a limited program of differentiation in B-precursor ALL that is reminiscent of normal B-cell development. We found that ALL cell populations consist of both a subpopulation of progenitors with the immunophenotype of normal B-cell precursors that has self-renewal capability and a second subpopulation with a more mature early B-cell immunophenotype that is without self-renewal capability but can proliferate to a limited extent. In our recent studies we were able to grow the progenitor cells in the ALL blast colony assay and establish their leukemic origin using the polymerase chain reaction. Our results suggest that these progenitors are the cells that sustain the disease. We hypothesize that these cells may remain quiescent, for a time, and either eventually die or regain proliferative capability and cause relapse. Further studies aimed both at detecting residual ALL and determining changes in their biology may provide an understanding of the mechanisms of relapse in this disease.Keywords:
Immunophenotyping
Minimal Residual Disease
Precursor cell
Objective To investigate the characteristics of immunophenotyping and clinical significance of MRD analysis in MM patients. Methods Multi-parameter flow cytometry was applied to analyze the immunophenotyping of malignant plasma cells from 172 MM patients, and normal plasma cells from 16 healthy individuals. MRD was analyzed in 32 MM patients with remission. Meanwhile, the effects of MRD status on the disease relapse and patient disease free survival ( DFS ) time was evaluated by following up patients. Results The immunophenotyping of normal plasma cells were CD38, CD138, CD19 and CD45 positive, while the predominant phenotype of MM cells were CD+38( 100.0% ), CD+138( 100.0% ), CD-19 ( 167/172, 97. 1% ), CD+56( 152/172, 88.4% ) and CD-45( 166/172, 96. 5% ). The characteristic markers for MM cells were CD+38, CD-138, CD-19, CD-45 and CD+56. MRD analysis revealed that, among 32 MM patients with remission, 14 patients were MRD negative and 18 patients were MRD positive. During follow-up of 2 to 16 months, the relapse rate in MRD negative patients was significantly lower ( 4/14, 28.6% ) than that of MRD positive patients ( 13/18, 72. 2% ;χ2 =6. 03, P <0. 05 ). Furthermore, the DFS time was significantly longer in MRD negative patients[ 16. 23( 10. 37-21.62 )months ] than that of the MRD positive patients [ 10. 07( 3. 79-16. 20 )months,χ2 =7. 53,P <0. 05 ]. Conclusions CD+38, CD+138, CD-19, CD-45 and CD+56 are the characteristic markers of MM cells compared to those of the normal plasma cells. MRD analysis is a valuable prognostic factor for MM patients.
Key words:
Multiple myeloma; Immunophenotyping; Neoplasm,residual; Flow cytometry
Immunophenotyping
Minimal Residual Disease
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Immunophenotyping
Minimal Residual Disease
Lymphoblast
Acute lymphocytic leukemia
Bone marrow aspirate
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Minimal residual disease (MRD) can be detected only by sophisticated methods, e.g. immunologic. The purpose of the study was to detect MRD in leukemia patients (AL) being in hematological and clinical remission (CR) by immunophenotyping of bone marrow cells and to define the role of the immunologic method in the detection of MRD. Bone marrow samples from 31 patients with ALL and AML and from 18 volunteers were taken several times. Staining of the cells was performed by double color immunofluorescence (IF) and double color immunoenzyme assay (APAAP). The detection of MRD was done by the comparison of the percent of positive cells between AL and normal cases. Each pair of the antigens (CD) was estimated in its usefulness in MRD detection. The statistical analyses were evaluated with a t-Student's test.
Immunophenotyping
Minimal Residual Disease
Immunofluorescence
Bone marrow examination
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Multiple myeloma (MM) is a haematological malignancy characterized by the accumulation of monoclonal plasma cells in the bone marrow and remained incurable. Flow cytometry has been widely used in the detection of immunophenotype and minimal residual disease, diagnosis, monitoring and prognosis of MM. Normal plasma cells and malignant plasma cells can be distinguished according to different cell surface antigen expression. The clinical significane of many immune markes has been elucidated. However, the clinical significance of some phenotype remains controversial, the detection scheme and gating strategy are not unified. This review discusses the recent research progress on detection of MM immunophenotype and minimal residual disease by flow cytovetry.
Immunophenotyping
Minimal Residual Disease
Clinical Significance
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Immunophenotyping
Minimal Residual Disease
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Minimal residual disease (MRD) following treatment is a robust prognostic marker in B lymphoblastic leukemia. However, the detection of MRD by flow cytometric immunophenotyping is technically challenging, and an automated method to detect MRD is therefore desirable. viSNE, a recently developed computational tool based on the t-Distributed Stochastic Neighbor Embedding (t-SNE) algorithm, has been shown to be capable of detecting synthetic "MRD-like" populations of leukemic cells created in vitro, but whether viSNE can facilitate the immunophenotypic detection of MRD in clinical samples has not been evaluated.
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Minimal Residual Disease
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The detection of minimal residual disease (MRD) is an important prognostic factor in childhood acute lymphoblastic leukemia (ALL) providing crucial information on the response to treatment and risk of relapse. However, the high cost of these techniques restricts their use in countries with limited resources. Thus, we prospectively studied the use of flow cytometry (FC) with a simplified 3-color assay and a limited antibody panel to detect MRD in the bone marrow (BM) and peripheral blood (PB) of children with ALL. BM and PB samples from 40 children with ALL were analyzed on days (d) 14 and 28 during induction and in weeks 24-30 of maintenance therapy. Detectable MRD was defined as > 0.01% cells expressing the aberrant immunophenotype as characterized at diagnosis among total events in the sample. A total of 87% of the patients had an aberrant immunophenotype at diagnosis. On d14, 56% of the BM and 43% of the PB samples had detectable MRD. On d28, this decreased to 45% and 31%, respectively. The percentage of cells with the aberrant phenotype was similar in both BM and PB in T-ALL but about 10 times higher in the BM of patients with B-cell-precursor ALL. Moreover, MRD was detected in the BM of patients in complete morphological remission (44% on d14 and 39% on d28). MRD was not significantly associated to gender, age, initial white blood cell count or cell lineage. This FC assay is feasible, affordable and readily applicable to detect MRD in centers with limited resources.
Minimal Residual Disease
Immunophenotyping
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Minimal Residual Disease
Immunophenotyping
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Minimal residual disease (MRD) as a tool to monitor response to therapy is both a criterion for detailed risk stratification and an independent prognostic factor in childhood acute lymphoblastic leukemia (ALL). Immunological assays particularly flow cytometry (FC) are priority methods in MRD monitoring. Multicolor flow cytometry makes it possible to most fully characterize the immunophenotype of tumor B lymphoblasts and reveal leukemia-associated immunophenotypes not only according to the CD58 and CD38 antigens but also as an additional criterion of aberrancy. This allows you to identify and select individual criteria for further monitoring of minimal residual disease for each patient with ALL. The aim of this chapter is to compare immunophenotyping features of normal B-cell precursors and B-lymphoblasts in acute leukemia and to show possibilities of use of a leukemia-associated immunophenotype in monitoring of the MRD.
Immunophenotyping
Minimal Residual Disease
Lymphoblast
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Immunophenotyping
Minimal Residual Disease
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