问题亮点- 2023年5月

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Sa Wang MD
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Therefore, use of these therapies pose great challenges for clinical cytometry labs in the assessment of post-treatment samples, especially in the detection of measurable/minimal residual disease (MRD). In this issue, Chen, Gao, et al. (<span>2023</span>) provided an overview of MRD detection in B-lymphoblastic leukemia/lymphoma in the era of immunotherapy, and Gao et al. (<span>2023</span>) focused their review on the impact of targeted therapy on mature B- and plasma cell neoplasms utilizing flow cytometry assessments. In both reviews, the authors illustrated the challenges, identified the problems, and provided a list of available options and solutions. For each of the above-mentioned disease categories, optimal gating and analysis strategies were illustrated with literature review and inputs from the authors' experience and insights. The utility and interpretation of additional B-cell markers other than CD19 and CD20 for mature or immature B-cell neoplasms such as CD22, CD24, and cCD79a (Mikhailova et al., <span>2022</span>) were studied as well as VS38, CD229, and CD319 (Pojero et al., <span>2016</span>; Soh et al., <span>2021</span>) for plasma cell neoplasms. The authors recommended that the flow cytometry assays in the era of targeted therapies must contain significant redundancy in the antibody panels allowing the detection of the cells of interest and additionally should be ready to utilize several gating strategies for accurate and consistent population identification.</p><p>Neoplastic mature B-cells often show restricted kappa or lambda light chain expression; however, light chain expression may be absent in around 5%–10% of mature B-cell lymphoma (Li et al., <span>2002</span>). It is suggested that mature B-cells lacking surface light chain expression can be used as a surrogate marker to diagnose mature B-cell lymphomas. Huang et al. (<span>2023</span>) reported a series of 89 cases of surface light chain negative B-cell lymphoma which consisted primarily of chronic lymphocytic leukemia/small lymphocytic lymphoma (CLL/SLL). Interestingly, the authors also reported no detectable light chain expression in normal/reactive mature B cells collected from body fluids and cystic fluids from 14 patients with no clinical and pathological evidence of lymphoma/leukemia. Body fluids are often proteaceous; thus additional washing prior to kappa/lambda staining is often required to obtain adequate light chain staining and caution is needed in the interpretation of light chain expression in B-cells collected from body fluids. It is known that out of the context of chronic myeloid leukemia (CML) (Soma et al., <span>2016</span>), lymphoblastic crisis is extremely rare in other chronic myeloid neoplasms, such as myelodysplastic syndrome (MDS) (Xie et al., <span>2019</span>) and Philadelphia negative myeloproliferative neoplasms (MPN). Chan et al. (<span>2023</span>) reported the detection of a low level of abnormal B-lymphoblasts ranging from 0.012% to 3.6% in 9 out of 1262 MDS or Ph-negative MPN. Cell sorting coupled with next-generational sequencing showed that the abnormal B- lymphoblasts in myeloid neoplasms were often, but not always, clonally related to the myeloid compartment, and the molecular genetic findings suggested a mutant multipotent progenitor cell with different lineage output that might be determined by the specific mutations and the particular cell stage where the mutations occurred. Importantly, unlike CML, the presence of abnormal B-lymphoblasts in MDS and Ph-neg MPNs did not necessarily indicate blast crisis, and therapy for the underlying myeloid neoplasms with close monitoring is suggested to be a reasonable approach.</p><p>The last article in this issue (Chen, Zhang, et al., <span>2023</span>) studied mucosal-associated invariant T cells (MAIT) (Godfrey et al., <span>2019</span>) in aplastic anemia (AA), a type of bone marrow failure directly linked to abnormal immune responses. MAIT cells exhibit an effector-memory phenotype and express several NK receptors such as NKG2D and CD161 and play an important role in the development of autoimmune diseases. The authors showed an increased frequency of MAIT cells with an activation and effector function-related cell surface marker profile in patients with aplastic anemia. 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Alternatively, these drugs might target the surface antigens expressed by tumor cells such as CD19 and CD22 in B-cell neoplasms. Of the latter, targeted immunotherapies include monoclonal antibodies with or without drug conjugates, bispecific T-cell engagers, or chimeric antigen receptor (CAR) T-cell therapy. The binding sites of these therapeutic antibodies are often identical or in proximity with the binding sites of the diagnostic antibodies. Therefore, use of these therapies pose great challenges for clinical cytometry labs in the assessment of post-treatment samples, especially in the detection of measurable/minimal residual disease (MRD). In this issue, Chen, Gao, et al. (<span>2023</span>) provided an overview of MRD detection in B-lymphoblastic leukemia/lymphoma in the era of immunotherapy, and Gao et al. (<span>2023</span>) focused their review on the impact of targeted therapy on mature B- and plasma cell neoplasms utilizing flow cytometry assessments. 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The authors recommended that the flow cytometry assays in the era of targeted therapies must contain significant redundancy in the antibody panels allowing the detection of the cells of interest and additionally should be ready to utilize several gating strategies for accurate and consistent population identification.</p><p>Neoplastic mature B-cells often show restricted kappa or lambda light chain expression; however, light chain expression may be absent in around 5%–10% of mature B-cell lymphoma (Li et al., <span>2002</span>). It is suggested that mature B-cells lacking surface light chain expression can be used as a surrogate marker to diagnose mature B-cell lymphomas. Huang et al. (<span>2023</span>) reported a series of 89 cases of surface light chain negative B-cell lymphoma which consisted primarily of chronic lymphocytic leukemia/small lymphocytic lymphoma (CLL/SLL). 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引用次数: 0

摘要

在个体化医疗时代,靶向治疗药物的清单得到了极大的扩展,其中许多药物被用于治疗血淋巴肿瘤。这些药物包括专门针对免疫检查点信号表位的药物,如程序性细胞死亡1 (PD1)及其配体PDL1,以抑制t细胞活化。或者,这些药物可能靶向肿瘤细胞表达的表面抗原,如b细胞肿瘤中的CD19和CD22。在后者中,靶向免疫治疗包括单克隆抗体(含或不含药物偶联物)、双特异性t细胞接合物或嵌合抗原受体(CAR) t细胞治疗。这些治疗性抗体的结合位点通常与诊断性抗体的结合位点相同或接近。因此,使用这些疗法对临床细胞实验室在评估治疗后样本时提出了巨大的挑战,特别是在检测可测量/微小残留疾病(MRD)时。在这一期中,Chen、Gao等人(2023)概述了免疫治疗时代B淋巴母细胞白血病/淋巴瘤的MRD检测,Gao等人(2023)利用流式细胞术评估了靶向治疗对成熟B细胞和浆细胞肿瘤的影响。在这两篇综述中,作者都阐述了挑战,确定了问题,并提供了可用选项和解决方案的列表。对于上述每种疾病类别,通过文献综述和作者的经验和见解,说明了最佳的门控和分析策略。研究了除CD19和CD20以外的其他b细胞标志物(如CD22、CD24和cCD79a)在成熟或未成熟b细胞肿瘤中的应用和解释(Mikhailova等人,2022),以及VS38、CD229和CD319 (Pojero等人,2016;Soh et al., 2021)对浆细胞肿瘤的影响。作者建议,在靶向治疗时代,流式细胞术检测必须在抗体组中包含重要的冗余,以便检测感兴趣的细胞,此外还应准备好利用几种门控策略来准确和一致地进行群体识别。肿瘤成熟b细胞常表现出kappa或lambda轻链表达受限;然而,在大约5%-10%的成熟b细胞淋巴瘤中可能没有轻链表达(Li et al., 2002)。提示缺乏表面轻链表达的成熟b细胞可作为诊断成熟b细胞淋巴瘤的替代标志物。Huang等(2023)报道了89例表面轻链阴性b细胞淋巴瘤,主要包括慢性淋巴细胞白血病/小淋巴细胞淋巴瘤(CLL/SLL)。有趣的是,作者还报告了从14例无临床和病理证据的淋巴瘤/白血病患者的体液和囊性液中收集的正常/反应性成熟B细胞中未检测到轻链表达。体液通常是蛋白质;因此,通常需要在kappa/lambda染色之前进行额外的洗涤,以获得足够的轻链染色,并且在解释从体液中收集的b细胞中的轻链表达时需要谨慎。众所周知,除慢性髓性白血病(CML)外(Soma et al., 2016),其他慢性髓性肿瘤,如骨髓增生异常综合征(MDS) (Xie et al., 2019)和费城阴性骨髓增生性肿瘤(MPN),淋巴母细胞危象极为罕见。Chan等人(2023)报道,在1262例MDS或ph阴性MPN中,有9例检测到低水平的异常b淋巴细胞,范围为0.012%至3.6%。细胞分选结合下一代测序表明,髓系肿瘤中异常的B淋巴母细胞通常(但并非总是)与髓系室克隆相关,分子遗传学结果表明,具有不同谱系输出的突变多能祖细胞可能由特定突变和突变发生的特定细胞阶段决定。重要的是,与CML不同,MDS和ph阴性mpn中存在异常b淋巴细胞并不一定表明母细胞危象,密切监测潜在髓系肿瘤的治疗被认为是一种合理的方法。这期的最后一篇文章(Chen, Zhang, et al., 2023)研究了再生障碍性贫血(AA)中的粘膜相关不变T细胞(MAIT) (Godfrey et al., 2019),再生障碍性贫血是一种与异常免疫反应直接相关的骨髓衰竭。MAIT细胞表现出效应记忆表型,表达多种NK受体,如NKG2D和CD161,并在自身免疫性疾病的发展中发挥重要作用。作者发现再生障碍性贫血患者中具有激活和效应功能相关的细胞表面标记谱的MAIT细胞的频率增加。 NKG2D在MAIT细胞上表达的特异性提示这些细胞可能在AA免疫发病机制中具有独特的参与机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Issue highlights—May 2023

Issue highlights—May 2023

In the era of personalized medicine, the list of targeted therapeutic drugs has been greatly expanded, many of which are employed to treat hematolymphoid neoplasms. These include drugs specifically targeting immune checkpoint signaling epitopes such as programmed cell death 1 (PD1) and its ligand PDL1 to inhibit T-cell activation. Alternatively, these drugs might target the surface antigens expressed by tumor cells such as CD19 and CD22 in B-cell neoplasms. Of the latter, targeted immunotherapies include monoclonal antibodies with or without drug conjugates, bispecific T-cell engagers, or chimeric antigen receptor (CAR) T-cell therapy. The binding sites of these therapeutic antibodies are often identical or in proximity with the binding sites of the diagnostic antibodies. Therefore, use of these therapies pose great challenges for clinical cytometry labs in the assessment of post-treatment samples, especially in the detection of measurable/minimal residual disease (MRD). In this issue, Chen, Gao, et al. (2023) provided an overview of MRD detection in B-lymphoblastic leukemia/lymphoma in the era of immunotherapy, and Gao et al. (2023) focused their review on the impact of targeted therapy on mature B- and plasma cell neoplasms utilizing flow cytometry assessments. In both reviews, the authors illustrated the challenges, identified the problems, and provided a list of available options and solutions. For each of the above-mentioned disease categories, optimal gating and analysis strategies were illustrated with literature review and inputs from the authors' experience and insights. The utility and interpretation of additional B-cell markers other than CD19 and CD20 for mature or immature B-cell neoplasms such as CD22, CD24, and cCD79a (Mikhailova et al., 2022) were studied as well as VS38, CD229, and CD319 (Pojero et al., 2016; Soh et al., 2021) for plasma cell neoplasms. The authors recommended that the flow cytometry assays in the era of targeted therapies must contain significant redundancy in the antibody panels allowing the detection of the cells of interest and additionally should be ready to utilize several gating strategies for accurate and consistent population identification.

Neoplastic mature B-cells often show restricted kappa or lambda light chain expression; however, light chain expression may be absent in around 5%–10% of mature B-cell lymphoma (Li et al., 2002). It is suggested that mature B-cells lacking surface light chain expression can be used as a surrogate marker to diagnose mature B-cell lymphomas. Huang et al. (2023) reported a series of 89 cases of surface light chain negative B-cell lymphoma which consisted primarily of chronic lymphocytic leukemia/small lymphocytic lymphoma (CLL/SLL). Interestingly, the authors also reported no detectable light chain expression in normal/reactive mature B cells collected from body fluids and cystic fluids from 14 patients with no clinical and pathological evidence of lymphoma/leukemia. Body fluids are often proteaceous; thus additional washing prior to kappa/lambda staining is often required to obtain adequate light chain staining and caution is needed in the interpretation of light chain expression in B-cells collected from body fluids. It is known that out of the context of chronic myeloid leukemia (CML) (Soma et al., 2016), lymphoblastic crisis is extremely rare in other chronic myeloid neoplasms, such as myelodysplastic syndrome (MDS) (Xie et al., 2019) and Philadelphia negative myeloproliferative neoplasms (MPN). Chan et al. (2023) reported the detection of a low level of abnormal B-lymphoblasts ranging from 0.012% to 3.6% in 9 out of 1262 MDS or Ph-negative MPN. Cell sorting coupled with next-generational sequencing showed that the abnormal B- lymphoblasts in myeloid neoplasms were often, but not always, clonally related to the myeloid compartment, and the molecular genetic findings suggested a mutant multipotent progenitor cell with different lineage output that might be determined by the specific mutations and the particular cell stage where the mutations occurred. Importantly, unlike CML, the presence of abnormal B-lymphoblasts in MDS and Ph-neg MPNs did not necessarily indicate blast crisis, and therapy for the underlying myeloid neoplasms with close monitoring is suggested to be a reasonable approach.

The last article in this issue (Chen, Zhang, et al., 2023) studied mucosal-associated invariant T cells (MAIT) (Godfrey et al., 2019) in aplastic anemia (AA), a type of bone marrow failure directly linked to abnormal immune responses. MAIT cells exhibit an effector-memory phenotype and express several NK receptors such as NKG2D and CD161 and play an important role in the development of autoimmune diseases. The authors showed an increased frequency of MAIT cells with an activation and effector function-related cell surface marker profile in patients with aplastic anemia. The specific property of NKG2D expression on MAIT cells suggests that these cells may have a distinct mechanism involved in AA immune pathogenesis.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
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2.10%
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