{"title":"问题亮点- 2023年7月","authors":"Wolfgang Kern","doi":"10.1002/cyto.b.22138","DOIUrl":null,"url":null,"abstract":"<p>Diagnostic techniques within hematology are becoming more sensitive and measurable residual disease (MRD) is gaining importance as a result—for both diagnosticians and patients. MRD measurement is increasingly used as a study endpoint in clinical trials and also in routine diagnostics—and as a strong predictor of treatment outcome. Currently, more sensitive and specific methods of measurement are in development. Besides molecular assays, flow cytometry is one of the most frequently used methods for MRD assessment due to its shorter turnaround time, its cost-effectiveness, and broader applicability.</p><p>In this issue, several researchers have delved into various aspects of flow cytometry techniques being used for MRD detection within hematological malignancies. Gao et al. introduced a single tube flow cytometry assay with high sensitivity for monitoring MRD in B-lymphoblastic leukemia/lymphoma (B-ALL), independent of specific surface antigen expression like CD19 and CD22. As the authors point out, the development of such assays has become relevant due to the emergence of targeted anti-CD19 and anti-CD22 therapies (Gao, Chen, et al., <span>2023</span>; Gao, Liu, et al., <span>2023</span>). Targeted immunotherapy demonstrated encouraging results in recent years but induces significant changes in the phenotype of leukemic blasts concurrently. Therefore, alternative gating strategies have gained importance and potential CD19 substitutes have been proposed (Chen et al., <span>2023</span>; Mikhailova et al., <span>2022</span>).</p><p>The development of alternative gating strategies is also relevant independently of targeted therapies, as shown by the authors of the next article. In a rare case study, Ramalingam et al. reported a patient with CD19-negative diffuse large B-cell lymphoma (DLBCL). Since CD19 is currently the primary gating marker for B cell neoplasms, its absence may lead to erroneous results and potentially affect therapeutic strategies, so the authors (Ramalingam et al., <span>2022</span>). Challenges for flow cytometry approaches have been studied before (Gao, Chen, et al., <span>2023</span>; Gao, Liu, et al., <span>2023</span>; Huang et al., <span>2023</span>; Martig & Fromm, <span>2022</span>).</p><p>In MRD detection, the avoidance of false positives is crucial as shown by Zhou et al. The authors discussed the pitfalls in MRD detection in B-ALL following targeted immunotherapy, describing the presence of two CD22-positive non-neoplastic cell populations. One progenitor population of uncertain lineage and one mature B-cell population were both immunophenotypic mimics of B-ALL. Zhou et al. concluded that an understanding of these normal cell populations is essential to avoid misinterpretation in MRD assessments and CD19-independent gating strategies, including CD22 and CD24, are key (Zhou et al., <span>2022</span>). Optimizing MRD measurement is at the forefront of numerous studies and alternative antigens (besides CD22 and CD24 also iCD79a) or radar plots and a flow cytometry scoring system for predicting <i>ZNF384</i> rearrangements have been suggested (Mikhailova et al., <span>2022</span>; Shopsowitz et al., <span>2022</span>; Wang et al., <span>2022</span>).</p><p>As the next article depicts, MRD measurement and its optimization plays a significant role not only in lymphoid but also in myeloid neoplasms. Since MRD analysis is not yet included in routine diagnostics in the United Kingdom, McMillan et al. adapted and validated a multicolor flow cytometry (MCF) assay for multiple myeloma (MM) MRD, allowing widespread usage of this assay in smaller laboratories for real-world practice (McMillan et al., <span>2022</span>). Achieving MRD negativity in MM is crucial for improved patient outcomes. In newly diagnosed and relapsed MM, a high percentage of BCMA-positive abnormal plasma cells was found, supporting its potential as a target for CAR-T cell and monoclonal-antibody therapies (Sriram et al., <span>2022</span>). Aberrancies in polyclonal plasma cells and immunomodulation in neoplastic plasma cells post-therapy were identified in another study, underscoring the importance of validating MRD assays under normal and reactive conditions (Das et al., <span>2022</span>). A consensus protocol has been proposed to reduce inter-laboratory variation in MM MRD reporting, leading to improved consistency. This harmonized approach makes MM MRD a potential surrogate clinical endpoint for assessing progression-free and overall survival in clinical trials (Soh et al., <span>2022</span>).</p><p>Hsu et al. investigated the impact of Down syndrome-specific non-malignant hematopoietic regeneration on MRD detection in myeloid leukemia associated with Down syndrome (ML-DS). The presence of DS-specific myeloid progenitors in the bone marrow can complicate MRD interpretations in ML-DS patients. Therefore, its awareness is essential to the MRD detection, the authors postulate (Hsu et al., <span>2023</span>).</p><p>The last article in this issue, Jurado et al. focused on optimizing the monocyte gating strategy for diagnosing chronic myelomonocytic leukemia (CMML). They proposed a 10-color tube and computational analysis to improve the reproducibility of monocyte subset quantification (Jurado et al., <span>2022</span>). Further studies highlight the robustness of the “monocyte assay” for CMML diagnosis, the complexities in distinguishing CMML from blastic plasmacytoid dendritic cell neoplasm (BPDCN), and the potential of immunophenotypic analysis in differentiating CMML from reactive monocytosis (Espasa et al., <span>2021</span>; Feng et al., <span>2018</span>; Wagner-Ballon et al., <span>2023</span>).</p><p>In conclusion, the highlighted articles in this issue contribute valuable insights into the ongoing efforts to develop sensitive diagnostic tools for MRD detection, address potential diagnostic challenges, and implement strategies to enhance the accuracy of MRD assessments in various hematological malignancies. These advancements hold great promise for improving patient outcomes and guiding treatment decisions in the field of hematology.</p>","PeriodicalId":2,"journal":{"name":"ACS Applied Bio Materials","volume":null,"pages":null},"PeriodicalIF":4.6000,"publicationDate":"2023-08-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/cyto.b.22138","citationCount":"0","resultStr":"{\"title\":\"Issue highlights—July 2023\",\"authors\":\"Wolfgang Kern\",\"doi\":\"10.1002/cyto.b.22138\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Diagnostic techniques within hematology are becoming more sensitive and measurable residual disease (MRD) is gaining importance as a result—for both diagnosticians and patients. MRD measurement is increasingly used as a study endpoint in clinical trials and also in routine diagnostics—and as a strong predictor of treatment outcome. Currently, more sensitive and specific methods of measurement are in development. Besides molecular assays, flow cytometry is one of the most frequently used methods for MRD assessment due to its shorter turnaround time, its cost-effectiveness, and broader applicability.</p><p>In this issue, several researchers have delved into various aspects of flow cytometry techniques being used for MRD detection within hematological malignancies. Gao et al. introduced a single tube flow cytometry assay with high sensitivity for monitoring MRD in B-lymphoblastic leukemia/lymphoma (B-ALL), independent of specific surface antigen expression like CD19 and CD22. As the authors point out, the development of such assays has become relevant due to the emergence of targeted anti-CD19 and anti-CD22 therapies (Gao, Chen, et al., <span>2023</span>; Gao, Liu, et al., <span>2023</span>). Targeted immunotherapy demonstrated encouraging results in recent years but induces significant changes in the phenotype of leukemic blasts concurrently. Therefore, alternative gating strategies have gained importance and potential CD19 substitutes have been proposed (Chen et al., <span>2023</span>; Mikhailova et al., <span>2022</span>).</p><p>The development of alternative gating strategies is also relevant independently of targeted therapies, as shown by the authors of the next article. In a rare case study, Ramalingam et al. reported a patient with CD19-negative diffuse large B-cell lymphoma (DLBCL). Since CD19 is currently the primary gating marker for B cell neoplasms, its absence may lead to erroneous results and potentially affect therapeutic strategies, so the authors (Ramalingam et al., <span>2022</span>). Challenges for flow cytometry approaches have been studied before (Gao, Chen, et al., <span>2023</span>; Gao, Liu, et al., <span>2023</span>; Huang et al., <span>2023</span>; Martig & Fromm, <span>2022</span>).</p><p>In MRD detection, the avoidance of false positives is crucial as shown by Zhou et al. The authors discussed the pitfalls in MRD detection in B-ALL following targeted immunotherapy, describing the presence of two CD22-positive non-neoplastic cell populations. One progenitor population of uncertain lineage and one mature B-cell population were both immunophenotypic mimics of B-ALL. Zhou et al. concluded that an understanding of these normal cell populations is essential to avoid misinterpretation in MRD assessments and CD19-independent gating strategies, including CD22 and CD24, are key (Zhou et al., <span>2022</span>). Optimizing MRD measurement is at the forefront of numerous studies and alternative antigens (besides CD22 and CD24 also iCD79a) or radar plots and a flow cytometry scoring system for predicting <i>ZNF384</i> rearrangements have been suggested (Mikhailova et al., <span>2022</span>; Shopsowitz et al., <span>2022</span>; Wang et al., <span>2022</span>).</p><p>As the next article depicts, MRD measurement and its optimization plays a significant role not only in lymphoid but also in myeloid neoplasms. Since MRD analysis is not yet included in routine diagnostics in the United Kingdom, McMillan et al. adapted and validated a multicolor flow cytometry (MCF) assay for multiple myeloma (MM) MRD, allowing widespread usage of this assay in smaller laboratories for real-world practice (McMillan et al., <span>2022</span>). Achieving MRD negativity in MM is crucial for improved patient outcomes. In newly diagnosed and relapsed MM, a high percentage of BCMA-positive abnormal plasma cells was found, supporting its potential as a target for CAR-T cell and monoclonal-antibody therapies (Sriram et al., <span>2022</span>). Aberrancies in polyclonal plasma cells and immunomodulation in neoplastic plasma cells post-therapy were identified in another study, underscoring the importance of validating MRD assays under normal and reactive conditions (Das et al., <span>2022</span>). A consensus protocol has been proposed to reduce inter-laboratory variation in MM MRD reporting, leading to improved consistency. This harmonized approach makes MM MRD a potential surrogate clinical endpoint for assessing progression-free and overall survival in clinical trials (Soh et al., <span>2022</span>).</p><p>Hsu et al. investigated the impact of Down syndrome-specific non-malignant hematopoietic regeneration on MRD detection in myeloid leukemia associated with Down syndrome (ML-DS). The presence of DS-specific myeloid progenitors in the bone marrow can complicate MRD interpretations in ML-DS patients. Therefore, its awareness is essential to the MRD detection, the authors postulate (Hsu et al., <span>2023</span>).</p><p>The last article in this issue, Jurado et al. focused on optimizing the monocyte gating strategy for diagnosing chronic myelomonocytic leukemia (CMML). They proposed a 10-color tube and computational analysis to improve the reproducibility of monocyte subset quantification (Jurado et al., <span>2022</span>). Further studies highlight the robustness of the “monocyte assay” for CMML diagnosis, the complexities in distinguishing CMML from blastic plasmacytoid dendritic cell neoplasm (BPDCN), and the potential of immunophenotypic analysis in differentiating CMML from reactive monocytosis (Espasa et al., <span>2021</span>; Feng et al., <span>2018</span>; Wagner-Ballon et al., <span>2023</span>).</p><p>In conclusion, the highlighted articles in this issue contribute valuable insights into the ongoing efforts to develop sensitive diagnostic tools for MRD detection, address potential diagnostic challenges, and implement strategies to enhance the accuracy of MRD assessments in various hematological malignancies. 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引用次数: 0
摘要
血液学的诊断技术正变得越来越敏感,可测量的残余疾病(MRD)对诊断医生和患者都越来越重要。MRD测量越来越多地被用作临床试验和常规诊断的研究终点,并作为治疗结果的有力预测指标。目前,更敏感和具体的测量方法正在开发中。除了分子分析,流式细胞术是最常用的MRD评估方法之一,因为它的周转时间短,成本效益高,适用性广。在这一期中,几位研究人员深入研究了流式细胞术技术在血液恶性肿瘤中用于MRD检测的各个方面。Gao等人介绍了一种高灵敏度的单管流式细胞术检测方法,用于监测b淋巴细胞白血病/淋巴瘤(B-ALL)的MRD,不依赖于CD19和CD22等特异性表面抗原的表达。正如作者所指出的,由于靶向抗cd19和抗cd22疗法的出现,这种检测方法的发展已经变得相关(Gao, Chen等,2023;高,刘,等,2023)。靶向免疫治疗近年来显示出令人鼓舞的结果,但同时诱导白血病母细胞表型的显着变化。因此,替代门控策略变得越来越重要,并提出了潜在的CD19替代品(Chen et al., 2023;Mikhailova et al., 2022)。正如下一篇文章的作者所示,替代门控策略的发展也与靶向治疗无关。在一个罕见的病例研究中,Ramalingam等人报道了一例cd19阴性弥漫性大b细胞淋巴瘤(DLBCL)患者。由于CD19目前是B细胞肿瘤的主要门控标志物,缺乏它可能导致错误的结果,并可能影响治疗策略,因此作者(Ramalingam et al., 2022)。之前已经研究过流式细胞术方法面临的挑战(Gao, Chen等,2023;高,刘等,2023;黄等人,2023;Martig,弗洛姆,2022)。在MRD检测中,如Zhou等人所示,避免假阳性是至关重要的。作者讨论了靶向免疫治疗后B-ALL MRD检测的缺陷,描述了两种cd22阳性非肿瘤细胞群的存在。一个谱系不确定的祖细胞群体和一个成熟的b细胞群体都是B-ALL的免疫表型模拟者。Zhou等人得出结论,了解这些正常细胞群对于避免MRD评估中的误解至关重要,而CD22和CD24等cd19独立门控策略是关键(Zhou等人,2022)。优化MRD测量是众多研究的前沿,已经提出了用于预测ZNF384重排的替代抗原(除了CD22和CD24之外,还有iCD79a)或雷达图和流式细胞术评分系统(Mikhailova等人,2022;Shopsowitz et al., 2022;Wang et al., 2022)。正如下一篇文章所描述的,MRD测量及其优化不仅在淋巴肿瘤中而且在髓系肿瘤中起着重要作用。由于MRD分析尚未包括在英国的常规诊断中,McMillan等人采用并验证了多发性骨髓瘤(MM) MRD的多色流式细胞术(MCF)检测方法,允许在较小的实验室中广泛使用该检测方法进行现实实践(McMillan等人,2022)。在MM中实现MRD阴性对于改善患者预后至关重要。在新诊断和复发的MM中,发现bcma阳性的异常浆细胞比例很高,支持其作为CAR-T细胞和单克隆抗体治疗靶点的潜力(Sriram et al., 2022)。另一项研究发现多克隆浆细胞和肿瘤浆细胞治疗后的免疫调节异常,强调了在正常和反应性条件下验证MRD分析的重要性(Das等,2022)。已经提出了一个共识协议,以减少MM MRD报告的实验室间差异,从而提高一致性。这种统一的方法使MM MRD成为临床试验中评估无进展和总生存期的潜在替代临床终点(Soh等人,2022)。Hsu等人研究了唐氏综合征特异性非恶性造血再生对唐氏综合征相关髓性白血病(ML-DS) MRD检测的影响。骨髓中ds特异性髓系祖细胞的存在会使ML-DS患者的MRD解释复杂化。因此,作者假设,其意识对MRD检测至关重要(Hsu et al., 2023)。在这期的最后一篇文章中,Jurado等人着重于优化单核细胞门控策略诊断慢性髓单细胞白血病(CMML)。 他们提出了一种10色管和计算分析来提高单核细胞亚群定量的可重复性(Jurado et al., 2022)。进一步的研究强调了“单核细胞试验”诊断CMML的稳健性,区分CMML与母浆细胞样树突状细胞肿瘤(BPDCN)的复杂性,以及免疫表型分析在区分CMML与反应性单核细胞增多症方面的潜力(Espasa等,2021;Feng et al., 2018;Wagner-Ballon et al., 2023)。总之,本期的重点文章为开发MRD检测的敏感诊断工具、解决潜在的诊断挑战和实施策略以提高各种血液恶性肿瘤MRD评估的准确性提供了有价值的见解。这些进步对改善血液学领域的患者预后和指导治疗决策具有很大的希望。
Diagnostic techniques within hematology are becoming more sensitive and measurable residual disease (MRD) is gaining importance as a result—for both diagnosticians and patients. MRD measurement is increasingly used as a study endpoint in clinical trials and also in routine diagnostics—and as a strong predictor of treatment outcome. Currently, more sensitive and specific methods of measurement are in development. Besides molecular assays, flow cytometry is one of the most frequently used methods for MRD assessment due to its shorter turnaround time, its cost-effectiveness, and broader applicability.
In this issue, several researchers have delved into various aspects of flow cytometry techniques being used for MRD detection within hematological malignancies. Gao et al. introduced a single tube flow cytometry assay with high sensitivity for monitoring MRD in B-lymphoblastic leukemia/lymphoma (B-ALL), independent of specific surface antigen expression like CD19 and CD22. As the authors point out, the development of such assays has become relevant due to the emergence of targeted anti-CD19 and anti-CD22 therapies (Gao, Chen, et al., 2023; Gao, Liu, et al., 2023). Targeted immunotherapy demonstrated encouraging results in recent years but induces significant changes in the phenotype of leukemic blasts concurrently. Therefore, alternative gating strategies have gained importance and potential CD19 substitutes have been proposed (Chen et al., 2023; Mikhailova et al., 2022).
The development of alternative gating strategies is also relevant independently of targeted therapies, as shown by the authors of the next article. In a rare case study, Ramalingam et al. reported a patient with CD19-negative diffuse large B-cell lymphoma (DLBCL). Since CD19 is currently the primary gating marker for B cell neoplasms, its absence may lead to erroneous results and potentially affect therapeutic strategies, so the authors (Ramalingam et al., 2022). Challenges for flow cytometry approaches have been studied before (Gao, Chen, et al., 2023; Gao, Liu, et al., 2023; Huang et al., 2023; Martig & Fromm, 2022).
In MRD detection, the avoidance of false positives is crucial as shown by Zhou et al. The authors discussed the pitfalls in MRD detection in B-ALL following targeted immunotherapy, describing the presence of two CD22-positive non-neoplastic cell populations. One progenitor population of uncertain lineage and one mature B-cell population were both immunophenotypic mimics of B-ALL. Zhou et al. concluded that an understanding of these normal cell populations is essential to avoid misinterpretation in MRD assessments and CD19-independent gating strategies, including CD22 and CD24, are key (Zhou et al., 2022). Optimizing MRD measurement is at the forefront of numerous studies and alternative antigens (besides CD22 and CD24 also iCD79a) or radar plots and a flow cytometry scoring system for predicting ZNF384 rearrangements have been suggested (Mikhailova et al., 2022; Shopsowitz et al., 2022; Wang et al., 2022).
As the next article depicts, MRD measurement and its optimization plays a significant role not only in lymphoid but also in myeloid neoplasms. Since MRD analysis is not yet included in routine diagnostics in the United Kingdom, McMillan et al. adapted and validated a multicolor flow cytometry (MCF) assay for multiple myeloma (MM) MRD, allowing widespread usage of this assay in smaller laboratories for real-world practice (McMillan et al., 2022). Achieving MRD negativity in MM is crucial for improved patient outcomes. In newly diagnosed and relapsed MM, a high percentage of BCMA-positive abnormal plasma cells was found, supporting its potential as a target for CAR-T cell and monoclonal-antibody therapies (Sriram et al., 2022). Aberrancies in polyclonal plasma cells and immunomodulation in neoplastic plasma cells post-therapy were identified in another study, underscoring the importance of validating MRD assays under normal and reactive conditions (Das et al., 2022). A consensus protocol has been proposed to reduce inter-laboratory variation in MM MRD reporting, leading to improved consistency. This harmonized approach makes MM MRD a potential surrogate clinical endpoint for assessing progression-free and overall survival in clinical trials (Soh et al., 2022).
Hsu et al. investigated the impact of Down syndrome-specific non-malignant hematopoietic regeneration on MRD detection in myeloid leukemia associated with Down syndrome (ML-DS). The presence of DS-specific myeloid progenitors in the bone marrow can complicate MRD interpretations in ML-DS patients. Therefore, its awareness is essential to the MRD detection, the authors postulate (Hsu et al., 2023).
The last article in this issue, Jurado et al. focused on optimizing the monocyte gating strategy for diagnosing chronic myelomonocytic leukemia (CMML). They proposed a 10-color tube and computational analysis to improve the reproducibility of monocyte subset quantification (Jurado et al., 2022). Further studies highlight the robustness of the “monocyte assay” for CMML diagnosis, the complexities in distinguishing CMML from blastic plasmacytoid dendritic cell neoplasm (BPDCN), and the potential of immunophenotypic analysis in differentiating CMML from reactive monocytosis (Espasa et al., 2021; Feng et al., 2018; Wagner-Ballon et al., 2023).
In conclusion, the highlighted articles in this issue contribute valuable insights into the ongoing efforts to develop sensitive diagnostic tools for MRD detection, address potential diagnostic challenges, and implement strategies to enhance the accuracy of MRD assessments in various hematological malignancies. These advancements hold great promise for improving patient outcomes and guiding treatment decisions in the field of hematology.