{"title":"Where diagnosis for myelodysplastic neoplasms (MDS) stands today and where it will go: The role of flow cytometry in evaluation of MDS","authors":"Wei Wang, Joseph D. Khoury","doi":"10.1002/cyto.b.22110","DOIUrl":null,"url":null,"abstract":"<p>Myelodysplastic neoplasms (MDS) are clonal hematopoietic neoplasms defined by cytopenias and morphologic dysplasia. This definition distinguishes MDS from clonal hematopoiesis of indeterminate potential (CHIP) and clonal cytopenia of undetermined significance (CCUS) wherein a patient harbors a somatic mutation involving a myeloid malignancy-associated gene in the absence of cytopenia and, in case of CCUS, dysplasia (Khoury et al., <span>2022</span>). As such, the diagnostic framework for MDS relies on the detection of morphologic dysplasia in bone marrow cells coupled with evidence of clonality in patients with cytopenia.</p><p>While the features of dysplasia in hematopoietic lineages have been long established, assessment is subjective and limited by inter-observer variability particularly in cases with mild morphologic changes. In addition, several non-neoplastic conditions give rise to dysplastic changes that can overlap markedly with those seen in MDS. Examples of such conditions include nutritional deficiencies, toxins, and exposure to various treatments. In view of the challenges inherent in dysplasia assessment, demonstration of clonality in a patient with cytopenia is critical to establishing a diagnosis of MDS, especially in lower-risk disease with no excess of blasts. Establishing clonality has long rested on detection of cytogenetic abnormalities using conventional karyotyping and/or fluorescence in situ hybridization (FISH). Beyond establishing evidence of clonality, cytogenetic studies also play an important role in risk stratification (Greenberg et al., <span>2012</span>), and some cytogenetic abnormalities correlate with distinct morphological and clinical features such as those of <i>MDS with low blasts and 5q deletion</i>. Yet, the problem of using cytogenetic abnormalities in the diagnostic workup of MDS is that they are detected in only up to 50% of MDS cases. In cases with normal cytogenetic findings, other tools are needed to demonstrate clonality and establish the diagnosis of MDS. Mutation profiling using next-generation sequencing (NGS) demonstrates somatic mutations in 80%–90% of MDS cases (Ogawa, <span>2019</span>), providing substantial value in diagnostic assessment and establishing the presence of clonality. Here too, beyond establishing evidence of clonality, mutation profiling studies also play an important role in risk stratification, and some gene abnormalities are required to diagnose certain MDS types with defining genetic abnormalities such as <i>MDS with low blasts and SF3B1 mutation</i> and <i>MDS with biallelic TP53 inactivation</i> (Bernard et al., <span>2022</span>; Khoury et al., <span>2022</span>; Malcovati et al., <span>2020</span>). However, a persistent caveat is that CHIP and CCUS can also occur in otherwise healthy elderly individuals (Jaiswal et al., <span>2014</span>), requiring caution in interpreting the significance of certain mutations, especially those that are well known age-related mutations (such as <i>DNMT3A</i>, <i>TET2</i>, and <i>ASXL1</i>). On that basis, MDS-associated somatic mutations alone are not per se diagnostic of MDS. Against this background, flow cytometry analysis has emerged in recent years as another valuable tool for MDS workup and the evaluation of cytopenic patients, as recommended in the European LeukemiaNet guidelines (van de Loosdrecht et al., <span>2023</span>).</p><p>Although no universal consensus on the optimal flow cytometry approach for MDS has been established to date, the diagnostic utility of flow cytometry in the evaluation of MDS patients has been the subject of several systematic analyses. In a recent study by Oelschlaegel et al., the analytic performance characteristics of five flow cytometry scoring systems were assessed and showed different specificity and sensitivity (Oelschlaegel et al., <span>2021</span>). When using flow cytometry to evaluate for MDS, various cell subsets can be interrogated to assess aberrant antigen expression and/or maturation patterns, including myeloid progenitors, B-cell progenitors, as well as maturing granulocytic, monocytic and erythroid cells. Among these, based on our experience (Sanz-De Pedro et al., <span>2018</span>) and the experience of others (van de Loosdrecht et al., <span>2023</span>), the evaluation of CD34+ myeloid precursors offers more reliable and specific results than the evaluation of other cell types. Conceptually, this is not unexpected given that MDS is inherently a hematopoietic stem cell disease, and such cells are enriched within the CD34+ myeloid precursor compartment. Further adding to their utility is the fact that CD34+ myeloid precursors tend to have a more stable immunophenotype in comparison to maturing cells and are less affected by reactive conditions or pre-analytic factors. This contrasts with granulocytes and monocytes whose antigen expression and maturation patterns can be impacted by aging samples, sample hemodilution, reactive conditions, or the presence of a paroxysmal nocturnal hemoglobinuria (PNH) clone (van der Velden et al., <span>2023</span>; Westers et al., <span>2021</span>). In the appropriate clinical setting and appropriate sample quality control, however, the evaluation of maturing myelomonocytic and erythroid components provides valuable information especially in cases with limited number of CD34+ cells or cases with subtle phenotypic abnormalities in the CD34+ compartment. In summary, although it is widely recognized that flow cytometry findings alone are not sufficient to establish a definitive diagnosis of MDS, the detection of immunophenotypic aberrancies in CD34-positive myeloid precursors and maturing hematopoietic cells provides valuable ancillary support in conjunction with morphologic, cytogenetic, and molecular assessment in patients presenting with cytopenia.</p><p>Immunophenotypic alterations in the CD34+ myeloid compartment commonly used to indicate aberrancy include: (1) <i>altered intensities of expression</i>, such as increased expression of CD13, CD117 and CD123, and decreased expression of CD38 and HLA-DR; (2) <i>altered patterns of maturation/differentiation</i>, such as high expression of CD13 or CD117 in CD38 + dim very early precursors; (3) <i>aberrant expression of lymphoid antigens</i>, such as CD5, CD7, and CD56; and (4) <i>asynchronous expression of mature myelomonocytic antigens</i>, such as CD10, CD15, and CD64 in CD38 + dim very early precursors. Although increased numbers of CD34+ myeloid precursors and/or decreased numbers of early B-cell precursors (stage 1 hematogones) have been used to indicate abnormality in the evaluation of MDS (Oelschlaegel et al., <span>2021</span>), such findings should be interpreted with caution as some patients, especially those with <i>SF3B1</i> mutation, can have preserved hematogones (Chen et al., <span>2020</span>). Similarly, CD34+ myeloid precursors can be increased in non-neoplastic conditions and due to growth factor administration. Other limitations—none of which are exclusive to flow cytometry—include the absence of detectable aberrations in a small subset of MDS cases, reliance on live cells, and the need for interpretation expertise.</p><p>In summary, flow cytometry has contributed significantly to the workup of MDS patients, with demonstrable value, reliability, and accuracy in clinical practice (Kern et al., <span>2023</span>; Oelschlaegel et al., <span>2021</span>; Westers et al., <span>2023</span>). Compared to cytogenetic studies and mutational profiling, flow cytometric analysis has a much shorter turnaround time and can provide diagnostic value in cases with normal cytogenetics and equivocal molecular findings. Thus, we recommend that flow cytometric analysis should be included as a component of the evaluation of patients with cytopenias alongside cytogenetic studies and NGS-based mutation profiling.</p>","PeriodicalId":2,"journal":{"name":"ACS Applied Bio Materials","volume":null,"pages":null},"PeriodicalIF":4.6000,"publicationDate":"2022-12-27","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/cyto.b.22110","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"ACS Applied Bio Materials","FirstCategoryId":"3","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/cyto.b.22110","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"MATERIALS SCIENCE, BIOMATERIALS","Score":null,"Total":0}
引用次数: 1
Abstract
Myelodysplastic neoplasms (MDS) are clonal hematopoietic neoplasms defined by cytopenias and morphologic dysplasia. This definition distinguishes MDS from clonal hematopoiesis of indeterminate potential (CHIP) and clonal cytopenia of undetermined significance (CCUS) wherein a patient harbors a somatic mutation involving a myeloid malignancy-associated gene in the absence of cytopenia and, in case of CCUS, dysplasia (Khoury et al., 2022). As such, the diagnostic framework for MDS relies on the detection of morphologic dysplasia in bone marrow cells coupled with evidence of clonality in patients with cytopenia.
While the features of dysplasia in hematopoietic lineages have been long established, assessment is subjective and limited by inter-observer variability particularly in cases with mild morphologic changes. In addition, several non-neoplastic conditions give rise to dysplastic changes that can overlap markedly with those seen in MDS. Examples of such conditions include nutritional deficiencies, toxins, and exposure to various treatments. In view of the challenges inherent in dysplasia assessment, demonstration of clonality in a patient with cytopenia is critical to establishing a diagnosis of MDS, especially in lower-risk disease with no excess of blasts. Establishing clonality has long rested on detection of cytogenetic abnormalities using conventional karyotyping and/or fluorescence in situ hybridization (FISH). Beyond establishing evidence of clonality, cytogenetic studies also play an important role in risk stratification (Greenberg et al., 2012), and some cytogenetic abnormalities correlate with distinct morphological and clinical features such as those of MDS with low blasts and 5q deletion. Yet, the problem of using cytogenetic abnormalities in the diagnostic workup of MDS is that they are detected in only up to 50% of MDS cases. In cases with normal cytogenetic findings, other tools are needed to demonstrate clonality and establish the diagnosis of MDS. Mutation profiling using next-generation sequencing (NGS) demonstrates somatic mutations in 80%–90% of MDS cases (Ogawa, 2019), providing substantial value in diagnostic assessment and establishing the presence of clonality. Here too, beyond establishing evidence of clonality, mutation profiling studies also play an important role in risk stratification, and some gene abnormalities are required to diagnose certain MDS types with defining genetic abnormalities such as MDS with low blasts and SF3B1 mutation and MDS with biallelic TP53 inactivation (Bernard et al., 2022; Khoury et al., 2022; Malcovati et al., 2020). However, a persistent caveat is that CHIP and CCUS can also occur in otherwise healthy elderly individuals (Jaiswal et al., 2014), requiring caution in interpreting the significance of certain mutations, especially those that are well known age-related mutations (such as DNMT3A, TET2, and ASXL1). On that basis, MDS-associated somatic mutations alone are not per se diagnostic of MDS. Against this background, flow cytometry analysis has emerged in recent years as another valuable tool for MDS workup and the evaluation of cytopenic patients, as recommended in the European LeukemiaNet guidelines (van de Loosdrecht et al., 2023).
Although no universal consensus on the optimal flow cytometry approach for MDS has been established to date, the diagnostic utility of flow cytometry in the evaluation of MDS patients has been the subject of several systematic analyses. In a recent study by Oelschlaegel et al., the analytic performance characteristics of five flow cytometry scoring systems were assessed and showed different specificity and sensitivity (Oelschlaegel et al., 2021). When using flow cytometry to evaluate for MDS, various cell subsets can be interrogated to assess aberrant antigen expression and/or maturation patterns, including myeloid progenitors, B-cell progenitors, as well as maturing granulocytic, monocytic and erythroid cells. Among these, based on our experience (Sanz-De Pedro et al., 2018) and the experience of others (van de Loosdrecht et al., 2023), the evaluation of CD34+ myeloid precursors offers more reliable and specific results than the evaluation of other cell types. Conceptually, this is not unexpected given that MDS is inherently a hematopoietic stem cell disease, and such cells are enriched within the CD34+ myeloid precursor compartment. Further adding to their utility is the fact that CD34+ myeloid precursors tend to have a more stable immunophenotype in comparison to maturing cells and are less affected by reactive conditions or pre-analytic factors. This contrasts with granulocytes and monocytes whose antigen expression and maturation patterns can be impacted by aging samples, sample hemodilution, reactive conditions, or the presence of a paroxysmal nocturnal hemoglobinuria (PNH) clone (van der Velden et al., 2023; Westers et al., 2021). In the appropriate clinical setting and appropriate sample quality control, however, the evaluation of maturing myelomonocytic and erythroid components provides valuable information especially in cases with limited number of CD34+ cells or cases with subtle phenotypic abnormalities in the CD34+ compartment. In summary, although it is widely recognized that flow cytometry findings alone are not sufficient to establish a definitive diagnosis of MDS, the detection of immunophenotypic aberrancies in CD34-positive myeloid precursors and maturing hematopoietic cells provides valuable ancillary support in conjunction with morphologic, cytogenetic, and molecular assessment in patients presenting with cytopenia.
Immunophenotypic alterations in the CD34+ myeloid compartment commonly used to indicate aberrancy include: (1) altered intensities of expression, such as increased expression of CD13, CD117 and CD123, and decreased expression of CD38 and HLA-DR; (2) altered patterns of maturation/differentiation, such as high expression of CD13 or CD117 in CD38 + dim very early precursors; (3) aberrant expression of lymphoid antigens, such as CD5, CD7, and CD56; and (4) asynchronous expression of mature myelomonocytic antigens, such as CD10, CD15, and CD64 in CD38 + dim very early precursors. Although increased numbers of CD34+ myeloid precursors and/or decreased numbers of early B-cell precursors (stage 1 hematogones) have been used to indicate abnormality in the evaluation of MDS (Oelschlaegel et al., 2021), such findings should be interpreted with caution as some patients, especially those with SF3B1 mutation, can have preserved hematogones (Chen et al., 2020). Similarly, CD34+ myeloid precursors can be increased in non-neoplastic conditions and due to growth factor administration. Other limitations—none of which are exclusive to flow cytometry—include the absence of detectable aberrations in a small subset of MDS cases, reliance on live cells, and the need for interpretation expertise.
In summary, flow cytometry has contributed significantly to the workup of MDS patients, with demonstrable value, reliability, and accuracy in clinical practice (Kern et al., 2023; Oelschlaegel et al., 2021; Westers et al., 2023). Compared to cytogenetic studies and mutational profiling, flow cytometric analysis has a much shorter turnaround time and can provide diagnostic value in cases with normal cytogenetics and equivocal molecular findings. Thus, we recommend that flow cytometric analysis should be included as a component of the evaluation of patients with cytopenias alongside cytogenetic studies and NGS-based mutation profiling.
骨髓增生异常肿瘤(MDS)是一种克隆性造血肿瘤,其特征是细胞减少和形态异常增生。这一定义将MDS与潜力不确定的克隆性造血(CHIP)和意义不确定的克隆性细胞减少(CCUS)区别开,后者患者在没有细胞减少的情况下存在涉及髓系恶性肿瘤相关基因的体细胞突变,而在CCUS的情况下,则存在发育不良(Khoury et al., 2022)。因此,MDS的诊断框架依赖于骨髓细胞形态学异常增生的检测,以及细胞减少患者的克隆证据。虽然造血谱系中发育不良的特征早已确立,但评估是主观的,并受到观察者之间差异的限制,特别是在轻度形态学改变的情况下。此外,一些非肿瘤性疾病会引起与MDS显著重叠的发育不良变化。这种情况的例子包括营养缺乏、毒素和接受各种治疗。鉴于不典型增生评估所固有的挑战,证明细胞减少患者的克隆性对于确定MDS的诊断至关重要,特别是在没有过多原细胞的低风险疾病中。长期以来,建立克隆依赖于传统核型和/或荧光原位杂交(FISH)检测细胞遗传学异常。除了建立克隆性的证据外,细胞遗传学研究在风险分层中也起着重要作用(Greenberg等,2012),一些细胞遗传学异常与不同的形态学和临床特征相关,例如低原细胞和5q缺失的MDS。然而,在MDS的诊断检查中使用细胞遗传学异常的问题是,它们仅在高达50%的MDS病例中被检测到。在细胞遗传学结果正常的情况下,需要其他工具来证明克隆并确定MDS的诊断。使用下一代测序(NGS)的突变分析显示,80%-90%的MDS病例中存在体细胞突变(Ogawa, 2019),这为诊断评估和确定克隆性的存在提供了重要价值。在这里,除了建立克隆性的证据外,突变谱研究在风险分层中也起着重要作用,并且需要一些基因异常来诊断某些MDS类型,定义遗传异常,如低原细胞和SF3B1突变的MDS和双等位基因TP53失活的MDS (Bernard et al., 2022;Khoury等人,2022;Malcovati et al., 2020)。然而,一个持续的警告是CHIP和CCUS也可能发生在其他健康的老年人中(Jaiswal等人,2014),需要谨慎解释某些突变的意义,特别是那些众所周知的与年龄相关的突变(如DNMT3A、TET2和ASXL1)。在此基础上,MDS相关的体细胞突变本身并不能诊断MDS。在这种背景下,近年来,流式细胞术分析作为MDS检查和评估细胞减少患者的另一种有价值的工具出现,这是欧洲白血病网络指南(van de Loosdrecht等人,2023)的推荐。虽然迄今为止还没有关于MDS的最佳流式细胞术方法的普遍共识,但流式细胞术在MDS患者评估中的诊断效用已经成为几个系统分析的主题。在Oelschlaegel等人最近的一项研究中,评估了五种流式细胞术评分系统的分析性能特征,并显示出不同的特异性和敏感性(Oelschlaegel等人,2021)。当使用流式细胞术评估MDS时,可以询问各种细胞亚群来评估异常抗原表达和/或成熟模式,包括髓系祖细胞、b细胞祖细胞以及成熟的粒细胞、单核细胞和红细胞。其中,根据我们的经验(Sanz-De Pedro et al., 2018)和其他人的经验(van de Loosdrecht et al., 2023), CD34+髓系前体的评估比其他细胞类型的评估提供了更可靠和特异性的结果。从概念上讲,这并不意外,因为MDS本质上是一种造血干细胞疾病,这些细胞在CD34+髓系前体室中富集。与成熟细胞相比,CD34+髓系前体往往具有更稳定的免疫表型,并且受反应性条件或分析前因素的影响较小,这进一步增加了它们的实用性。这与粒细胞和单核细胞形成对比,后者的抗原表达和成熟模式可能受到样本老化、血液稀释、反应条件或突发性夜间血红蛋白尿(PNH)克隆的影响(van der Velden等人,2023;Westers et al., 2021)。 然而,在适当的临床环境和适当的样品质量控制下,成熟骨髓单核细胞和红细胞成分的评估提供了有价值的信息,特别是在CD34+细胞数量有限或CD34+细胞室有细微表型异常的病例中。总之,尽管人们普遍认为流式细胞术的发现不足以建立MDS的明确诊断,但在cd34阳性骨髓前体和成熟造血细胞中检测免疫表型异常,结合形态学、细胞遗传学和分子评估,为出现细胞减少的患者提供了有价值的辅助支持。通常用于指示异常的CD34+髓系间室的免疫表型改变包括:(1)表达强度改变,如CD13、CD117和CD123的表达增加,CD38和HLA-DR的表达减少;(2)成熟/分化模式的改变,如CD38 +暗淡的非常早期前体中CD13或CD117的高表达;(3)淋巴样抗原如CD5、CD7、CD56的异常表达;(4)成熟的骨髓单核细胞抗原,如CD10、CD15和CD64在CD38 + dim非常早期的前体中异步表达。尽管CD34+髓系前体数量增加和/或早期b细胞前体(1期造血细胞)数量减少已被用于MDS评估中的异常(Oelschlaegel等人,2021),但这些发现应谨慎解释,因为一些患者,特别是SF3B1突变的患者,可能保留了造血细胞(Chen等人,2020)。同样,CD34+髓系前体在非肿瘤条件下和由于生长因子的使用而增加。其他的限制——这些限制都不是流式细胞术所独有的——包括在一小部分MDS病例中没有可检测到的畸变,依赖于活细胞,以及需要解释专业知识。综上所述,流式细胞术对MDS患者的检查有重要贡献,在临床实践中具有可证明的价值、可靠性和准确性(Kern et al., 2023;Oelschlaegel等人,2021;韦斯特等人,2023)。与细胞遗传学研究和突变谱分析相比,流式细胞分析具有更短的周转时间,并且可以在正常细胞遗传学和模棱两可的分子结果的情况下提供诊断价值。因此,我们建议将流式细胞术分析与细胞遗传学研究和基于ngs的突变谱分析一起纳入细胞减少症患者的评估。