Altered physical phenotypes of leukemia cells that survive chemotherapy treatment.

IF 1.5 4区 生物学 Q4 CELL BIOLOGY
Chau Ly, Heather Ogana, Hye Na Kim, Samantha Hurwitz, Eric J Deeds, Yong-Mi Kim, Amy C Rowat
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引用次数: 1

Abstract

The recurrence of cancer following chemotherapy treatment is a major cause of death across solid and hematologic cancers. In B-cell acute lymphoblastic leukemia (B-ALL), relapse after initial chemotherapy treatment leads to poor patient outcomes. Here we test the hypothesis that chemotherapy-treated versus control B-ALL cells can be characterized based on cellular physical phenotypes. To quantify physical phenotypes of chemotherapy-treated leukemia cells, we use cells derived from B-ALL patients that are treated for 7 days with a standard multidrug chemotherapy regimen of vincristine, dexamethasone, and L-asparaginase (VDL). We conduct physical phenotyping of VDL-treated versus control cells by tracking the sequential deformations of single cells as they flow through a series of micron-scale constrictions in a microfluidic device; we call this method Quantitative Cyclical Deformability Cytometry. Using automated image analysis, we extract time-dependent features of deforming cells including cell size and transit time (TT) with single-cell resolution. Our findings show that VDL-treated B-ALL cells have faster TTs and transit velocity than control cells, indicating that VDL-treated cells are more deformable. We then test how effectively physical phenotypes can predict the presence of VDL-treated cells in mixed populations of VDL-treated and control cells using machine learning approaches. We find that TT measurements across a series of sequential constrictions can enhance the classification accuracy of VDL-treated cells in mixed populations using a variety of classifiers. Our findings suggest the predictive power of cell physical phenotyping as a complementary prognostic tool to detect the presence of cells that survive chemotherapy treatment. Ultimately such complementary physical phenotyping approaches could guide treatment strategies and therapeutic interventions. Insight box Cancer cells that survive chemotherapy treatment are major contributors to patient relapse, but the ability to predict recurrence remains a challenge. Here we investigate the physical properties of leukemia cells that survive treatment with chemotherapy drugs by deforming individual cells through a series of micron-scale constrictions in a microfluidic channel. Our findings reveal that leukemia cells that survive chemotherapy treatment are more deformable than control cells. We further show that machine learning algorithms applied to physical phenotyping data can predict the presence of cells that survive chemotherapy treatment in a mixed population. Such an integrated approach using physical phenotyping and machine learning could be valuable to guide patient treatments.

化疗后白血病细胞物理表型的改变。
化疗后癌症复发是实体癌和血液癌死亡的主要原因。在b细胞急性淋巴细胞白血病(B-ALL)中,初始化疗后复发导致患者预后不佳。在这里,我们验证了一个假设,即化疗治疗的B-ALL细胞与对照的B-ALL细胞可以根据细胞物理表型进行表征。为了量化化疗后白血病细胞的物理表型,我们使用来自B-ALL患者的细胞,这些患者接受长春新碱、地塞米松和l -天冬酰胺酶(VDL)的标准多药化疗方案治疗7天。我们通过跟踪单个细胞在微流体装置中流过一系列微米尺度的收缩时的顺序变形,对vdl处理的细胞与对照细胞进行物理表型分析;我们称这种方法为定量周期性变形细胞术。使用自动图像分析,我们提取变形细胞的时间相关特征,包括细胞大小和传输时间(TT)与单细胞分辨率。我们的研究结果表明,vdl处理的B-ALL细胞比对照细胞具有更快的TTs和转运速度,表明vdl处理的细胞更具可变形性。然后,我们使用机器学习方法测试物理表型如何有效地预测vdl处理细胞和对照细胞混合群体中vdl处理细胞的存在。我们发现,通过一系列连续收缩的TT测量可以使用各种分类器提高混合群体中vdl处理细胞的分类准确性。我们的研究结果表明,细胞物理表型的预测能力作为一种补充的预后工具来检测化疗后存活细胞的存在。最终,这种互补的物理表型方法可以指导治疗策略和治疗干预。化疗后存活的癌细胞是患者复发的主要原因,但预测复发的能力仍然是一个挑战。在这里,我们研究了白血病细胞的物理特性,这些细胞通过微流体通道中一系列微米尺度的收缩使单个细胞变形,从而在化疗药物治疗中存活下来。我们的研究结果表明,化疗后存活下来的白血病细胞比对照细胞更易变形。我们进一步表明,应用于物理表型数据的机器学习算法可以预测混合人群中化疗后存活的细胞的存在。这种使用物理表型和机器学习的综合方法可能对指导患者治疗有价值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Integrative Biology
Integrative Biology 生物-细胞生物学
CiteScore
4.90
自引率
0.00%
发文量
15
审稿时长
1 months
期刊介绍: Integrative Biology publishes original biological research based on innovative experimental and theoretical methodologies that answer biological questions. The journal is multi- and inter-disciplinary, calling upon expertise and technologies from the physical sciences, engineering, computation, imaging, and mathematics to address critical questions in biological systems. Research using experimental or computational quantitative technologies to characterise biological systems at the molecular, cellular, tissue and population levels is welcomed. Of particular interest are submissions contributing to quantitative understanding of how component properties at one level in the dimensional scale (nano to micro) determine system behaviour at a higher level of complexity. Studies of synthetic systems, whether used to elucidate fundamental principles of biological function or as the basis for novel applications are also of interest.
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