The integrated on-chip isolation and detection of circulating tumour cells

IF 3.5 Q2 CHEMISTRY, ANALYTICAL Sensors & diagnostics Pub Date : 2024-03-26 DOI:10.1039/D3SD00302G
Sophia M. Abusamra, Robert Barber, Mohamed Sharafeldin, Claire M. Edwards and Jason J. Davis
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Abstract

Circulating tumour cells (CTCs) are cancer cells shed from a primary tumour which intravasate into the blood stream and have the potential to extravasate into distant tissues, seeding metastatic lesions. As such, they can offer important insight into cancer progression with their presence generally associated with a poor prognosis. The detection and enumeration of CTCs is, therefore, critical to guiding clinical decisions during treatment and providing information on disease state. CTC isolation has been investigated using a plethora of methodologies, of which immunomagnetic capture and microfluidic size-based filtration are the most impactful to date. However, the isolation and detection of CTCs from whole blood comes with many technical barriers, such as those presented by the phenotypic heterogeneity of cell surface markers, with morphological similarity to healthy blood cells, and their low relative abundance (∼1 CTC/1 billion blood cells). At present, the majority of reported methods dissociate CTC isolation from detection, a workflow which undoubtedly contributes to loss from an already sparse population. This review focuses on developments wherein isolation and detection have been integrated into a single-step, microfluidic configuration, reducing CTC loss, increasing throughput, and enabling an on-chip CTC analysis with minimal operator intervention. Particular attention is given to immune-affinity, microfluidic CTC isolation, coupled to optical, physical, and electrochemical CTC detection (quantitative or otherwise).

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片上分离和检测循环肿瘤细胞的集成方法
循环肿瘤细胞(CTCs)是从原发肿瘤脱落的癌细胞,这些细胞会侵入血流,并有可能外渗到远处的组织,成为转移灶的种子。因此,CTCs 能为了解癌症进展提供重要信息,出现 CTCs 通常与预后不良有关。因此,CTCs 的检测和计数对于在治疗过程中指导临床决策和提供疾病状态信息至关重要。CTC 分离研究采用了大量方法,其中免疫磁捕获和微流控尺寸过滤是迄今为止最有影响力的方法。然而,从全血中分离和检测 CTC 存在许多技术障碍,例如细胞表面标记的表型异质性、与健康血细胞的形态相似性以及相对丰度低(约 1 CTC/1 十亿血细胞)。目前,大多数报道的方法都将 CTC 分离与检测分离开来,这种工作流程无疑会造成本已稀少的 CTC 群体的损失。本综述重点介绍将分离和检测整合到一个单一步骤的微流控配置中,从而减少 CTC 丢失、提高通量,并在操作员干预最少的情况下实现片上 CTC 分析的进展。特别关注免疫亲和微流控 CTC 分离,以及光学、物理和电化学 CTC 检测(定量或其他)。
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