Circulating tumor cells: detection, molecular profiling and future prospects

Disseminated malignancy is responsible for the vast majority of cancer-related deaths. During this process, circulating tumor cells (CTC) are generated, spread from the primary tumor, colonize distant organs and lead to overt metastatic disease. CTC are essential for establishing metastasis; however, they are not sufficient as this process is highly inefficient and most will fail to grow in target sites. Several CTC die during migration while others remain dormant for several years and very few grow into macrometastases. CTC have been well documented in the bloodstream of cancer patients; however, the clinical relevance of this detection is still the subject of controversies and their biology is poorly understood. Indeed, available markers fail to distinguish between subgroups of CTC, and several current methods lack sensitivity, specificity or reproducibility in CTC characterization and detection. The advent of more precise technologies is renewing the interest in CTC biology. We will review herein recent findings on CTC biology, on the role of host-tumor interactions in CTC shedding and implantation, available methods of CTC detection and future perspectives for the molecular characterization of the CTC subset(s) responsible for the development of metastasis. Ultimately, understanding CTC biology and host-tumor 'complementarities' will help define metastasis-related biomarkers providing formidable and tailored novel therapeutic targets.     

Circulating tumor cells: the 'leukemic phase' of solid cancers

It is well known that malignant cells circulate in the bloodstream of patients with solid tumors. However, the biological significance of circulating tumor cells (CTCs) and the clinical relevance of their detection are still debated. Besides technical issues regarding CTC-detection methods, discontinuous shedding of CTCs from established cancer deposits, genomic instability and metastatic inefficiency might underlie the conflicting results currently available. Nevertheless, technological advances and recent clinical findings are prompting researchers to dissect CTC biology further. Here, we review these recent findings, and discuss the prospects for the identification and molecular characterization of the CTC subset that is responsible for metastasis development. This would provide a formidable tool for prognosis evaluation, anticancer-drug development and, ultimately, cancer-therapy personalization.     

Circulating tumor cells: approaches to isolation and characterization

Circulating tumor cells (CTCs) shed from primary and metastatic cancers are admixed with blood components and are thus rare, making their isolation and characterization a major technological challenge. CTCs hold the key to understanding the biology of metastasis and provide a biomarker to noninvasively measure the evolution of tumor genotypes during treatment and disease progression. Improvements in technologies to yield purer CTC populations amenable to better cellular and molecular characterization will enable a broad range of clinical applications, including early detection of disease and the discovery of biomarkers to predict treatment responses and disease progression.     

循环肿瘤细胞捕获与检测的纳米分析技术进展

随着纳米科学技术的发展,结构可控、表面多功能化、生物相容性良好的纳米材料在生物医药领域的各个方面都具有广泛的应用.作为一种重要的血液生物学标志物,循环肿瘤细胞(CTC)是肿瘤转移的"种子",活力较强的肿瘤细胞随着血液的流动可穿出血管在远端聚集形成微小的癌栓,对CTC的检测可用于癌症的早期诊断和转移的评估.新型纳米材料以及纳米表征测量技术的应用对CTC分析技术的进步产生了巨大的影响.近年来,基于纳米材料和微流控技术对CTC的捕获和检测已成为液体活检的研究热点,这一技术也被逐步推广到临床应用中.本文对纳米材料与纳米技术在CTC的捕获和检测中所发挥的作用进行了综述,并展望了该领域生物分析的应用前景.     

Circulating tumor cells in the diagnosis and management of pancreatic cancer

Pancreatic cancers are typically resistant to chemo and radiation therapy and are predisposed to distant metastases. Circulating tumor cells (CTCs) are tumor cells disseminated from primary and metastatic sites and can be isolated from peripheral blood. CTC may overcome the limitation of the current available tumor markers, CA19-9. As a surrogate for 'real-time biopsy', CTCs allow recurrent assessment of a tumor's biological activity. We review the current methodologies for CTC extraction and characterization including antibody-based immunological assays, PCR-based assays, and novel technologies based on the physical or biological characteristics of CTCs. CTCs also provide an accessible link to the existence of epithelial to mesenchymal transition, tumor stem cell markers, and ongoing clonal mutations and epigenetic changes in the tumor. We also explore the potential of using CTC profiling in diagnosis, selection of neoadjuvant and adjuvant therapy, detection of recurrent disease, examination of pharmacodynamic biomarkers, as well as in gene therapy and immunotherapy for pancreatic cancer. Ongoing CTC characterization not only has the potential to represent all cells shed from primary pancreatic tumor and each metastatic site, but also allows dynamic sampling at multiple time points during the clinical course to identify the subpopulations of CTCs and the specific molecules driving metastasis and chemo resistance. We predict that CTC genotyping and phenotyping will play an increasing role in personalized therapy and in identification of novel therapeutic targets as well as monitoring the course and status of the disease.     

综述——基于纳米材料的生物检测与医学诊断技术：循环肿瘤细胞富集和检测的纳米技术

循环肿瘤细胞(CTC)是肿瘤转移过程中在血液循环系统中存活的肿瘤细胞,该细胞的生成被认为是肿瘤发生转移的必要前提．CTC的存在与否及数量多少是肿瘤预后判断、疗效监控和肿瘤转移评估的一个重要检测指标．近年来,纳米材料、纳米结构表面以及可操控微量液体的微流控技术广泛应用于CTC的富集和检测,本文对CTC富集、检测纳米技术的最新进展进行综述,希望能够为肿瘤的诊断和治疗提供帮助．     

Circulating tumour cells in clinical practice: Methods of detection and possible characterization

Circulating Tumour Cells (CTCs) can be released from the primary tumour into the bloodstream and may colonize distant organs giving rise to metastasis. The presence of CTCs in the blood has been documented more than a century ago, and in the meanwhile various methods have been described for their detection. Most of them require an initial enrichment step, since CTCs are a very rare event. The different technologies and also the differences among the screened populations make the clinical significance of CTCs detection difficult to interprete. Here we will review the different assays up to now available for CTC detection and analysis. Moreover, we will focus on the relevance of the clinical data, generated so far and based on the CTCs analysis. Since the vast majority of data have been produced in breast cancer patients, the review will focus especially on this malignancy.     

循环肿瘤细胞识别技术研究现状

循环肿瘤细胞(CTCs)对恶性肿瘤传播转移有重要影响,因此CTCs识别技术的出现与不断进步有着重要的临床意义,准确可靠的CTCs识别技术将为尽早确诊肿瘤、指导个性化治疗方案、诊断微小残留病变以及评估抗癌药物的敏感性提供强有力的工具。本文针对核酸检测法、免疫细胞化学术、流式细胞术和基于表征特性图像识别技术等CTC识别技术的发展情况进行了综述总结,比较各种技术的优缺点,对现阶段该领域存在的问题进行了讨论,并对CTCs识别的技术发展方向作了进一步的展望,为学者们提供更广的研究思路。     

Isolation and characterization of circulating tumor cells using a novel workflow combining the CellSearch® system and the CellCelector™

Circulating tumor cells (CTC) are rare cells which have left the primary tumor to enter the blood stream. Although only a small CTC subgroup is capable of extravasating, the presence of CTCs is associated with an increased risk of metastasis and a shorter overall survival. Understanding the heterogeneous CTC biology will optimize treatment decisions and will thereby improve patient outcome. For this, robust workflows for detection and isolation of CTCs are urgently required. Here, we present a workflow to characterize CTCs by combining the advantages of both the CellSearch^® and the CellCelector? micromanipulation system. CTCs were isolated from CellSearch^® cartridges using the CellCelector? system and were deposited into PCR tubes for subsequent molecular analysis (whole genome amplification (WGA) and massive parallel multigene sequencing). By a CellCelector? screen we reidentified 97% of CellSearch^® SKBR‐3 cells. Furthermore, we isolated 97% of CellSearch^®‐proven patient CTCs using the CellCelector? system. Therein, we found an almost perfect correlation of R² = 0.98 (Spearman's rho correlation, n = 20, p < 0.00001) between the CellSearch^® CTC count (n = 271) and the CellCelector? detected CTCs (n = 252). Isolated CTCs were analyzed by WGA and massive parallel multigene sequencing. In total, single nucleotide polymorphisms (SNPs) could be detected in 50 genes in seven CTCs, 12 MCF‐7, and 3 T47D cells, respectively. Taken together, CTC quantification via the CellCelector? system ensures a comprehensive detection of CTCs preidentified by the CellSearch^® system. Moreover, the isolation of CTCs after CellSearch^® using the CellCelector? system guarantees for CTC enrichment without any contaminants enabling subsequent high throughput genomic analyses on single cell level. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 33:125–132, 2017     

Computational methods and challenges in analyzing intratumoral microbiome data

The human microbiome is intimately related to cancer biology and plays a vital role in the efficacy of cancer treatments, including immunotherapy. Extraordinary evidence has revealed that several microbes influence tumor development through interaction with the host immune system, that is, immuno–oncology–microbiome (IOM). This review focuses on the intratumoral microbiome in IOM and describes the available data and computational methods for discovering biological insights of microbial profiling from host bulk, single-cell, and spatial sequencing data. Critical challenges in data analysis and integration are discussed. Specifically, the microorganisms associated with cancer and cancer treatment in the context of IOM are collected and integrated from the literature. Lastly, we provide our perspectives for future directions in IOM research.     

Circulating tumor cell isolation,culture, and downstream molecular analysis

Circulating tumor cells (CTCs) are a major contributor of cancer metastases and hold a promising prognostic significance in cancer detection. Performing functional and molecular characterization of CTCs provides an in-depth knowledge about this lethal disease. Researchers are making efforts to design devices and develop assays for enumeration of CTCs with a high capture and detection efficiency from whole blood of cancer patients. The existing and on-going research on CTC isolation methods has revealed cell characteristics which are helpful in cancer monitoring and designing of targeted cancer treatments. In this review paper, a brief summary of existing CTC isolation methods is presented. We also discuss methods of detaching CTC from functionalized surfaces (functional assays/devices) and their further use for ex-vivo culturing that aid in studies regarding molecular properties that encourage metastatic seeding. In the clinical applications section, we discuss a number of cases that CTCs can play a key role for monitoring metastases, drug treatment response, and heterogeneity profiling regarding biomarkers and gene expression studies that bring treatment design further towards personalized medicine.     

Classification of Circulating Tumor Cells by Epithelial-Mesenchymal Transition Markers

In cancer, epithelial-mesenchymal transition (EMT) is associated with metastasis. Characterizing EMT phenotypes in circulating tumor cells (CTCs) has been challenging because epithelial marker-based methods have typically been used for the isolation and detection of CTCs from blood samples. The aim of this study was to use the optimized CanPatrol CTC enrichment technique to classify CTCs using EMT markers in different types of cancers. The first step of this technique was to isolate CTCs via a filter-based method; then, an RNA in situ hybridization (RNA-ISH) method based on the branched DNA signal amplification technology was used to classify the CTCs according to EMT markers. Our results indicated that the efficiency of tumor cell recovery with this technique was at least 80%. When compared with the non-optimized method, the new method was more sensitive and more CTCs were detected in the 5-ml blood samples. To further validate the new method, 164 blood samples from patients with liver, nasopharyngeal, breast, colon, gastric cancer, or non-small-cell lung cancer (NSCLC) were collected for CTC isolation and characterization. CTCs were detected in 107(65%) of 164 blood samples, and three CTC subpopulations were identified using EMT markers, including epithelial CTCs, biophenotypic epithelial/mesenchymal CTCs, and mesenchymal CTCs. Compared with the earlier stages of cancer, mesenchymal CTCs were more commonly found in patients in the metastatic stages of the disease in different types of cancers. Circulating tumor microemboli (CTM) with a mesenchymal phenotype were also detected in the metastatic stages of cancer. Classifying CTCs by EMT markers helps to identify the more aggressive CTC subpopulation and provides useful evidence for determining an appropriate clinical approach. This method is suitable for a broad range of carcinomas.     

肺癌循环肿瘤细胞的单细胞EGFR基因突变检测

循环肿瘤细胞（Circulating tumor cells,CTCs）是从肿瘤原发病灶脱落并侵入外周血循环的肿瘤细胞。由于CTCs存在较大的异质性,其与癌症发展转移密切相关,但目前尚缺乏有效的CTCs单细胞异质性检测方法。鉴于此,本文发展了在单细胞层面对CTCs进行基因突变的检测方法并用于单个肺癌CTC的EGFR（Epidermal growth factor receptor）基因突变检测。首先用集成式微流控系统完成血液中稀有CTCs的捕获,接着将CTCs释放入含有多个微孔的微阵列芯片中,得到含有单个CTC的微孔,通过显微操作将单个CTC转入PCR管内完成单细胞基因组的放大,并进行单细胞的EGFR基因突变检测。以非小细胞肺癌细胞系A549、NCI-H1650和NCI-H1975为样本,通过芯片与毛细管修饰、引物扩增条件（复性温度、循环次数）的优化,结果显示在复性温度59℃、30个循环次数的条件下,引物扩增效果最优。利用该方法成功地对非小细胞肺癌（Non-small cell lung cancer, NSCLC）患者的血液样本进行了测试。从患者2 mL血液中获取5个CTCs,分别对其EGFR基因的第18、19、20、21外显子进行测序,发现该患者CTCs均为EGFR野生型。研究结果证明此检测方法可以灵敏地用于单个CTC基因突变的检测,在临床研究上具有重要的指导意义。     

MicroRNAs in the tumor endothelium: Novel controls on the angioregulatory switchboard

Tumor angiogenesis facilitates tumor metastasis and allows malignant tissues to grow beyond a diffusion limited size. It is a complex process that requires endothelial cells to execute specific steps during different phases. miRNAs are small non-coding RNAs that act as molecular switches to redirect the expression profile of a cell. Evidence is emerging that miRNAs are important players in endothelial cell biology and tumor angiogenesis. In this review we summarize the available data of miRNA expression in the endothelium. In addition, we describe the current knowledge regarding the function of miRNAs in endothelial cell biology. Finally, we discuss the potential applications of miRNA based treatment strategies in angiostatic cancer therapy.     

How to decide whether small samples comply with an equidistribution

The decision whether a measured distribution complies with an equidistribution is a central element of many biostatistical methods. High throughput differential expression measurements, for instance, necessitate to judge possible over-representation of genes. The reliability of this judgement, however, is strongly affected when rarely expressed genes are pooled. We propose a method that can be applied to frequency ranked distributions and that yields a simple but efficient criterion to assess the hypothesis of equiprobable expression levels. By applying our technique to surrogate data we exemplify how the decision criterion can differentiate between a true equidistribution and a triangular distribution. The distinction succeeds even for small sample sizes where standard tests of significance (e.g. chi(2)) fail. Our method will have a major impact on several problems of computational biology where rare events baffle a reliable assessment of frequency distributions. The program package is available upon request from the authors.     

肿瘤相关成纤维细胞与肿瘤微环境

肿瘤的发展过程与肿瘤微环境密切相关,而肿瘤相关成纤维细胞（CAFs）是上述微环境中最主要的宿主细胞,CAFs是一类不同细胞源性的细胞群,可来源于多种细胞包括静止的成纤维细胞、上皮细胞、内皮细胞和间质干细胞的分化过程。体内和体外生物学实验均证实,成纤维细胞在肿瘤微环境中并不是被动的对肿瘤发展提供支持,而是发挥了至关重要的作用,所以靶向CAFs有望成为肿瘤治疗的新方向,对CAFs相关分子标记物和分子事件的进一步探索将为抗肿瘤的临床治疗提供新的思路。本文将对CAFs的来源以及CAFs对肿瘤发生发展、转移及VEGF耐受等方面的作用做一综述。