High purity microfluidic sorting and analysis of circulating tumor cells: towards routine mutation detection

Autebert, Julien; Coudert, Bruno; Champ, Jérôme; Saias, Laure; Guneri, Ezgi Tulukcuoglu; Lebofsky, Ronald; Bidard, François‐Clément; Pierga, Jean‐Yves; Farace, Françoise; Descroix, Stéphanie; Malaquin, Laurent; Viovy, Jean‐Louis

doi:10.1039/c5lc00104h

Cited by 60 publications

(53 citation statements)

References 29 publications

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“…From Gaussian theory, probability density function is defined as , where n is stage number starting from 0 to 13. With μ = 7.3 and σ = 3.544, percentage at various stages could be calculated theoretically 35,36 (See Supplementary). Cumulative percentage of CTCs remained at various stages is shown in Fig.…”

Section: Resultsmentioning

confidence: 99%

Highly-sensitive capture of circulating tumor cells using micro-ellipse filters

Chen

Cao

Sun

et al. 2017

Sci Rep

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Circulating tumor cells (CTCs) detection, enumeration and characterization with microfluidic chips has critical significance in cancer prognosis offering a non-invasive “liquid biopsy”. Based on physical differences of size and deformability, we explore micro-ellipse filters consisting of microfuidic slits in series gradually narrowed. Slender tunnels sensitively capture tumor cells with slim chance to escape. Tumor cells could reside at capture sites organized by arrays of micro-ellipse microposts enduring less stress. Circular elliptical microstructures produce smooth flow minimally reducing any damage. “Air Suction” could extremely shorten capture. Capture efficiency comes out to be a robust yield of 90% and percentage obeys Gaussian distribution at various stages. With rare number accurately enumerated, micro-Ellipse filters have been tested high efficiently capturing tumor cells in both whole and lysed blood. To clinically validate the device, the microfluidic chip was utilized to identify and capture CTCs from metastatic breast, colon and non-small-cell lung (NSCLC) cancer patients. CTCs were detected positive in all samples with 4 patients having more than 20 CTCs. Those sensitive results are consistent with theoretical expectation. Efficient micro-ellipse filters enable clinical enumeration of metastasis, on-chip anti-cancer drug responses and biological molecular analysis.

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Section: Resultsmentioning

confidence: 99%

Highly-sensitive capture of circulating tumor cells using micro-ellipse filters

Chen

Cao

Sun

et al. 2017

Sci Rep

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“…As such, those studies mostly pursued only small numbers of gene candidates that were already known to be involved in breast cancer progression, metastasis and therapeutic resistance, rather than global transcriptional profiles (Aktas et al, 2011;Bolke et al, 2009;Gervasoni et al, 2008;Gradilone et al, 2011;Theodoropoulos et al, 2010). Recent technological advancements allow for immunomagnetic-bead-or microfluidicbased isolation of CTCs (Autebert et al, 2015;Magbanua and Park, 2013). When coupled to high-throughput microarray or RNAsequencing technologies and unbiased bioinformatics analyses, the aforementioned obstacles are significantly surmounted (Curtis, 2015;Magbanua and Park, 2014).…”

Section: Molecular Profiling Of Circulating Tumor Cellsmentioning

confidence: 99%

Signatures of breast cancer metastasis at a glance

Karagiannis

Goswami

Jones

et al. 2016

Journal of Cell Science

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Gene expression profiling has yielded expression signatures from which prognostic tests can be derived to facilitate clinical decision making in breast cancer patients. Some of these signatures are based on profiling of whole tumor tissue (tissue signatures), which includes all tumor and stromal cells. Prognostic markers have also been derived from the profiling of metastasizing tumor cells, including circulating tumor cells (CTCs) and migratory–disseminating tumor cells within the primary tumor. The metastasis signatures based on CTCs and migratory–disseminating tumor cells have greater potential for unraveling cell biology insights and mechanistic underpinnings of tumor cell dissemination and metastasis. Of clinical interest is the promise that stratification of patients into high or low metastatic risk, as well as assessing the need for cytotoxic therapy, might be improved if prognostics derived from these two types of signatures are used in a combined way. The aim of this Cell Science at a Glance article and accompanying poster is to navigate through both types of signatures and their derived prognostics, as well as to highlight biological insights and clinical applications that could be derived from them, especially when they are used in combination.

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“…One example of a technology that has implemented an immunomagnetic strategy on a micro-scale is the Ephesia chip. The Ephesia chip uses microcontact printing to create magnetic traps that promote the self-assembly of functionalized magnetic beads into an array of 48,000 columns within a microfluidic channel (Autebert et al, 2015;Saliba et al, 2010). The Ephesia design combines aspects of immunomagnetic sorting and micropost-based enrichment designs, while overcoming some of the limitations of previous micropost technologies.…”

Section: Epispotmentioning

confidence: 99%

Circulating tumor cell technologies

2016

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Cancer CTC capture CTC clustersImmunoaffinity enrichment A B S T R A C TCirculating tumor cells, a component of the "liquid biopsy", hold great potential to transform the current landscape of cancer therapy. A key challenge to unlocking the clinical utility of CTCs lies in the ability to detect and isolate these rare cells using methods amenable to downstream characterization and other applications. In this review, we will provide an overview of current technologies used to detect and capture CTCs with brief insights into the workings of individual technologies. We focus on the strategies employed by different platforms and discuss the advantages of each. As our understanding of CTC biology matures, CTC technologies will need to evolve, and we discuss some of the present challenges facing the field in light of recent data encompassing epithelial-to-mesenchymal transition, tumor-initiating cells, and CTC clusters.

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High purity microfluidic sorting and analysis of circulating tumor cells: towards routine mutation detection

Cited by 60 publications

References 29 publications

Highly-sensitive capture of circulating tumor cells using micro-ellipse filters

Highly-sensitive capture of circulating tumor cells using micro-ellipse filters

Signatures of breast cancer metastasis at a glance

Circulating tumor cell technologies

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