Three-dimensional nanostructured substrates enable dynamic detection of ALK-rearrangement in circulating tumor cells from treatment-naive patients with stage III/IV lung adenocarcinoma

Circulating tumor cells (CTC) are cancer cells that exist in the circulation system of patients with solid cancers, after detaching from primary tumor lesions. It is said that CTC holds great promise in tailoring treatment decision for cancer patients [1]. CellSearch system as the most classic CTC enrichment system based on detection of tumor cells that express epithelial cell adhesion molecule (EpCAM), was effective to predict prognosis of many cancers, especially breast and lung cancers [1‐3]. Furthermore, it is the only method approved by the US Food and Drug Administration (FDA) for the enumeration of CTC in certain advanced cancers. Detection of 5 CTCs per 7.5 ml or higher can predict prognosis regardless of disease histology and molecular subtype, type of treatment, or whether the patient had recurrent or de-novo metastatic disease [4].

Over the past years, a diverse suite of techniques including biophysical (e.g., density gradient centrifugation devices, size-based filtration systems, cell dielectric properties-based isolation assays, microfluidics-based technologies, etc.) and biochemical (e.g., capture-agent-labeled immunomagnetic beads, CTCs-chip and nanoparticle enrichment devices, etc.) methodology-based enrichment assays by their different properties had been demonstrated [5, 6]. One such most widely-used CTC assay CellSearch mentioned above is based on the technique of capture-agent-coated magnetic beads. More recently, nanostructured cell-affinity substrate coated with cancer-cell capture agents (e.g., epithelial cell adhesion molecule antibody, anti-EpCAM) has also been applied to enrich and immobilize CTCs, exhibiting improved cell-capture efficiency [7‐13]. However, the overall enrichment efficacy is still discontented by use of these techniques.

Previously, we pioneered a NanoVelcro Chip owning anti-EpCAM [14, 15] coated 3D-nanostructured substrate [16], showed enhanced CTCs enrichment efficacy compared to CellSearch [17] in prostate cancer. Our NanoVelcro Chip integrates three functional features: (1) anti-EpCAM coating for capturing EpCAM-positive cells through immunological reaction, (2) a silicon nanopillar (SiNP) substrate with special microstructured surfaces, which exhibits improved cell-capture efficiency owing to enhanced local topographic interactions [18] between the SiNP substrates and nanoscale cellular surface components [17], (3) an overlaid polydimethylsiloxane (PDMS) chip with a serpentine chaotic mixing channel [8, 19‐21] forming special microfluidic that increased cell-substrate contact frequency. Despite the enhanced CTCs capture ability, the controlled study did not perform in lung cancer and the subsequent CTC cellular characterization (e.g., driver oncogene mutation status) consistency which is of great clinical significance for therapy guidance between the two methods weren’t further analyzed in this study.

As the most common sensitive gene mutations for lung cancer, a fusion gene between the anaplastic lymphoma kinase (ALK) gene and echinoderm microtubule associated protein-like 4 (EML4) was identified in 3% to 7% of unselected NSCLC patients [22], and further proved to be a potent oncogenic driver [23, 24]. Crizotinib as an ALK inhibitor [9, 24], was approved by the FDA for treating advanced ALK-positive NSCLC patients [10] and showed good therapeutic effect. Recently, the Vysis ALK Break-Apart FISH Probe Kit (Abbott Molecular, Inc.) was approved to detect ALK rearrangement status on small biopsies or fine-needle aspirated tissue. Considering the biopsy risk, medical cost and patient acceptance, it is difficult to repeatedly obtain tumor specimens, which are imperative in determining the therapeutic effect, exploring predictive biomarkers and choosing alternative treatment timely. In patients with advanced NSCLC, tumor specimen is more difficult to obtain because surgery is rarely a component of treatment [11] in advanced lung cancer patients. Thus, developing a noninvasive and effective assessment platform, that could predict whether patients can benefit from primary treatment and diagnosis if an ALK-rearrangement presents identifying NSCLC patients benefiting from Crizotinib treatment, is imperative and invaluable.

Based on the predicament faced above, our present study was to determine if NanoVelcro platform could capture CTC from the advanced NSCLC patient blood with improved efficiency compared to CellSearch system by utilizing similar enrichment technique. Moreover, the second endpoint of our study was to determine whether an ALK-rearrangement could be detected in CTCs enriched by NanoVelcro assay from ALK-positive advanced NSCLC patients, facilitating treatment strategy design and prognosis monitoring.

Our present study showed great improvement in CTC-capture efficiency with NanoVelcro chip compared with CellSearch in stage III or IV lung adenocarcinoma, which is in accordance with our previous findings [17], however the results need to be further validated by enlarging the sample size. Furthermore, CTC counts of the two methods positively correlated. Correlation between CTC counts and pTNM stage determined by NanoVelcro was more significant than that determined by CellSearch. CTC characterization analysis demonstrated that CTCs captured by NanoVelcro well reflect the ALK mutation status in tumor tissue, the ratio of ALK-rearrangement in CTCs positively correlated to that in tumor tissue. Furthermore, ALK-rearrangement CTC ratio detected by NanoVelcro correlated to the pTNM stage indicating that increased ALK-rearrangement CTCs may represent advanced disease status. Interestingly, as for therapeutic effect monitoring, in the short term (within the first 6 months), the two methods showed good consistency in evaluating the treatment efficacy of Clozotinib, but in the long run (the 8th month), compared with CellSearch, CTC counting by NanoVelcro was more stable and reliable in evaluating the efficacy of Clozotinib. Whilst, decreasing of NanoVlecro CTC counts could accurately reflect disease remission evaluated by chest CT image.

The ability to identify, isolate, propagate and characterize CTC subpopulations with noninvasive CTC-capture platform could deepen the understanding of blood metastasis mechanism, facilitate accurate evaluation of disease progression, continuously monitor the CTC (e.g. number, molecular and genetic characters) change to guide therapy. Although CellSearch is the only cell-affinity assay approved by the FDA and CTC numeration based on this platform and was proved to be an accurate prognostic indicator [1‐3], whereas, it is gradually being depreciated due to “important limitations” in selecting CTC based on EpCAM which could lead to comparatively limited number of captured CTCs of epithe-lial cell phenotype only. However, metastasis begin with the epithe-lial–mesenchymal transition (EMT), in which tumor cells lose many of their ‘epithelial’ characteristics and become more like mesenchymal cells with the abil-ity to spread and invade tissue [26]. Thus, this kind of cell capture technique is likely to miss the cells of mesenchymal cell phenotype which is EpCAM-negative. To increase capture efficiency of CTCs, we developed this NanoVelcro platform detect CTC based on the similar immunological mechanism of CellSearch, but combined with special microstructured surfaces to strengthen topographic interactions and microfluidics to facilitate contact frequency. Microfluidics design may increase the contact between CTC and EpCAM coated substrate and intensify the immunological recognition affinity, maximizing the capture potential which CellSearch can’t accomplish. Expectedly, this platform identified more than several times of CTC than CellSearch in advanced NSCLC patient, showing improved capture efficiency. Additionally, since CellSearch may miss EpCAM-negative CTC, this drawback may be partially compensated by strengthened topographic interactions between CTC and NanoVelcro microstructured surfaces [27], this is also involved in our device by using special microstructured surfaces.

In our study, CTC characterization analysis demonstrated that ALK-rearrangement status in NanoVelcro captured CTCs showed reliable consistency with that in the tumor specimen, and ALK-rearrangement was consistently detected in CTC from lung cancer patients harboring this rearrangement. Traditionally, ALK mutation status can be only determined by tissue biopsy, which is invasive, expensive and time consuming. We demonstrated NanoVelcro platform that can non-invasively and accurately determine ALK mutations status in advanced NSCLC patients. Thus, NanoVelcro may be a surrogate to screen ALK positive patients eligible for ALK-targeted treatment, and CTCs captured by such technique and further FISH may resolve the problem of monitoring the genomic profiling of tumor, which may predict the treatment efficacy of Crizotinib and is hard to be achieved by traditionally tumor biopsy analysis. Furthermore, ALK-rearrangement CTC ratio detected by NanoVelcro correlated to pTNM stage indicating that increased ALK-rearrangement CTCs may represent advanced disease status.

Then we further demonstrate the ability to identify CTC number changes by NanoVelcro in response to Crizotinib therapies in one metastatic NSCLC patients. The results showed that, compared with CellSearch, CTCs counting by NanoVelcro was more stable and reliable in evaluating the efficacy of Clozotinib both in the short and long run. Whilst, changing of NanoVlecro CTC counts could accurately reflect disease progression. This might be due to the fact that the NanoVelcro assay can more accurately reflect the true number of CTCs. Our results are simillar to those reported [28, 29]. As the NanoVelcro generally presented much higher capture efficiency compared to the CellSearch™ assay, CTC counts by the NanoVelcro yield a wider dynamic range and may be a better predictor of disease progression [7]. Whilst, decreasing of NanoVlecro CTC counts could accurately reflect disease remission evaluated by chest CT image. Thus, NanoVelcro can be used to dynamically monitor the tumor morphology changes through analyzing CTC avoiding traditional tumor biopsy.

Briefly, NanoVelcro platform showed improved CTC-capture efficiency than CellSearch system, and the ALK-rearrangement status of captured CTCs kept in accordance with results from tumor specimen. This platform is primarily demonstrated to be an accurate, noninvasive and real-time detection of ALK mutations in treatment-naive patients with stage III or IV lung adenocarcinoma, optimizing the selection of ALK-inhibitor eligible patients and the dynamic monitoring of therapy reaction. Promisingly, Since NanoVelcro captured CTC are alive, these cells could potentially be expanded ex vivo for further molecular interrogation. Our future efforts will be devoted to preserve patient-derived CTC lines to select potential therapies options for individual cancer patients. We will also attempt to utilize NanoVelcro to predict the treatment reaction based on real-time monitoring the CTC counts and characterization changes in larger clinical cohorts to further confirm our findings.

In this study, ALK-rearrangement can be detected in CTCs captured by Nano Velcro system, presenting high concordance with matched primary tumor tissues. Correlation between CTC counts and pTNM stage determined by NanoVelcro was more significant than that determined by CellSearch. Whilst, the therapeutic efficacy of Clozotinib can be reliably responded by NanoVelcro assay and the changing of NanoVlecro CTC counts could accurately reflect disease progression. With CTCs capture and their corresponding ALK detection, dynamic monitoring of treatment effect for lung cancer patients could be realized during the process of Crizotinib treatment.