This study enrolled 79 patients with NPC, including 53 men and 26 women, aged 23 to 79 years. Patients were diagnosed and admitted to the present hospital between November 2014 and October 2020. Following the Tumor-Node-Metastasis (TNM) staging system for NPC in the 2008 version, the number of patients with stages I, II, III, Iva and IVb were 2, 6, 33, 27 and 11, respectively, and the diagnosis was confirmed by histopathological specialists based on tumor biopsy or fine-needle aspiration cytology. TNM staging was determined by combining clinical characteristics and pathological types. The following conditions were excluded from this study: active infection and malfunction or failure of key organs such as the liver, kidney, and heart. A total of 119 peripheral blood samples from 79 patients with NPC, including 70 samples in pre-treatment and 49 samples in post-treatment groups, were collected, and CTCs were identified via CanPatrolTM CTC enrichment and RNA In Situ Hybridization (RNA-ISH) techniques before or after treatment because this technique has very sensitivity and specificity.14,25

The study was reviewed and approved by the ethics committee of the First People's Hospital of Zhaoqing City (approval number #:2018-11-02). Written informed consent was obtained from all the patients before the study. All procedures performed in studies were in accordance with the ethical standards of the 1964 Declaration of Helsinki and its later amendments or comparable ethical standards.

The authors used a filtration method to identify the CTCs as in previous descriptions.25,26 Briefly, all blood samples were processed in a filtration tube system (SurExam, Guangzhou, China) in the laboratory, including a calibrated membrane with 8-μm diameter pores (Millipore, Billerica, USA), a manifold vacuum plate with valve (SurExam, Guangzhou, China), and a vacuum pump (Auto Science). First, a total of 5 milliliters (mL) of peripheral blood from patients was taken in veins 1‒3 days at pre-treatment and post-treatment and loaded into Ethylenediaminetetraacetic Acid (EDTA) coated tube. Then, erythrocytes in the collected blood sample were removed using lysis buffer (Sigma, St. Louis, USA, Cat#:R7757‒100 mL). The remaining cells were centrifuged and discarded into the supernatant. The cell pellet was suspended and fixed in 4% formaldehyde in Phosphate-Buffered Saline (PBS) for 5 minutes. Finally, the cell suspension was connected to the filtration tube in vacuum conditions, and samples were processed.

To identify CTCs, the authors used the RNA-ISH technique for this study, which is based on branched DNA (bDNA) signal amplification technology. Signals of biomarkers of interest were amplified based on the binding of a bDNA capture probe to the target sequences.27 Briefly, the targeted DNA sequences were first bound by multiple bDNA capture probes; bDNA signal amplification probes were then bound to bDNA capture probes. Finally, the bDNA amplifier probe with different fluorescent dye labeling was identified using an immunofluorescence microscope (Olympus, Tokyo, Japan). The capture probes for EpCAM and CK8/18/19 specifically bound to epithelial markers were labeled with Alexa Fluor 594 showing red color. Vimentin and twist were specific mesenchymal markers and labeled with Alexa Fluor 488 showing green color. The capture probes were purchased from SurExam Company (SurExam, Guangzhou, China) and the sequences are in Table 1. The authors also performed 40,6-Diamidino-2-Phenylindole (DAPI) staining to gate nuclei shape. All process was performed in 24-well plates (Corning, USA) and carried out at 40°C.

All data analyses were performed via statistic software SPSS 24.0 (IBM Inc, Chicago, IL, USA). CTCs positive rate and comparison among different groups were implied via the χ2 test, t-test, and Kruskal-Wallis test. For two-group comparisons, the authors employed the Mann-Whitney U test. Fisher's exact and Pearson Chi-Square tests were used to analyze relationships between CTCs number and clinical characteristics including age, gender, smoking, and TNM staging. PFS and OS rates were calculated via Kaplan-Meier analysis; p < 0.05 was considered statistically significant.

A total of 79 patients were recruited in this study, and their detailed characteristics are shown in Tables 2 and 3. A total of 119 blood samples were collected during treatment. Based on the collection time of blood samples, the patients were divided into pre- and post-treatment groups. In the pre-treatment group, the positive CTCs were counted in 65 of 70 patients (92.9%) with a median number of 5.00 CTCs in 5 mL blood (range 0‒62). In the post-treatment group, positive CTCs were identified in 42 of the 49 patients (85.7%) with a median number of 4.00 CTCs in 5 mL blood (range 0‒51). CTCs were categorized into three phenotypes according to their surface markers: epithelial, biphenotypic, and Mesenchymal CTCs (MCTCs). Similarly, positive MCTCs were counted in 52 of the 70 patients (74.3%) with a median number of 4.00 CTCs in 5 mL blood (range 0‒61) in the pre-treatment group and in 33 of the 49 patients (67.3%) with a median number of 3.00 CTCs in 5 mL blood (range 0‒44) in the post-treatment group (Tables 2 and 3). Additionally, there were significant differences in the number of CTCs and MCTCs between the pre-treatment and post-treatment groups (Fig. 1 A and B). These data indicated that CTCs and MCTCs both decreased after treatment.

Figure 1.

Correlation between CTCs or MCTCs count and treatment. (A) The comparison of CTCs count between pre-treatment and post-treatment. (B) The comparison of MCTCs count between pre-treatment and post-treatment. CTC, circulating tumor cell; MCTC, mesenchymal circulating cell.

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Bivariate analyses of the correlation between the CTC and MCTC positivity rates and the characteristics of patients with NPC are listed in Tables 2 and 3 (pre-treatment and post-treatment groups). The results showed that CTC or MCTC positivity rates had no association with patient characteristics (p > 0.05, in all cases; Tables 2 and 3). However, the authors found that the total number of CTCs and MCTCs was associated with the TNM stage (I, II, III, Iva, IVb) (p < 0.05, Fig. 2). In both groups, patients at stage III had the highest numbers of CTCs and MCTCs statistically, and the authors hypothesized that total CTCs and MCTCs were related to metastasis. In the pre-treatment group, the median number of CTCs in patients with stage III tumors was 11.5, which was significantly higher than that in patients with stage II tumors, even stage Iva and IVb (median: 3.5, 8, 10) and stage I (only 1 sample, Fig. 2 A and B). Similarly, the authors found that the median number of MCTCs in patients with stage III tumors was 6. In contrast, the median MCTC number was 3.5 and 5.5 at stage II and stage IVa or Ivb, respectively. In addition, in the post-treatment group, the median CTCs were 6.5, 3, and 6 at stage III, IVa, and IVb, respectively. The median MCTC in stage III was 5.5, while the median in stage Iva and stage Ivb were both 1 (Fig. 2 C and D). These data revealed that CTC and MCTC had peak values in stage III, which may have been caused by metastasis.

Figure 2.

Correlation between CTC number, MCTC number and TNM stage. (A) In the pre-treatment group, the CTC number had significant difference between stage III and stage IVa. (B)In the pre-treatment group, the MCTC number had significant difference between early stage III and stage II, stage IVa, stage IVb. (C) In post-treatment group, CTCs number of the patients with stage IVa were statistically lower than those who with stage III and stage IVb. (D) In post-treatment group, the MCTCs number had significant difference between stage III and stage IVa.

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The outcomes of 79 patients were followed up using the RECIST assessment system. The follow-up period ranged from 7 to 94 months (median, 18 months). Among these patients, 6 (7.6%) had progressive disease and 73 (92.4%) exhibited non-progressive disease. The authors also evaluated associations among three different therapies (chemoradiotherapy, chemotherapy combined targeted therapy, or chemoradiotherapy combined targeted therapy), CTC status, CTC amount, and changes in CTC numbers of pre- and post-treatment. The authors selected a cutoff of 7 CTCs in 5 mL blood based on the Receiver Operating Characteristic (ROC) curve, and the PFS and OS rates were determined using the Kaplan-Meier method. The authors found that the PFS of patients with > 7 CTCs or > 5 MCTCs in 5 mL blood was significantly shorter than that of patients with ≤ 7 CTCs or ≤5 MCTCs (p = 0.016 and p = 0.016, respectively; Fig. 3 A and C). The presence of > 7 CTCs or > 5 MCTCs per 5 mL blood was associated with a poorer OS than ≤ 7 CTCs or ≤5 MCTCs (p = 0.018 and p = 0.018, respectively; Fig. 3 B and D). Moreover, the PFS and OS rates of patients treated with chemoradiotherapy were also significantly longer than those of patients treated with targeted therapy combined with chemotherapy or chemoradiotherapy (Fig. 4A). These results revealed that chemoradiotherapy was more effective than combined targeted therapy and chemotherapy. Moreover, the number of metastatic lesions was also associated with progression-free survival, and patients with > 1 metastatic lesion had a markedly shorter PFS than those with ≤1 metastatic lesion (Fig. 4B). Notably, analyzing the paired data obtained from 36 patients in whom the number and phenotype of CTCs were detected before and after treatment, it was found that the absolute value of the differences between the two sets of data was a potential prognostic factor for NPC. The authors investigated the prognostic potential of the changes in the number of CTCs after treatment using Kaplan-Meier survival analyses for PFS and OS. As shown in Figure 4, patients with ≥ 4 change in CTC number after treatment had a shorter PFS and OS than those with < 4 change in CTC number changed after treatment (Fig. 4 C and D).

Figure 3.

The comparison of progression-free survival (PFS) and overall survival (OS) in NPC patients by Kaplan-Meier curves. (A) Relationship between CTC count and PFS rate. (B) Relationship between CTC count and OS rate. (C) Relationship between MCTC number and PFS rate. (D) Relationship between MCTC number and OS rate.

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Figure 4.

The comparison of progression-free survival (PFS) and overall survival (OS) in NPC patients with different treatments. (A) Relationship between three different therapies and PFS rate. Number 1 represents chemoradiotherapy, number 2 represents chemoradiotherapy combined targeted therapy, and number 3 represents chemotherapy combined targeted therapy. Statistical log rank test found that the p-value in the difference between group 1 and 2 is0.350, group 2 and group 3 is 0.065, while group 1 and group 3 is 0.0001. (B) Relationship between the number of metastatic lesions and PFS rate. (C) Relationship between the change in number of CTC after treatment and PFS rate. (D) Relationship between the change in number of CTC after treatment and OS rate. N1: the CTC counts before treatment. N2: the CTC counts after treatment. N: the absolute value of the change in number of CTC after treatment.

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