Novel Silicone-Coated 125I Seeds for the Treatment of Extrahepatic Cholangiocarcinoma

Lizhou Lin; Lili Guo; Weixing Zhang; Xiaobo Cai; Dafan Chen; Xinjian Wan

doi:10.1371/journal.pone.0147701

Abstract

¹²⁵I seeds coated with titanium are considered a safe and effective interstitial brachytherapy for tumors, while the cost of ¹²⁵I seeds is a major problem for the patients implanting lots of seeds. The aim of this paper was to develop a novel silicone coating for ¹²⁵I seeds with a lower cost. In order to show the radionuclide utilization ratio, the silicone was coated onto the seeds using the electro-spinning method and the radioactivity was evaluated, then the anti-tumor efficacy of silicone ¹²⁵I seeds was compared with titanium ¹²⁵I seeds. The seeds were divided into four groups: A (control), B (pure silicone), C (silicone ¹²⁵I), D (titanium ¹²⁵I) at 2 Gy or 4 Gy. Their anti-tumour activity and mechanism were assessed in vitro and in vivo using a human extrahepatic cholangiocarcinoma cell line FRH-0201 and tumor-bearing BALB/c nude mice. The silicone ¹²⁵I seeds showed higher radioactivity; the rate of cell apoptosis in vitro and the histopathology in vivo demonstrated that the silicone ¹²⁵I seeds shared similar anti-tumor efficacy with the titanium ¹²⁵I seeds for the treatment of extrahepatic cholangiocarcinoma, while they have a much lower cost.

Citation: Lin L, Guo L, Zhang W, Cai X, Chen D, Wan X (2016) Novel Silicone-Coated ¹²⁵I Seeds for the Treatment of Extrahepatic Cholangiocarcinoma. PLoS ONE 11(2): e0147701. https://doi.org/10.1371/journal.pone.0147701

Editor: Bing Xu, Brandeis University, UNITED STATES

Received: August 25, 2015; Accepted: January 7, 2016; Published: February 3, 2016

Copyright: © 2016 Lin et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All relevant data are within the paper and its Supporting Information files.

Funding: This work was supported by Doctoral Fund of Education Administration for New Teacher (project code: 070162). The funding receiver was Xinjian Wan. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Worldwide, cholangicarcinoma(CC) is the second commonest primary liver cancer after hepatocellular carcinoma, and accounts for 15% of all primary hepatic malignancies[1–2]. With the incidence and mortality rates risen in extrahepatic CC (including perihilar cholangicarcinoma), the diagnosis rates for CC have risen steeply and steadily across the world over the past few decades. Currently, the only curative therapeutic option in extrahepatic CC is resection. However, only a minority of the patients can be operated and even if a clear resection (R0 resection) is possible, the rate of relapse is as high as 60–75% [2–5]. Although multimodal therapeutic concepts have been proposed, they were not successful to achieve major progress.Hence, the insertion of biliary stents has been widely accepted as a mainly palliative procedure for the improvement of biliary drainage[5–9]; however, the prognosis remains poor, with complex hilar lesions conferring a median patient survival of less than 6 months[10–11]. Since the cause of death in extrahepatic CC is commonly due to recurrent biliary obstruction and intrabiliary sepsis, key issues are controlling local disease and optimizing biliary drainage[1]. There is evidence indicating that the combination of radiotherapy with stent insertion improves survival time compared to stent insertion alone[12–13].

For decades, ¹²⁵I seeds have been successfully used as interstitial brachytherapy for prostate, pancreatic, and lung cancer, where they are characterized by a long half-life of 59.6 days[14–16]. Liu et al. first introduced endoprosthesis containing ¹²⁵I seeds for intraluminal brachytherapy in the biliary system, and demonstrated that the combination of ¹²⁵I seeds and stenting was a useful and well-tolerated method for treatment of advanced extrahepatic CC[17].The conventional ¹²⁵I seeds are coated by titanium, it is a mental material which has the characteristics of no toxicity, undegradable and good biocompatibility. However, the titanium coating ¹²⁵I seeds are quite expensive, and approximately twice the amount of ¹²⁵I solution is required to obtain effective radioactivity due to the self-shielding effect of the titanium coating, further increasing the price. Therefore, developing simple and cheap coatings for ¹²⁵I seeds may hold therapeutic promise. Medical silicone is widely used for biomedical purposes, such as coating neural microelectrodes and antibiotics. The medical silicone has many advantages, beside the capability of corrosion resistance, the suitable biocompatibility and appropriate absorption rate make it becomes widely used medical material[18–20]. However, there have been few studies into the use of ¹²⁵I-coated-silicone seeds for tumor radiotherapy.

The aim of this study was to develop silicone coating for ¹²⁵I seeds and compare the safety and efficacy with conventional titanium coated ¹²⁵I seeds for the treatment of extrahepatic CC.

Materials and Methods

2.1. Coating technique

Silicone with a pore size of 10 A was dissolved in silver nitrate solution to form silver-silicone, and the solution was subject to spinning. The ¹²⁵I solution (specific activity greater than 800 mCi/ml) was added into the spinning solution, which was immediately discharged into a syringe. Another syringe was filled with the silicone solution. The syringes were connected to a high voltage power supply controlled at 25 kV in a modified coaxial electrospinning device (Cole-Parmer Instrument Company, USA) as shown in Fig 1. The solution was sprayed evenly onto a nanofiber mixture to form an initial silicone ¹²⁵I (s-¹²⁵I) mixture. The nanofibers were collected on aluminum foil, forming a core-shell structure, with the core composed of silver-silicone containing ¹²⁵I and a shell of silicone. Nanofibers were then cut into seeds. All processes were undertaken in a sealed and protective glove box. All samples were vacuum dried at 60°C for 12 h to remove solvents. Following solvent removal, the seeds received an appearance inspection, and were cleaned in scintillation fluid (Fig 2). The cleaning fluid was collected to check for leaks (less than 185 Bq is qualified). Finally, the radioactivity of each seeds was measured, with recordings of radioactivity taken for 20 groups (Table 1). The utilization of the radionuclide was estimated using Eq 1.

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Fig 1. Diagrams illustrating the experimental design: (a) coaxial electrospinning device, silver-silicone with ¹²⁵I in syringe1, another silicone in syringe2 as the shell, the jets forming the core—shell structure; (b) the principle diagram of seeds, the outside layer is the silicone coating the ¹²⁵I solution inside(c,d) the anti-tumor effect of the silicone was examined in vitro and in vivo using human cell line FRH-0201 and tumor-bearing BALB/c nude mice.

https://doi.org/10.1371/journal.pone.0147701.g001

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Fig 2. Silicone ¹²⁵I seeds, the diameter and length was 0.8 mm by 4.5 mm.

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Table 1. 20 groups datas of silicone ¹²⁵I seeds and titanium ¹²⁵I seeds.

https://doi.org/10.1371/journal.pone.0147701.t001

(1)

Where R means radionuclide utilization ratio; A is the actual ¹²⁵I radioactivity; T is the total ¹²⁵I radioactivity.

The titanium ¹²⁵I(t-¹²⁵I) seeds were produced by XinKe Co., China. The diameter and length of each titanium capsule was 0.8 mm by 4.5 mm.

Compare the radionuclide utilization ratio and radioactivity of s-¹²⁵I with t-¹²⁵I.

2.2 Cell apoptosis evaluation in vitro

To obtain a relatively homogeneous dose distribution at the top of the dish, eight ¹²⁵I seeds were evenly fixed with double-sided adhesive around a 35 mm diameter circle in the center of a 6-cm cell culture dish, with one ¹²⁵I seed placed in the center (Fig 3B). A 35-mm cell culture dish containing cells was placed on the top of the ¹²⁵I seed irradiation model during the experiment (Fig 3C). The model was kept in the incubator to maintain constant cell culture conditions (Fig 3A) and was validated with thermoluminescent dosimetry measurement using an empirical formula established by the American Association of Physicists in Medicine (AAPM; 15)[21]. The exposure time for delivering doses of 2 Gy and 4 Gy were 44 h and 92 h, respectively.

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Fig 3.

A.The irradiation model was placed in the incubator. B. Eight ¹²⁵I seeds were fixed on the dish around the 35 mm diameter circumference, with one ¹²⁵I seed placed at the center of dish. C. A 35mm culture dish was placed on the top of the irradiation model.

https://doi.org/10.1371/journal.pone.0147701.g003

The human extrahepatic cholangiocarcinoma cell line FRH-0201 was provided by the Central Laboratory of First People’s Hospital (Shanghai, China), were maintained in Roswell Park Memorial Institute (RPMI) 1640 medium (Gibco, Invitrogen) supplemented with 10% fetal bovine serum (Gibco, Invitrogen) and 1% pen-strep (100 U/ml penicillin and 100 mg/ml streptomycin) (Gibco, Invitrogen) in a 37°C humidified incubator containing 5% CO₂. When the cell concentration reached 1 × 10⁵ cells/mL, cells were placed at the top of the ¹²⁵I seed irradiation model in the incubator. The cells were randomly divided into four groups: group A (control), B (pure silicone, only silicone), C (t-¹²⁵I), and D (s-¹²⁵I), and maintained in culture above the seeds for lengths of time equivalent to 2 and 4 Gy doses.

Apoptosis analysis using flow cytometry: Following exposure to radioactive seeds, 5 x 10⁵ cells were collected from each group and washed twice with phosphate buffered saline. The cell pellet was resuspended in 500 mL ice-cold binding buffer. Then, 5 μL of Annexin V-FITC and 100 uL of propidium iodide solution (Becton-Dickinson, BD, USA) were added to the cell suspension, and mixed by mild vortexing. The samples were incubated for 15 min in the dark before flow cytometric analysis. Stained cells were analyzed with fluorescence-activated cell sorting (BD Biosciences, USA). The assay was performed 3 times for each experimental group.

2.3 Animal preparation

A total of 24 female athymic BALB/c nude mice (6–8 weeks old) weighing 18–20g were supplied by the Laboratory Animal Center of Shanghai First People’s Hospital (Shanghai, China). These mice received humane care in a pathogen-free environment (23 ± 2°C and 55% ± 5% humidity). They were maintained on a 12-h light and 12-h dark cycle, with food and water supplied during the entire experimental period. Animal care and surgery protocols were approved by the Animal Care Committees of Shanghai Jiaotong University.

In order to establish xenograft tumors, 2 × 10⁵ FRH-0201 cells were subcutaneously injected into the back of the BALB/c nude mice. After 16 days, all mice had tumors with a volume of approximately 100 mm³, then were randomly separated into four groups: A (control), B (pure silicone), C (t-¹²⁵I), and D (s-¹²⁵I), three per group according to the volume of tumor calculated by Eq 2 [21]. Tumor volume and mouse weight change ratio (%) were calculated using Eqs 3 and 4, respectively. (2) (3) (4) where V is the tumor volume; L is the tumor length; W is the tumor width; V₁ is the tumor volume measured on the first day; and V_N is the tumor volume measured N days after implantation with ¹²⁵I seeds; W₁ is the mouse weight measured on the first day; and W_N is the mouse weight measured N days after treatment with ¹²⁵I seeds.

All the mice were administered general anesthesia by intraperitoneal injection of pentobarbital sodium, and an 18-gauge needle was used to implant ¹²⁵I seeds, a straight

skin incision, approximately 1 cm long, into the tumour was performed so that sufficient space was created for embedding the ¹²⁵I seed. Finally, the incision was sutured so that the tumor could be treated locally.Fig 4 shows the operative procedure for the seed implantation into the tumor. All tumors volume and mouse weight were measured every two days, and the mice were humanely sacrificed after 16 days.

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Fig 4. Operative procedure for the seed implantation into the tumor: (a) the mouse was given a implantation of seed by tweezers; (b) the seed was implanted into the tumor.

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2.4 TUNEL staining

The fresh tumor tissues were fixed in 10% formalin solution and embedded in paraffin. Formalin-fixed, paraffin embedded blocks were sectioned at 5 mm, and the sections were baked for 1 h at 60°C. The tissue sections were incubated in 0.1% Triton X-100 in 0.1% sodium citrate for 15 min, followed by incubation in 0.3% H₂O₂ for 30 min. The slides were washed three times in phosphate-buffered saline and incubated with 50 μL of TUNEL reaction mixture (TdT and fluorescein-labeled dUTP) in a dark and humid atmosphere for 60 min at 37°C. Slides were mounted in neutral gum medium, and 100 fields were observed with a fluorescence microscope (Olympus, Tokyo, Japan). Pictures were taken with an MZ FLIII stereomicroscope (Leica Microsystems, Deerfield, IL) with red-field transmitted light, and apoptotic cells were counted.

2.5 Hematoxylin and eosin staining

All tumors were fixed in 10% formalin solution, and embedded in paraffin. Formalin-fixed, paraffin-embedded blocks were sectioned at 5 mm, and hematoxylin and eosin stained for examination. A slide of each tumor was evaluated and imaged at a high magnification (×50 and ×200). Representative images were captured with a Leica microscope (Leica Microsystems, Wetzlar, Germany).

2.6 Statistical analyses

All statistical analyses were performed with SPSS software, version 13.0 for Windows (SAS Institute, Cary, NC). Data are presented as mean ± standard deviation. Student’s t-tests were used to compare apoptosis of tumor cells, as well as the volume and weight change before and after treatment. Student’s t-test was also used to compare the number of apoptotic cells following TUNEL staining. Because multiple comparisons were performed on some data, it was noted wherever statistical significance would be removed by using the Bonferroni method. Further, p < 0.05 was considered statistically significant.

Result

3.1 Utilization of ¹²⁵I radionuclides

With the help of a coaxial electrospinning device, the production of silicone ¹²⁵I seed was straightforward, the radioactivity of s-¹²⁵I seeds were obviously higher than the t-¹²⁵I seeds (Fig 5), and the radionuclide was well dispersed within the silicon-silver. As shown in Table 2, ¹²⁵I is highly utilized by the silicone seeds. According to Eq 1, the utilization of ¹²⁵I by silicone was highly improved, with 91.2% of the ¹²⁵I being utilized, while the titanium only utilized 50.1% of the ¹²⁵I. Throughout all procedures, safe handling of the radionuclide was prioritized, and the remaining solution required less than 185 Bq (5 nCi).

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Fig 5. The radioactivity comparison of s-¹²⁵I seeds and t-¹²⁵I seeds.

The radioactivity of s-¹²⁵I is higher than t-¹²⁵I obviously.

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Table 2. The radioactivity and radionuclide utilization ratio comparison of s-¹²⁵I Seeds and t-¹²⁵I Seeds.

https://doi.org/10.1371/journal.pone.0147701.t002

3.2 Apoptosis analysis

Tumor cells both in the control and silicone groups exhibited minimal apoptosis, while the ¹²⁵I seed groups displayed an obvious increase in apoptosis. The percentage of apoptotic cells in the 2 Gy groups were 19.40% ± 0.64% for silicone ¹²⁵I and 20.00% ± 0.56% for titanium ¹²⁵I seeds(P>0.05). When cells were treated with 4 Gy, the apoptosis increased to 61.78% ± 0.90% for silicone ¹²⁵I and 63.37% ± 0.44% for titanium ¹²⁵I(P>0.05). Importantly, at either radiation dose, the silicone and titanium coated ¹²⁵I exhibited a similar induction of apoptosis in tumor cells (Fig 6).

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Fig 6. Evaluation of the in vitro anti-tumour effects of ¹²⁵I seeds.

(a) and (b)apoptotic progression in FRH-0201 cell lines in response to the titanium ¹²⁵I seeds and silicone ¹²⁵I seeds treatment for 2Gy and 4Gy; (c) cell FACS distributions (%) of apoptotic cells in different groups. Quadrant Q1,Q2,Q3 and Q4 reflect necrosis, late apoptosis, alive and early apoptosis, respectively.Total apoptosis includes late apoptosis plus early apoptosis. There was not significance between titanium ¹²⁵I seeds and silicone ¹²⁵I seeds groups. * P <0.05 means 4Gy compared with the 2 Gy groups respectively.

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3.3 The inhibition of tumor growth

No mice died during the experiment; however, one mouse in the titanium group lost the ¹²⁵I seed. Our results showed that the tumor volume in the pure silicone group and control group increased rapidly over 2 weeks. Mice treated with either silicone or titanium coated ¹²⁵I seeds show significant inhibition of tumor volume, with only a small increase in tumor volume (Fig 7A). Our observation of inhibition of tumor growth is consistent with the results of cell apoptosis by flow cytometry indicating that silicone and titanium ¹²⁵I have similar therapeutic efficacy in vivo. The weight change ratio shown in Fig 7B illustrates that the silicone ¹²⁵I seeds do not induce obvious side effects in vivo, because the mice weights remained stable.

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Fig 7. Investigation into the in vivo anti-tumor effects of the ¹²⁵I seeds: (a,b)graphs of tumor growth and mice weight change after treatment with titanium ¹²⁵I seeds and silicone ¹²⁵I seeds in vivo.

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3.4 Tissue staining analysis

Representative TUNEL stains obtained from the four groups are shown in Fig 8A. For either silicone or titanium ¹²⁵I seeds, the average number of apoptotic cells was significantly higher than that for the control group (p < 0.05), but there was no statistically significant difference between the two coatings (Fig 8B). These data also suggest that the ¹²⁵I seed implantation induced significant apoptosis in extrahepatic CC.

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Fig 8. Anti-tumor effects of the ¹²⁵I seeds by TUNEL staining:(a)the red spots represented the apoptotic cells detected by TUNEL staining in the each groups. The average number of apoptotic cells per 100 objective fields were plotted.(b) *P < 0.05 compared with the control group.

#P < 0.05 compared with the pure silicone group.

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Due to the rapid tumor growth in the control and pure silicone groups, tissue necrosis and ischemia were most frequently observed (Fig 9). However, the silicone and titanium ¹²⁵I groups illustrated inhibition of tumor growth, and very few necrotic or apoptotic cells were observed in the tumors.

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Fig 9. HE staining.

The tumor histopathology for all ¹²⁵I seeds and pure silicone groups after treatment. Tissue necrosis and ischemia were most frequently observed in the control and pure silicone groups, the silicone and titanium ¹²⁵I groups showed very few necrotic or apoptotic cells were observed in the tumors.

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Discussion

Biliary stent placement has been recommended as a palliative approach for the treatment of extrahepatic CC[2–7]. Several studies have demonstrated that stent insertion could relieve duct obstruction and maintain biliary drainage[22–26]. However, restenosis ignited by newly developed in-stent tumors is still an obstacle for this approach, and decreases survival[26–27]. To further control the growth of carcinoma, brachytherapy such as iridium 192 or holmium 166 in combination with stenting have been introduced. Although several studies showed favorable results, the efficacy of this approach remains controversial[11–14]. Furthermore, although holmium 166 and iridium 192 have been safely used for long-term brachytherapy, their half-life and penetration depth are short. In addition, an isolated, well-shielded room is needed for protection and to decrease the incidence of side effects to other organs when using iridium 192.

The ¹²⁵I seed has a half-life of 59.6 days, and its whole failure period is about 400 days, can be implanted into the body, are under investigation as a promising brachytherapy source for carcinoma owing to their good treatment effect and low incidence of complications[14–16]. Several studies have demonstrated that implanting ¹²⁵I seeds achieves satisfactory outcomes for unresectable pancreatic and hepatic carcinoma[28–29]; however, reports on extrahepatic CC are scarce because the bile tract anatomical structure makes implantation difficult to perform, and the titanium ¹²⁵I seeds easily migrate. Thus, the radioactive seeds combined with biliary stenting may be an alternative approach. The ¹²⁵I seeds coated by titanium are safety for radionuclide leakage and undegradable. However, the titanium-coated seeds are expensive, it is a burden for patients who need many seeds for the treatment in clinical, and due to the self-shielding effect, the radioactivity of ¹²⁵I seeds weakens, and considerably more ¹²⁵I solution is consumed during the procedure. Therefore, a long duration of treatment increases medical costs and requires good patient compliance. Medical silicone has been widely used for biomedical purposes. Compared to titanium, medical silicone also offers good tightness for ¹²⁵I radionuclide, besides, including good biocompatibility, low cost and availability. Several studies achieved satisfactory outcomes by using silicone as biological drug delivery material[18–19].S. Radin et al. reported silica sol-gel showed biocompatibility and controlled resorbability of the drug composite in vivo, suggests that silica sol-gel is a promising carrier for the treatment of bone infections[30]. However, little research has been conducted into the use of silicone-coated ¹²⁵I seeds for extrahepatic CC.

Although there is currently no adequate evidence to support the routine use of ¹²⁵I radiotherapy postoperatively or for unresectable extrahepatic CC, important palliative value still have been reported. A epidemiological retrospective study in 4758 patients with extrahepatic CC suggested that palliative radiotherapy prolonged survival[31]. In our study, we developed a novel silicone-coated ¹²⁵I seed. The silicone mixed with silver to form silver-silicone showed good absorption of ¹²⁵I, and the silver-silicone is well encapsulated by silicone in combination with the technology of coaxial electrospinning. We found that the coating membrane was a nanofiber mixture, the ¹²⁵I was stably distributed in the core, and the silicone ¹²⁵I seeds have a higher utilization of ¹²⁵I. Our study demonstrated that novel silicone ¹²⁵I seeds inhibit extrahepatic CC with a similar efficacy as that achieved with titanium ¹²⁵I seeds. In vitro experiments showed that the apoptosis rates were similar for the silicone ¹²⁵I and titanium ¹²⁵I seed groups. In vivo, control nude mice, which were not implanted with ¹²⁵I seeds, showed rapid tumor growth after 16 days. In contrast, both the silicone ¹²⁵I and titanium ¹²⁵I seed groups exhibited significantly decreased tumor growth, and both groups showed similar tumor inhibition, Furthermore, the mice weights remained relatively stable throughout the experiment, because the ¹²⁵I seeds effectively inhibited tumor growth. These datas demonstrate the feasibility of silicone ¹²⁵I seeds as a palliative treatment for extrahepatic CC.

However, this study still has some limitations. First, although we measured the leakage of silicone ¹²⁵I seeds to guarantee the safety of radionuclides in this procedure, it is an in vitro study, and the significance is limited by the nature of experimental research. Second, we established the xenografts on the back of mice as a model; however, the subcutaneous environment and the bile duct environment are different. The aim of our current study was to investigate the inhibition of tumor growth; however, our study lasted only for 16 days. As it is known, the significant role of silicone-coated ¹²⁵I seeds are to be applied in the clinical work, treatment of patients, where the silicone ¹²⁵I seeds are combined with a stent as a treatment for extrahepatic CC, may require much more time in vivo[24–25]. Therefore, a longer observation period is require, so far, we have successfully complete this novel silicone ¹²⁵I seeds in combination with the placement of a stent in pig bile duct. The silicone ¹²⁵I seeds performance, in vivo degradation, effects in the bile duct tissues of the model will be observed and analyzed in the future to ensure our model yields an accurate outcome.

Conclusions

¹²⁵I seeds coated with titanium are considered a safe and effective interstitial brachytherapy for tumors. In this work, ¹²⁵I were mixed and coated with a modified coaxial electros-pinning machine showed silicone coating ¹²⁵I seeds are straightforward to produce,. The results demonstrated that silicone ¹²⁵I seeds showed higher radioactivity, compared to titanium ¹²⁵I seeds. The results for the cell cycle and apoptosis evaluation showed that the silicone ¹²⁵I seeds share the same anti-tumor effect with titanium ¹²⁵I seeds, and the sustainable irradiation provided better anti-tumor effect. Furthermore, in vivo, the implanted titanium ¹²⁵I seeds and the silicone ¹²⁵I seeds demontrated the similar anti-tumor capability. Silicone-coated ¹²⁵I seeds hold promise for treating extrahepatic CC. Further studies are needed to determine the efficacy and safety of silicone-coated ¹²⁵I seeds in combination with biliary stenting in vivo.

Supporting Information

S1 Fig. Dates of mouse weight and volume change.

https://doi.org/10.1371/journal.pone.0147701.s001

(TIF)

S1 Table. The table includes the minimal dates of cell apoptosis,the assay was performed 3 times for each experimental group.

https://doi.org/10.1371/journal.pone.0147701.s002

(XLS)

Acknowledgments

We would like to sincerely thank Zhongming Xiao from the hospital for assistance with cell experiments, and Prof. Xiumei Mo for the support with the equipment installation. We also would like to thank the XinKe Co. for the support of the production of titanium ¹²⁵I.

Author Contributions

Conceived and designed the experiments: LL LG XW. Performed the experiments: LL. Analyzed the data: LL WZ. Contributed reagents/materials/analysis tools: WZ. Wrote the paper: LL. Helped to guide the manuscript writing: XC DC.

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Figures

Abstract

Introduction

Materials and Methods

2.1. Coating technique

2.2 Cell apoptosis evaluation in vitro

2.3 Animal preparation

2.4 TUNEL staining

2.5 Hematoxylin and eosin staining

2.6 Statistical analyses

Result

3.1 Utilization of 125I radionuclides

3.2 Apoptosis analysis

3.3 The inhibition of tumor growth

3.4 Tissue staining analysis

Discussion

Conclusions

Supporting Information

S1 Fig. Dates of mouse weight and volume change.

S1 Table. The table includes the minimal dates of cell apoptosis,the assay was performed 3 times for each experimental group.

Acknowledgments

Author Contributions

References

3.1 Utilization of ¹²⁵I radionuclides