- Open Access
Low temperature of radiofrequency ablation at the target sites can facilitate rapid progression of residual hepatic VX2 carcinoma
Journal of Translational Medicinevolume 8, Article number: 73 (2010)
Rapid progression of residual tumor after radiofrequency ablation (RFA) of hepatocellular carcinoma has been observed increasingly. However, its underlying mechanisms remain to be clarified. The present study was designed to determine whether low temperature of RFA at the target sites facilitates rapid progression of residual hepatic VX2 carcinoma and to clarify the possible underlying mechanisms.
The residual VX2 hepatoma model in rabbits was established by using RFA at 55, 70 and 85°C. Rabbits that were implanted with VX2 hepatoma but did not receive RFA acted as a control group. The relationship between rapid progression of residual hepatic VX2 carcinoma and low temperature of RFA at the target sites was carefully evaluated. A number of potential contributing molecular factors, such as proliferating cell nuclear antigen (PCNA), matrix metalloproteinase 9 (MMP-9), vascular endothelial growth factor (VEGF), hepatocyte growth factor (HGF) and Interleukin-6 (IL-6) were measured.
The focal tumor volume and lung metastases of RFA-treated rabbits increased significantly compared with the control group (P < 0.05), and the greatest changes were seen in the 55°C group (P < 0.05). Expression of PCNA, MMP-9, VEGF, HGF and IL-6 in tumor tissues increased significantly in the RFA-treated groups compared with the control group, and of the increases were greatest in the 55°C group (P < 0.05). These results were consistent with gross pathological observation. Tumor re-inoculation experiments confirmed that low temperature of RFA at the target sites facilitated rapid progression of residual hepatic VX2 carcinoma.
Insufficient RFA that is caused by low temperature at the target sites could be an important cause of rapid progression of residual hepatic VX2 carcinoma. Residual hepatic VX2 carcinoma could facilitate its rapid progression through inducing overexpression of several molecular factors, such as PCNA, MMP-9, VEGF, HGF and IL-6.
Hepatocellular carcinoma (HCC) is still one of the most important diseases for health care systems due to its high morbidity, mortality and increasing incidence worldwide . Although hepatic resection and transplantation have been considered as the main curative therapies for HCC, the vast majority of patients are not eligible when this tumor is detected. Only about 20% of HCC cases are resectable [2, 3]. Currently, various local ablative therapies, such as radiofrequency ablation (RFA), have been accepted as an alternative treatment option for HCC, because of its several advantages, such as definitive therapeutic effect, minimal invasiveness, repeatability, safety, and shorter hospitalization .
At present, residual tumor is one of the main obstacles that greatly hinders the effectiveness of RFA for HCC . The residual tumor cannot be entirely avoided for several reasons, such as the mechanisms of RFA, the pathological characteristics of HCC, and the anatomical traits of the liver. The reasons for residual tumor can be categorized as follows: First, the target temperature for ablation cannot be easily reached due to the "heat sink" effect of blood vessels, especially large vessels, within or around the tumor . Second, the operator might deliberately reduce the local intensity of RFA to avoid unintended injury when the tumor is adjacent to an organ such as the stomach, intestine or gallbladder. Third, the performance of overlapping ablation in a mathematically irregular fashion is difficult, especially by the percutaneous route. As a result, nests of viable tumor cells remain in the clefts between the incompletely fused coagulation zones. Finally, the microvascular invasion area that surrounds the main tumor in HCC is sometimes wider than expected, or undetected microscopic satellite tumor lesions might be present .
Since 2001, rapid progression of residual tumor after RFA of HCC has been observed increasingly [7, 8]. Cumulative evidence has demonstrated that residual tumor after RFA might exhibit an aggressive phenotype and unfavorable prognosis , and even change to sarcoma , which leads to deterioration of the patient's condition. The conventional concepts of residual tumor have been greatly altered recently. It is believed that clarifying the underlying mechanisms of rapid progression of residual tumor might have a significant effect on the therapeutic principle and strategy of RFA for HCC .
Based on analysis of the aforementioned risk factors, we hypothesized that low temperature of RFA at the target sites, which leads to incomplete ablation, might play an important role in facilitating rapid progression of residual tumor of HCC after RFA. The present study was designed to test this hypothesis and to clarify the possible underlying mechanisms.
Animals and tumor inoculation
The experiments were performed with New Zealand white rabbits that weighed 2.5-3.0 kg. The experiments were approved by the Animal Care Committee of Capital Medical University, Beijing, China and were performed in accordance with the institutional guidelines. The animals were anesthetized with an intravenous injection of 35 mg/kg pentobarbital. The animals were allowed food and water ad libitum between the various procedures. A schematic diagram has been produced and added to illustrate the experimental procedures (Fig. 1). VX2 carcinoma was used to establish the model of HCC. VX2 carcinoma is an anaplastic squamous cell carcinoma that is derived from a virus-induced papilloma in wild rabbits, but appears as a carcinoma in the domestic species. VX2 tumors were first grown for 2 weeks on the hind legs of carrier rabbits and then were harvested after they reached a size of 1.5 cm. The harvested tumors were placed into saline solution and cut into cubes of 1 mm3. Only portions of tumor tissue that did not show any macroscopic signs of necrosis were used. Abdomens of the recipient rabbits were shaved and prepared with povidone iodine, and a midline subxyphoid incision was made. The anterior surface of the liver was exposed and one of the prepared cubes of tumor tissue was implanted in the left lobe of the liver using a 21-gauge angioneedle (Becton Dickinson, Sandy, UT, USA). This method allowed the growth of a solitary, well-demarcated tumor. There was only one inoculation site in each liver. Proper aseptic technique was rigorously observed during each inoculation. After surgery, the animals were returned to their cages, kept warm, and monitored in the animal laboratory until they recovered from anesthesia. An HDI 5000 ultrasound system (Philips Healthcare, Bothell, WA, USA) with a 7.5-MHz linear probe was used to monitor the tumor size. Based on the methods described previously[11, 12] and our experimental design, VX2 carcinoma nodules > 2.0 cm in diameter were considered appropriate for RFA. The period for tumors to reach the size of 2.0 cm ranged from 16 to 18 days. All inoculations were performed by the same individual investigator, who inoculated specimens of the same tumor into all rabbits to minimize inter-animal variations in tumor growth rate.
Model of residual hepatic VX2 carcinoma following RFA
The RFA procedure for residual hepatic VX2 carcinoma was standardized in advance as depicted in Fig. 1 and Fig. 2. Sixty rabbits were randomly divided into four groups of 15: group I was treated with RFA at 55°C; group II was treated with RFA at 70°C; group III was treated with RFA at 85°C; and the control group received laparotomy, RFA probe puncture but no ablation. RFA was performed using the same anesthesia protocol as for carcinoma implantation. Two grounding pads were applied to the animal's flank before RFA. Abdomens of the experimental rabbits were shaved and prepared with povidone iodine, and a midline subxyphoid incision was made. The tumor size was measured and the tumor was ablated. The tumor center was also designated as the RFA center. The measured minor axis of the tumor was used to guide the release of the RFA needle electrode. Thus, residual tumor was left on both sides of the measured major axis of the tumor (shadowed area depicted in Fig. 2). An RF current generator (Model 1500X Generator; RITA Medical Systems, Manchester, GA, USA) was used to generate RF energy. To deliver RF energy, we used a 14-gauge expandable RF needle electrode (StarBurst™ XL; RITA Medical Systems), 10 cm in length. Each ablation cycle lasted for 5 min.
Gross pathological analysis
The rabbits were sacrificed by injecting an overdose of ketamine and xylazine 10 days after RFA. The liver and lungs were carefully dissected and excised. The number and size of masses were noted. The pathological findings could thus be compared directly with the tumor numbers, volumes and locations. Quantitative evaluation of the lung metastatic nodules was made by two observers using the following procedures: macroscopic study by stereoscopic magnifying glass (Olympus SZH, Zeiss Stemi DV4, Germany) and counting the metastatic nodules on the pleural surface of the whole lobules . The variation between the observers' findings was < 5%.
The streptavidin-peroxidase two-step method was used for immunohistochemical detection of matrix metalloproteinase 9 (MMP-9), vascular endothelial growth factor (VEGF) and proliferating cell nuclear antigen (PCNA). Representative 5-μm tissue sections were cut from paraffin-embedded specimens. The sections were washed three times for 3 min with PBS, and blocked with a solution of 30 mL/L hydrogen peroxide in ethanol for 10 min at room temperature. They were immersed in 30 mL/L normal horse serum for 10 min at room temperature. The sections were incubated for 1 h with primary antibodies (mouse monoclonal antibodies; Abcam, Cambridge, UK) specific to MMP-9 (dilution 1:50), VEGF (dilution 1:50) or PCNA (dilution 1:100). Negative controls consisted of tissue sections incubated with Tris-buffered saline (TBS) instead of the primary antibody. The immunoreactivity was then visualized by incubating the samples in 3,3'-diaminobenzedine. Finally, the slides were counterstained with hematoxylin. To evaluate the expression of MMP-9, VEGF and PCNA, all slides were examined and scored by two independent pathologists who were blinded to the animal data. A few cases with discrepant scores were reevaluated to reach a final agreement. Any slides that exhibited diffuse immunostaining or > 50% tumor cells were classified as (++), > 10% but < 50% as (+), and < 10% as (-).
Proteins for Western blotting were isolated from fresh-frozen tissue using T-Per extraction reagent (Pierce Biotechnology, Rockford, IL, USA) according to the manufacturer's recommendations. The supernatants were frozen at -80°C until use. The proteins were fractionated by 10% SDS-PAGE and followed by electrotransfer onto nitrocellulose filters (Bio-Rad, CA, USA). The filters were blocked at 4°C overnight with a blocking buffer (pH 7.6) that contained 5% non-fat dry milk. The filters were incubated with a primary monoclonal antibody to MMP-9 (1:200; Abcam), VEGF (1:200; Abcam), PCNA (1:200; Abcam), and a secondary antimouse HRP-antibody (1:2000; Santa Cruz Biotechnology, Santa Cruz, CA, USA) for 2 h at room temperature. Immunoreactive bands were visualized using ECL detection reagents (Amersham Pharmacia Biotech, Little Chalfont, Bucks, UK).
Expression of hepatocyte growth factor (HGF) in tissues was measured using the ELISA Kit for Rabbit HGF according to the manufacturer's instructions (USCN Life Science, Wuhan, China). Expression of interleukin 6 (IL-6) in tissues was measured using the ELISA Kit for Rabbit IL-6 according to the manufacturer's instructions (USCN Life Science, Wuhan, China).
The rabbits were sacrificed and the liver tumors were harvested simultaneously 10 days after RFA. The harvested tumors were placed in saline solution and cut into cubes of 1 mm3. Only portions of tumor tissue that did not show any macroscopic signs of necrosis were used. The tumor tissue was reinoculated subcutaneously into the hind legs of the rabbits as depicted in Fig. 1. Tumor sizes were measured every 1-2 days, with tumor volumes calculated according to the formula : V = ab2/2, where, a is the longest and b the smallest diameter of the tumor in vivo. Rabbits were sacrificed 21 days after reinoculation or when they became moribund. The tumor, liver and lungs were carefully dissected and examined.
Data were presented as the means ± SD for the indicated number of separate experiments. Statistical analysis was performed using SPSS version 11.5. One-way ANOVA followed by the Newman-Keuls test, Kruskal-Wallis H test, Mann-Whitney test and Student's t test were used to evaluate statistical significance and P < 0.05 was considered significant.
Effects of low temperature of RFA at the target sites on growth of hepatic VX2 carcinoma
We showed in our previous experiments that residual hepatic VX2 carcinoma could be seen microscopically in groups I, II and III. We determined the effects of 5 min RFA at each temperature on the growth of hepatic VX2 carcinoma. The changes in tumor volume were 24.21 ± 3.94 cm3 in group I, 17.28 ± 1.84 cm3 in group II and 15.48 ± 0.91 cm3 in group III, which were all larger than that in the control group (12.63 ± 1.87 cm3). It seemed that the lower the temperature of RFA was, the larger the tumor volume was (Fig. 3).
Effects of low temperature of RFA at the target sites on lung metastasis of hepatic VX2 carcinoma
We examined by gross observation lung metastasis of hepatic VX2 carcinoma after RFA at low temperature. Quantifiable metastatic nodules were taken to be those structures of a white-grey coloration that could be distinguished on the lung surface and which was sufficiently separated from each other to be counted individually (Fig. 4A and 4B). The numbers of metastatic nodules are shown in Fig. 5. The control group had between 55 and 80 metastatic nodules randomly distributed over the lung surface, with a mean of 69.0 ± 10.5. Group I showed a mean of 302.2 ± 21.6, group II, a mean of 137.2 ± 16.3, and group III, a mean of 99.6 ± 10.5. Group I was treated with the lowest temperature, therefore, it showed the greatest increase in metastatic nodules compared with all the other groups (P < 0.05).
MMP-9, VEGF and PCNA were found to be mainly expressed in cancerous lesions, but also in some normal tissues (Fig. 6). In vitro cell invasiveness was assessed using anti-MMP-9 antibody. In vitro cell proliferation and angiogenesis were evaluated using anti-PCNA and anti-VEGF antibodies, respectively (Fig. 6). The percentage of positive MMP-9, VEGF and PCNA tumor cells in the RFA treatment groups were markedly higher than that in the control group (Table 1, P < 0.05). Compared with groups II and III, the percentage of positive MMP-9, VEGF and PCNA tumor cells in group I was even higher (P < 0.05).
MMP-9, VEGF and PCNA expression in residual hepatic VX2 carcinoma tissues
Expression of MMP-9 in tumor tissues was markedly decreased in the control group, and incomplete RFA due to low temperature at the target sites significantly increased MMP-9 level in the other groups (Fig. 7). Similarly, incomplete RFA significantly elevated protein expression of VEGF and PCNA in groups I, II and III. At the same time, expression of VEGF and PCNA was markedly decreased in tumor tissues in the control group (Fig. 7). The lower the target temperature of RFA was, the higher was the expression of MMP-9, VEGF and PCNA in residual hepatic VX2 carcinoma tissues. These results had a similar trend as those of the immunohistochemical assays.
Tissue levels of HGF and IL-6 at the time of animal killing
To assess whether any cytokines from the tumor microenvironment might be involved in rapid tumor progression after incomplete RFA, the levels of HGF and IL-6 were determined in tumor and normal tissues from the same liver at the time of animal killing. Expression of HGF and IL-6 in the tumor tissues of group I increased dramatically in comparison with that in the control group. At the same time, the concentrations of HGF and IL-6 in non-ablated liver tissues in group I were much higher than those in liver tissues in the control group (Fig. 8).
Measurement of tumor growth and metastasis after reinoculation
To demonstrate further the role of low temperature of RFA at the target sites in the rapid progression of residual hepatic VX2 carcinoma, tumor tissues that survived the first RFA at 55°C were reinoculated to other normal rabbits. The tumor growth and metastasis were carefully observed individually. It was found that tumor growth and lung metastasis in the RFA groups were much more obvious than in the control group (Figs. 9 and 10). However, no liver metastasis was detected in any of the groups.
It was demonstrated directly or indirectly in our study that residual tumor was prone to proliferation, invasion and metastasis when the local ablative temperature was not sufficiently high. Besides, it seemed that the lower the target temperature was, the more significant were the local proliferation and distant metastasis (e.g. to the lungs) of the tumor. It is known that different cells, such as tumor cells, have different endurance to heat. Some cells can even survive high temperature from 50-55°C. However, cells can seldom survive temperatures above 55°C . Therefore, it seems that most residual tumor and rapid progression should occur when the temperature is below 55°C, which is consistent with the results of our study.
In clinical settings, although the target temperature can be set as high as 105-115°C during RFA, only the tissues that surround the electrodes can reach that temperature . In fact, the real temperature of the tumor tissue between the two adjacent electrodes is lower than the target temperature because of the "heat sink" effect of blood flow . Residual tumor can occur whenever the local ablative temperature is sufficiently low. In the present study, the VX2 nodules were transplanted into the liver rather than derived from the liver itself, therefore, the feeding artery and the heat sink effect were less than those for HCC. The real ablative temperature of the tumor might be nearer to the target temperature, compared with the clinical situation. This was why we chose 85°C as the highest RFA temperature.
At present, a large number of molecular factors have been shown to be associated with HCC invasion and metastasis, such as PCNA, MMP-9, VEGF, HGF and IL-6. PCNA is a nuclear protein that plays a key role in cell proliferation, DNA repair and cell cycle control . In cirrhotic patients, a high level of PCNA immunolabeling is associated with an increased risk of HCC [17, 18], and in HCC, high PCNA values are associated with poor prognosis . Cell invasion is a major component of the complex multistep process of tumor metastasis. Invasion of malignant tumor cells requires destruction of basement membranes and proteolysis of extracellular matrix (ECM). Of the several families of ECM-degrading enzymes, the most extensive are the MMPs, which are a large family of structurally related zinc endopeptidases that collectively degrade most of the ECM components [19, 20]. Among previously reported human MMPs, MMP-9 is thought to be a vital enzyme for degrading type IV collagen and is postulated to play an important role in HCC invasion and metastasis [21, 22].
Tumor angiogenesis is another crucial step in the growth and metastasis of cancer, including HCC, and has drawn much attention in recent years [23, 24]. Hence, the molecular basis of tumor angiogenesis has been a major interest in the field of cancer research. The VEGF pathway is well established as an important driving force of this process . To date, increasing evidence indicates that tumor-stromal cell interactions have a crucial role in tumor initiation and progression . These interactions modify cellular compartments, which leads to the co-evolution of tumor cells and their microenvironment. HGF, also known as scatter factor, is produced by non-parenchymal liver cells, and is a multifunctional cytokine of the tumor microenvironment of HCC . HGF accomplishes most of the functions of the invasive program in carcinomas (loss of adhesive junctions, motility, angiogenesis, and survival/apoptosis). HGF receptor, also known as c-Met, plays important roles in angiogenesis and tumor growth . It has been reported that c-Met expression is significantly higher in the invasive type of HCC, as determined by gross type, vessel invasion, intrahepatic metastasis and histological type, and induction of c-Met might be used as a indicator of HCC progression, especially intrahepatic metastasis .
IL-6 is a multifunctional regulator of the immune response and hematopoiesis. Recently, it has been reported that expression of IL-6 is correlated with prognosis in various cancer patients [30–32]. Kanazawa et al.  have reported that IL-6 can directly influence cell proliferation and the invasion potential as the first step of tumor metastasis. Hong et al.  believe that therapeutic targeting of IL-6 and its receptor in cancer has a strong biological rationale, and there is preliminary evidence to suggest that targeting of the IL-6 system might be beneficial in the treatment of cancer. In the present study, it was shown that expression of PCNA, MMP-9, VEGF, HGF and IL-6 in tumor tissues in groups I, II and III, which received incomplete RFA, increased remarkably. Furthermore, it seemed that the lower the target temperature of RFA was, the higher was the expression of these molecular factors. This was consistent with the results of tumor inoculation and reinoculation studies. These data suggest that the residual tumor cells facilitate tumor growth and metastasis through induction of overexpression of PCNA, MMP-9, VEGF, HGF and IL-6.
It is important to clarify the underlying mechanisms of rapid progression of residual HCC after RFA, to optimize the therapeutic principles and strategies of RFA. It has been reported that HGF/c-Met signaling can activate multiple signal transduction pathways, including the Src/focal adhesion kinase pathway, the p120/signal transducer and activator of transcription 3 pathway, the phosphoinositide-3 kinase (PI3K)/Akt pathway, and the MEK/ERK pathway [34, 35]. It has been confirmed that the PI3K/Akt and MEK/ERK pathways play a vital role in tumor invasion and metastasis [36–40]. Increasing evidence has demonstrated that the HGF/c-Met signaling pathway could be another valuable pathway for research on tumor target therapy, besides the VEGF signal pathway. HGF/c-Met signaling is activated in angiogenesis and tumor growth, therefore, several strategies have been explored for inhibiting this pathway. Some inhibitors of the HGF/c-Met signaling pathway have been developed and introduced into preclinical and phase I and II clinical trials . In our study, we found that expression of HGF in tumor tissues after incomplete RFA was much higher than that in tumor tissues without RFA. This indicates that the HGF/c-Met signaling pathway might be involved in the rapid progression of residual tumor after RFA. Further research in this area could have potential for enhancing the therapeutic effect of RFA on HCC. Another significant finding was that expression of HGF and IL-6 in non-ablated liver tissues in group I were much higher than those in liver tissues in the control group. We supposed that both the liver injury triggered by RFA and autocrine loop in tumor cells may involve in it. However, this needs to be confirmed.
In conclusion, the results of this study highlight two issues. Firstly, insufficient RFA, which is caused by low temperature at the target sites, could be an important reason for rapid progression of residual hepatic VX2 carcinoma. Secondly, residual hepatic VX2 carcinoma might facilitate rapid tumor progression through induction of overexpression of multiple molecular factors, such as PCNA, MMP-9, VEGF, HGF and IL-6.
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The authors appreciate technical assistance from P. Gu and Y. Xie, valuable discussion with Y.Q. Liu, and help from experimental animal facility technicians for animal care. This work was supported by grants from National Natural Science Foundation of China (No.30872490) and Dr. Wu Jie-ping Medical foundation (No.320675007131).
The authors declare that they have no competing interests.
SK, XD and JK performed the rabbit experiments and ELISA analysis. JG, SW and YC carried out the immunohistochemistry, XD and JK performed the western blotting. SK, XD and WS conceived and designed the experiments and analyzed the data. The manuscript was written by SK and WS. All authors read and approved the final manuscript.
Shan Ke, Xue-mei Ding contributed equally to this work.
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