1. Introduction
Hepatocellular carcinoma (HCC) is the leading primary cancer of the liver. It is one of the most common malignancies globally and the cause of substantial health-related problems, making it the third most frequent cause of cancer-related deaths in the world [
1]. The Barcelona Clinic Liver Cancer (BCLC) staging system is the most widely used treatment algorithm worldwide [
2]. Patients with early-stage HCC based on the BCLC staging system [
2] are treated with curative therapies such as surgical resection, transplantation, or locoregional therapies, which include radiofrequency ablation (RFA) and microwave thermosphere ablation (MTA) [
3].
Percutaneous RFA has recently become widely used because of its ease of use, safety, and efficacy in the treatment of hepatocellular carcinoma in patients with chronic liver disease [
4,
5,
6,
7]. RFA can be performed repeatedly and is particularly useful in reducing intrahepatic recurrence [
8].
Microwave ablation (MWA) has been developed as another percutaneous thermal ablation therapy for HCC. Compared to RFA, MWA has the advantage of faster heat generation and higher generated temperatures, making it less susceptible to heat sinking [
9]. However, conventional MWAs have several significant disadvantages. First, the ablation zone in conventional MWAs was tear-drop-shaped. Therefore, after developing higher power systems, the risk of thermal damage to subcutaneous tissue and skin was high when performing ablation on subcapsular tumors in the liver with conventional MWA [
9]. Second, changes in the surrounding tissue cannot predict the size of the ablation area in conventional MWA [
9]. To overcome these disadvantages, Emprint™ (Covidien, Boulder, CO, USA) was developed as a next-generation MWA system using MTA technology. MTA can make predictable spherical ablation zones by incorporating field control, thermal control, and wavelength control technologies into the system. This new system was approved for use in the United States in April 2014 and in Japan in July 2017. In this study, we investigated the clinical outcomes of patients with HCC who underwent next-generation MTA at our hospital.
2. Materials and Methods
2.1. Patients
All procedures in this retrospective analysis of database records complied with the Declaration of Helsinki. The study protocol was approved by the institutional ethics committee of the Japanese Red Cross Society Himeji Hospital (IRB No. H30-34) based on the Guidelines for Clinical Research issued by the Ministry of Health, Labour and Welfare of Japan. Informed consent to analyze the data was obtained from all patients.
Between September 2019 and September 2022, 436 consecutive patients with 615 HCCs were treated with MTA at the Japanese Red Cross Society Himeji Hospital. We excluded patients who met the following criteria: (1) maximum tumor diameter > 40 mm (4 patients with 4 HCCs) or (2) lost to follow-up (3 patients with 4 HCCs). Consequently, 429 patients with 607 HCCs were enrolled in the study (
Figure 1).
In September 2019, MTA therapy began to be used as a percutaneous local ablation therapy for HCC at our hospital. Until September 2019, RFA was used as a percutaneous local ablation therapy for HCC at our hospital. However, after the start of MTA therapy, the number of patients undergoing RFA decreased. Since January 2020, MTA therapy has been performed on all patients with HCC for whom percutaneous local ablation therapy was indicated.
HCC etiology was defined as hepatitis B virus in patients positive for hepatitis B virus surface antigen. It was defined as hepatitis C virus in those positive for hepatitis C virus antibodies.
The start of follow-up was defined as when the first MTA treatment was administered. The end of follow-up was defined as the date of the last visit for patients who were alive and the date of death for patients who died during the follow-up period.
2.2. Diagnosis and Treatment of HCC
HCC was diagnosed based on the results of multi-phasic contrast-enhanced computed tomography (CECT), gadolinium ethoxybenzyl diethylenetriamine pentaacetic acid (Gd-EOB-DTPA)-enhanced magnetic resonance imaging (MRI), contrast-enhanced ultrasonography (CEUS), pathological examination, or a combination of these modalities, as well as increases in levels of tumor markers such as α-fetoprotein (AFP), des-γ-carboxy prothrombin (DCP), and lens culinaris agglutinin-reactive α-fetoprotein (AFP-L3). The diagnostic criteria of HCC, according to imaging modalities, were based on previous reports of hyper-attenuation at the hepatic arterial phase, hypo-attenuation at the portal venous phase in triple-phase CT or MR imaging, or hyper-enhancement in the arterial phase, hypo-enhancement in the portal venous, and late phases in contrast-enhanced US (CEUS) [
10,
11].
The Japanese practice guidelines for HCC [
12,
13] state that MTA is indicated for patients with 3 or fewer HCCs (none > 3 cm). For patients classified as having more severe HCC, MTA was selected based on discussions among hepatologists, surgeons, and radiologists with consideration of the patient’s background such as Eastern Cooperative Oncology Group Performance Status (ECOG-PS), hepatic function, and tolerance for surgery. Informed consent was obtained from each patient.
2.3. MTA Technique
The Emprint™ ablation system with a 13-gauge standard antenna (20-cm long) was used for MTA. Prior to percutaneous MTA therapy, 15 mg of pentazocine hydrochloride and 25 mg of hydroxyzine hydrochloride were administered intravenously. Local anesthesia was induced with 5 mL of 1% lidocaine injected through the skin into the peritoneum along a predetermined puncture line. MTA antenna puncture was performed under ultrasound guidance. When the tumor was difficult to visualize using B-mode ultrasound, CEUS or fusion imaging with CECT or Gd-EOB-DTPA-enhanced MRI were used as complementary methods for MTA. B-mode ultrasound and CEUS images were obtained using the AplioTM i800 system with an 8 MHz convex transducer PVI-482BX (Canon Medical Systems, Otawara, Japan). Artificial pleural effusion or ascites were prepared using 5% glucose solution if needed. When tumor diameter was less than 1.5 cm, output power was initially set at 60 W and changed to 75 W after 1 min. In tumors with a diameter greater than 1.5 cm, starting output power was set at 60 W, changed to 75 W after 1 min, and then changed to 100 W after another minute.
MTA therapy was considered complete when a transient high echogenic region completely covered the target tumor. If coverage of the transient hyperechoic zone was insufficient for the target tumor, additional punctures and ablation were performed in the same treatment session. Needle track ablation at 75 W was performed to prevent hemorrhages. After the antenna was removed from the liver, the needle site was observed using color Doppler ultrasonography. If bleeding from the needle site increased rapidly, a new percutaneous puncture was used to re-ablate the liver surface around the needle site with an MTA antenna to stop the bleeding.
In this study, we defined the following areas of the liver as those where MTA therapy is difficult to perform: caudate lobe and areas near the primary and secondary branches of the intrahepatic portal vein, inferior vena cava, gallbladder, heart, duodenum, abdominal esophagus, collateral veins around the liver, and spleen. We consider that the lesion near the colon is not difficult to treat because the colon can be easily moved away from the cauterization zone by injecting artificial ascites. We defined tumors in contact with the hepatic capsule and raised on the liver surface as protruding from the liver surface.
2.4. Evaluation of Treatment Efficacy
Treatment efficacy was evaluated with CECT or MRI at 1–2 days after MTA therapy. Complete ablation was defined as no tumor enhancement with a safety margin ≥ 5 mm on CECT or a post-ablation zone that included the entire target tumor with a safety margin ≥ 5 mm on MRI.
2.5. Surveillance for HCC Recurrence after MTA Therapy
Follow-up consisted of regular blood tests and the monitoring of tumor markers such as α-fetoprotein, des-γ-carboxy prothrombin, and lens culinaris agglutinin-reactive α-fetoprotein every 3 months. Multi-phasic CECT, Gd-EOB-DTPA–enhanced MRI, or both were performed every 3–6 months after HCC treatment. When HCC recurrence or disease progression was detected based on radiologic findings, the most appropriate therapy was initiated in each patient based on the Japanese practice guidelines for HCC [
12,
13].
2.6. Evaluation of Outcomes after MTA Therapy
The primary endpoint of this study was local tumor recurrence, which represents treatment failure. Local tumor recurrence was defined as tumor growth that touched the inside or outside of the post-ablation zone.
2.7. Safety Evaluation
To evaluate the safety of MTA therapy, the profile and incidence of complications were investigated. Major complications were defined as events leading to substantial morbidity or disability, a higher level of care, hospital admission, or a substantially extended hospital stay [
14].
2.8. Statistical Analysis
Continuous variables are expressed as medians (interquartile range). The Chi-square test with Fisher’s exact test was used for categorical variables. Actuarial analysis of cumulative local tumor progression was performed using the Kaplan–Meier method; differences were evaluated using the log-rank test. Univariable and multivariable Cox proportional hazards models were used to analyze local tumor progression. In addition, univariable and multivariable regression were used to evaluate the relationship between clinical factors and complications. In this study, the number of events was small and only factors that were significant in the univariable analysis were included as covariates in the multivariable analysis.
Statistical significance was defined as p < 0.05. Statistical analysis was performed using JMP® (SAS Institute, Cary, NC, USA).
4. Discussion
In this study, we clarified the clinical outcomes of next-generation MTA in patients with HCC. Although this study only included patients with HCC who received MTA therapy at a single center in Japan, it included over 400 patients with 600 HCCs. This study showed that the cumulative local tumor recurrence rates at 1 and 3 years were 4.4% and 8.5%, respectively. In this study, there were 86 tumors in areas that were difficult to treat with MTA therapy; approximately 30% of those were located near the primary and secondary branches of the intrahepatic portal vein. However, this study did not identify any significant differences in local tumor recurrence by difficult-to-treat status. In the multivariable analysis, tumor size was significantly associated with local tumor recurrence. In fact, the cumulative recurrence rate was significantly higher in the group with large tumor size. In addition, the ablative margin was inversely associated with local tumor recurrence. In our study, 68% of patients had HBV or HCV infection, but as shown in
Table 4, HCV or HBV infection was not a significant factor associated with the local recurrence rate.
We used contrast-enhanced CT, MRI, and US of the abdomen, as well as measurement of tumor markers, for the diagnosis of recurrence surveillance. While imaging alone is sufficient to determine intrahepatic recurrence, the presence of elevated tumor markers further strengthens the evidence for recurrence. Even if there is no intrahepatic recurrence, elevated tumor markers may provide proof of suspected extrahepatic metastasis, such as to the chest or bones, and thus are considered necessary. In the present study, three patients had extrahepatic recurrence; one with bone metastasis showed elevated DCP, one with lymph node metastasis showed elevated AFP and AFP-L3, and one with lung metastasis tended toward elevated L3 (
Supplementary Table S1). Regarding complications, only tumor size was significantly associated with complications, whereas difficult-to-treat status was not. These results suggest that MTA therapy for HCC located in areas where MTA is difficult is not associated with local tumor progression or post-procedure complications.
In an analysis of 513 patients with 630 HCCs (≤3 cm) who underwent percutaneous RFA (174 patients, 214 HCCs) or MTA (339 patients, 416 HCCs), Tamai et al. reported a significant difference in 3-year local tumor progression rates between the RFA (22%) and MTA (8%) groups (
p < 0.001) [
15]. They found that ablation procedure (MTA; HR, 0.565; 95% CI, 0.437–0.731;
p < 0.001) and tumor diameter (per mm; HR, 1.070; 95% CI, 1.030–1.113;
p = 0.001) were independent factors associated with local tumor progression in a multivariable analysis [
15]. In addition, they found that the total complication rate was significantly lower in the MTA group (8.0%, 26/339) than in the RFA group (14.0%, 25/174) (
p < 0.05), particularly for bile duct injury (3.0% (11/339) versus 9.0% (15/174);
p = 0.010). In this study, we found that the cumulative local tumor recurrence rate at 3 years was 8.5% in our cohort, which included patients with tumors ≥ 3 cm. In this cohort, the total complication rate was 5.4% (33/607). These results suggest that MTA therapy can achieve good outcomes in patients with HCC for whom percutaneous ablation therapy is indicated. The advantage of this study is that our study included more patients and tumors that underwent MTA than the study by Tamai et al.
The Emprint™ Ablation System with Thermosphere™ Technology (Covidien) is an improved version of the Evident™ Microwave Ablation System developed by the same manufacturer. The new device uses a frequency of 2450 MHz and consists of a 100 W generator with a high-efficiency reusable cable and an ablation pump that cools the antenna during ablation. The U.S. Food and Drug Administration approved this system on 28 April 2014, and it was approved for use in Japan on 1 November 2016. This new generation MWA system attempts to address the limitations of conventional systems. It is designed to create a predictable, large, spherical ablation zone that is unaffected by changes in the tissue environment [
16]. Thus, predictable resection results and outcomes are obtained regardless of the target site or tissue type [
17]. Large, accurate, and predictable spherical ablation zones are maintained throughout the procedure by three different types of controls (field control, thermal control, and wavelength control) [
18]. Thermosphere™ technology maintains wavelength control by creating a constant, stable environment around the probe shaft and circulating sterile saline solution along the shaft. This minimizes the change in dielectric constant directly under the probe and maintains a shorter wavelength. It also ensures that the migration pattern of electrons in the probe is maintained, providing reliable field control. However, there have been few studies regarding MTA therapy that have evaluated treatment of HCC in real-world clinical practice. In this study, we clarified the outcomes of this therapy for HCC at a high-volume center in Japan.
The main limitations of this study include its small number of patients and retrospective nature at a single center in Japan. Further prospective studies with more patients from multiple centers are warranted. Another limitation of this study was that the outcomes have not been compared with those of RFA, which had been the mainstay of local ablation therapy for HCC. Further prospective studies that compare clinical outcomes of MTA and RFA in the real-world clinical setting should be performed.
In conclusion, MTA is a safe and effective local ablation therapy for HCC, even when the tumor is located in an area of the liver where local ablation therapy is difficult. Further studies are warranted to confirm these findings in other populations.