RFA vs. SBRT for Small HCC

Hepatocellular carcinoma (HCC) is one of the malignant tumors that seriously threaten the health of our people. Its morbidity and mortality rank third and second among various malignant tumors in China, respectively. Liver transplantation, surgical resection, and local ablation are the main curative treatments for early liver cancer. Our team first reported (Ann Surg, 2006) a prospective randomized controlled clinical trial of radiofrequency ablation (RFA) versus surgical resection for small HCC. The results showed that the long-term efficacy of RFA in the treatment of small HCC is similar to surgical resection. Subsequently, Feng et al (J Hepatol, 2012) and Lv et al reported obtained similar research conclusions. At present, local ablation therapy represented by RFA has been recommended as a first-line treatment for small HCC by many international guidelines, especially for small HCC located in central segments.

With the development of radiotherapy equipment and the precision imaging technology, especially the emergence of stereotactic radiotherapy (SBRT), the status of radiotherapy in the treatment of HCC is increasing. SBRT is defined as the use of external irradiation technology, which is divided into several fractions, and the high dose of radiotherapy is accurately delivered into the tumor. As a result, tumor is subjected to high dose and the normal tissue around the tumor is exposed to relatively low dose. Compared with conventional fractionated radiotherapy (CRT), SBRT possessed fewer segmentation times (1 to 6 F), higher fractional doses (5 to 20 Gy), and steeper gradients at the edge of the target region, so it has stronger biological effect. Meanwhile, SBRT can also protect the normal organs better, especially for the radiotherapy of smaller tumors. Multiple clinical studies and meta-analyses have shown that SBRT is superior to traditional CRT in the treatment of HCC, and the side effects are lower in the acute phase. SBRT has become a mainstream technology for HCC, and has been recommended as a routine local treatment for HCC by NCCN guidelines and NCI radiotherapy guidelines.

This project is to conduct a phase III, prospective, randomized, open, parallel controlled clinical study of RFA versus SBRT for small hepatocellular carcinoma (solitary tumor≤ 5.0 cm; initially treated). The primary end point is 3-year overall survival rate. As for secondary end points, we aim to compare 5-year overall survival rate, 1-, 2-, and 3- year progression-free survival (PFS), local control rate, and rate of complications.Stratified analysis will be performed according to tumor size (≤2.0 cm; 2.1-5.0 cm).

Patients enrolled in this clinical trail received either SBRT or RFA depending on the randomization allocation.

As for SBRT group, the treatment follows the protocol below.Immobilization: Patients are immobilized with vacuum bags or styrofoam in the supine position, with the arms raised above the head. 4DCT scanning: Simple breathing training is conducted before simulation, so that the patient can keep breathing quietly and evenly. A plastic box with reflective marker is placed on the patient's anterior abdominal surface where the respiratory amplitude is relatively large, approximately midway between the xiphoid and the umbilicus. The movement of the marker is recorded by an infrared camera, which is converted into breathing curve by computer software. After the breathing curve becomes stable, the CT data of different respiratory phases is collected by 4DCT in axial cine mode. CT scanning region: From 3-4 cm above the diaphragm to the 4th lumbar vertebra. The intravenous contrast is administered during CT scanning and the slice thickness is 3.0 mm. After 4DCT scanning, images are sorted into 10 phases by the software. Each respiratory cycle is divided into 10 respiratory phases, named as CT0% (end-inhalation), CT10%, CT20% (mid-exhalation), CT30%, CT40%, CT50% (end-exhalation), CT60%, CT70% (mid-inhalation), CT80%, CT90%, respectively. Delineation of the target volumes and organs at risk: Gross tumor volume (GTV) and organs at risk (OARs) are contoured on the 20% CT image (mid-exhalation). Then the GTV is registered to the other respiratory phases of 4DCT scan by a physicist using Atlas-based Auto-segmentation (ABAS, Elekta CMS), and the target volumes are modified and confirmed by a radiation oncologist using the standard window/level settings. GTV is defined as the intrahepatic lesion on images. Internal target volume (ITV) is defined as the combined volume of GTVs on 10 respiratory phases. Planning target volume (PTV) is generated by adding a 6-mm margin to the ITV. OARs include liver, kidney, stomach, small intestine, and spinal cord. Normal liver volume is defined as the entire liver minus GTV. Treatment planning: The plan of volumetric modulated arc therapy (VMAT) is designed on the 20% CT image using Monaco TPS (CMS, Elekta) with an optimization algorithm based on a combination of radiobiological and physical cost functions. Monte Carlo algorithm (MC) is performed in the optimization process and a single arc is conducted using FFF mode. Dosimetric evaluation: For PTV, V95% ≥95%, Dmax < 110%, Dmin >90%. For OARs, mean dose to normal liver (MDTNL) < 13 Gy, V15Gy of liver < 35%; Dmean of kidneys <6 Gy, D0.5cc of esophagus < 21 Gy; D0.5cc of stomach < 21 Gy; D0.5cc of small intestine < 21Gy; D0.5cc of colon < 24Gy; D0.5cc of heart < 30 Gy; D0.5cc of ribs < 39 Gy; Dmax of spinal cord < 18 Gy. The planning is evaluated according to the dose volume histogram (DVH) and the dose distribution of each layer. Elekta linear accelerator (Versa HDTM, MLCi2 80 leaves, 0.5 cm MLC) with 6-MV photons are used for treatment. The isocenter of the irradiation field is defined as the geometric center of the PTV, and the prescribed dose is defined as the average dose of PTV. The prescribed dose is maximized while meeting the dosimetric goals. The prescribed dose is 36-54 Gy in 3 fractions administered within 1 week. Plan Validation and Implementation: Dosimetric verification of plan is performed on a Versa HDTM linear accelerator using the three-dimensional semiconductor detection matrix Delta4 (ScandiDos, Uppsala, Sweden) before treatment for each patient. The gamma evaluation criteria were ±3% of 3 Gy and 3 mm of the distance criterion. After the patient's positioning, a 360° scanning is performed using 4D-CBCT prior to each fraction. The automatic bone registration and manual fine-tuning method are used to register the 20% CT image of 4D-CBCT with the planning CT. Then the positioning error data of 6-degree-of-freedom is obtained for online calibration. If the positioning error after calibration is less than 3 mm, the treatment will be delivered.

As for RFA group, contrast-enhanced ultrasonography (CEUS) was carried out for all patients before RFA. RFA was performed with the use of conscious analgesic sedation (intravenous administration of 0.1 mg of fentanyl, 5 mg of droperidol and 0.1 mg of tramadol hydrochloride) and local anesthesia (5 mL of 1% lidocaine) by an anesthesiologist. All procedures were performed percutaneously by one of three ablation experts with 6 to 15 years of experience under real-time ultrasound guidance. The ZW-II RFA system (Dalong South Technical Co., Ltd., Shenzhen, China) was used for ablation. After the single-needle electrode with an exposed tip was deployed to the residual tumor bottom under ultrasound guidance while avoiding critical structures during temporary suspension of respiration. The radiofrequency generator was activated and initiated with 30 W of power. The power was increased by 10 W per minute to 60 W. Tissue impedance was continuously monitored during the ablation, and generator output was adjusted to generator maximum power or until 8 minutes had elapsed. Then, the lesion was rescanned to determine whether the ablative region had covered the whole tumor or a second ablation was required to achieve a satisfactory ablative area. At the end of the procedure, the needle tract was ablated to prevent bleeding and needle track seeding.

This study is expected to complete enrollment in 3 years and to follow up for 3 years.The primary analysis is performed in the intention-to-treat population. Kaplan-Meier curves will be used to describe the patient's recurrence-free survival, and the corresponding statistical data are calculated, such as median progression-free survival (PFS) and bilateral 95% CI. The secondary analysis used a hypothesis test and a two-sided 95% confidence interval(CI) for the first time of the primary recurrence.Kaplan-Meier curves will also be used to describe the patient's disease progression, and calculated the corresponding statistical data, such as the median overall survival(OS) and bilateral 95% CI.Safety assessments will be also performed by comparing adverse events in the two groups of patients.