Abstract
Purpose
To retrospectively evaluate the utility of fusion images of pre- and post-ablation hepatobiliary phase (HBP) series to assess the ablation margins after radiofrequency ablation (RFA) of hepatocellular carcinomas (HCCs). Additionally, to identify factors indicative of an adequate ablation margin and predictors of local tumor progression (LTP).
Methods
Fifty-nine HCCs in 29 patients were treated by RFA and followed-up for > 1 year (mean 37.9 months). Fusion images of pre- and post-ablation HBP series were created using a non-rigid registration and manual correlation. The ablation margin appearance was classified as ablation margin + (ablation margin completely surrounding the tumor), ablation margin-zero (a partially discontinuous ablation margin without protrusion of HCC), ablation margin—(a partially discontinuous ablation margin with protrusion of HCC), and indeterminate (index tumor was not visible). The minimal ablation margin was measured, and clinical factors were examined to identify other risk factors for LTP.
Results
LTP was observed at follow-up in 12 tumors. The mean minimal ablation margin was 3.6 mm. Multivariate analysis revealed that the ablation margin status was the only significant factor (p = 0.028). The cumulative LTP rates (3.3%, 3.3%, and 3.3% at 1, 2, and 3 years, respectively) in 30 ablation margin + nodules were significantly lower (p = 0.006) than those (20.0%, 28.0%, and 32.2% at 1, 2, and 3 years, respectively) in 25 ablation margin-zero nodules.
Conclusions
Fusion images enable an early assessment of the ablation efficacy in the majority of HCCs. The ablation margin status is a significant factor for LTP.
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Percutaneous radiofrequency (RF) ablation is usually indicated as a curative therapy for early-stage hepatocellular carcinomas (HCCs) [1]. It is important to create the ablation margin surrounding the index tumor of > 3–5 mm [2, 3] because it is an independent factor for progression-free survival and overall survival [1,2,3,4].
To evaluate the ablation margin after the procedure, contrast-enhanced computed tomography (CT) has been used, comparing pre-and post-ablation CT images in a side-by-side manner [5]; however, this technique may be inaccurate due to translocation, rotation, or deformation of the liver depending on the patient’s position and respiratory motion. Moreover, the ablation-induced hyperemic rim surrounding the ablation zone may mimic a residual tumor [6]. To overcome these limitations, fusion imaging of pre- and post-ablation CT images have been developed for HCCs [7,8,9,10] and liver metastases [11].
Meanwhile, several researchers have investigated post-ablation magnetic resonance imaging (MRI) in the acute phase after the procedure because it can distinguish the index tumor from the ablation margin on the same image. The feasibility of T2*-weighted imaging after administration of superparamagnetic iron oxide [12] and unenhanced T1-weighted imaging was initially reported [13,14,15,16]. Subsequently, the utility of gadoxetate disodium (Gd-EOB-DTPA)—enhanced MRI (EOB-MRI) was identified [17,18,19] because post-ablation portal venous phase and hepatobiliary phase (HBP) images revealed conspicuous differentiation of the index tumor, ablation margin, and surrounding hepatic parenchyma with hypo- or hyper-intensity, intermediate-intensity, and iso-hyperintensity [17,18,19]. We believed that post-ablation HBP sequences could discriminate index tumors from the ablation margin most conspicuously with the least motion artifact among multiphasic images [19]. However, Koda et al. and Takeyama et al. recently revealed that many tumors became invisible 7 and 24 h after ablation, respectively [18, 19]. They concluded that approximately 25%–49% of index tumors were not identified on HBP images after the procedure. It was expected that fusion images of the pre- and post-ablation HBP series could solve the problem because MR–MR fusion images have enabled precise treatment evaluation [20,21,22], and post-ablation MRI examinations have been routinely acquired at our institution no more than 3 days after the procedure in patients with HCCs [17, 21].
The aim of this study was to clarify the clinical usefulness of fusion images of pre- and post-ablation HBP series, compared with post-ablation HBP sequences, using ablation margin grading. Additionally, factors to indicate an adequate ablation margin and factors to predict local tumor progression (LTP) were evaluated on fusion imaging.
Materials and methods
Patients
Our institutional review board approved this retrospective study and the informed consent requirement was waived by all patients. A computerized database of radiology reports was searched to identify all patients who met the following criteria from July 2011 to July 2016: “RF ablation for HCC”, “ EOB-MRI before and after ablation”, and “patients who were followed-up for > 1 year [23] ”. One hundred one HCCs in 63 patients were enrolled; however, the following were excluded: 23 HCCs in 19 patients who underwent transcatheter arterial chemoembolization (TACE) as neoadjuvant therapy prior to RF ablation and 17 HCCs in 13 patients for repeated ablations as LTP adjacent to a prior ablation zone. This resulted in data on 61 HCCs in 31 patients who underwent pre-ablation EOB-MRI and post-ablation unenhanced MRI being analyzed in this study (Fig. 1). The average largest diameter of tumors was measured during HBP on pre-ablation EOB-MRI in the arterial phase and portal venous phases. Tumor location was described according to the Couinaud segmental anatomic classification, and was divided into the following three patterns: subcapsular and subdiaphragmatic; within 3 mm of the first to third branches of the portal vein, hepatic vein, or inferior vena cava; and others. The number of lesions (single or multiple) and past therapies (surgical resection, RF ablation, or TACE in other segments), as well as underlying chronic liver disease due to alcohol, hepatitis B, hepatitis C, autoimmune hepatitis, primary biliary cirrhosis, and non-alcoholic steatohepatitis, was recorded. Clinical stage was defined according to the Child–Pugh classification, and pre-treatment stages were categorized in Child–Pugh classes A and B. The diagnosis of HCC on EOB-MRI was made for nodules showing enhancement during the arterial phase with washout during the portal venous phase [23], or nodules enhancing in the arterial phase with hypointensity during the HBP when it was difficult to determine washout [24].
The inclusion criteria for RF ablation were as follows: (a) target lesions visible on ultrasound and accessible via a percutaneous route; (b) tumors < 3 cm in patients who were expected to complete treatment without surgery; (c) no portal venous thrombosis or extrahepatic metastasis; (d) prothrombin time international normalized ratio [INR] < 1.7; (e) serum total bilirubin < 3.0/μL; and (f) platelet count > 50 × 103/mL.
RF ablation procedure
All RF ablation procedures were performed under local anesthesia using ultrasound guidance by experienced hepatologists. A 17-gauge cooled-tip electrode that was 15 or 20 cm long with a 2 or 3 cm-long exposed metallic tip was used with a 200 Watt generator (Cool-Tip Radiofrequency System, Covidien, Boulder, CO). The optimal electrodes were selected according to the tumor location and size. The electrode was repositioned during the procedure to create an effective ablation margin surrounding the tumor. In cases with multifocal tumors, several lesions were ablated during the same session.
Ablation was started with an initial power output of 20 or 40 W for the 2 or 3 cm active tip, respectively, and increased at a rate of 10 W/min until roll-off. When the tumor was located in the hepatic dome, an artificial pleural effusion technique was used to improve the tumor visibility.
MRI protocol
Pre-ablation EOB-MRI was performed no more than 3 months (mean 50.3 ± 24.6 days, ranging from 15 to 90 days) before ablation, and post-ablation HBP sequences were acquired no more than 3 days (mean 1.3 days) after ablation. Pre- and post-RFA MRI examinations were performed by either a 1.5-T system (Avanto or Essenza, Siemens Healthcare, Erlangen, Germany) or a 3-T system (Trio, Siemens Healthcare). Pre- and post-ablation MRI included T2-weighted, diffusion-weighted, unenhanced T1-weighted, and dynamic contrast-enhanced images with the injection of Gd-EOB-DTPA (Primovist, Bayer Healthcare, Osaka, Japan) of 0.025 mmol/kg of body weight followed by a 20 mL saline flush at a rate of 2 mL/s using a power injector. Arterial phase, portal venous phase, late phase, and HBP images were obtained at 20, 60, 120, and 20 min. Contrast-enhanced T1WI and HBP sequences were obtained with volumetric interpolated breath-hold examination (VIBE) sequences with fat saturation in the axial plane with the following parameters: TR range 2.87–4.97 ms; TE range 1.13–1.83 ms; and flip angle, 9°–15°.
The range of section thicknesses was 3.5–5.0 mm and the matrix range was from 262–420 to 379–420 pixels. The averaged section thickness was 4.0 ± 0.4 mm during pre-ablation HBP and was 4.1 ± 0.3 mm on post-ablation T1WI. The average gap between pre- and post-ablation MRI was 0.2 ± 0.3 mm, including gaps of 0 mm in 40 lesions, 0.5 mm in 17, and 1 mm in 2.
Treatment and follow-up
Patients with RF ablation for HCCs underwent unenhanced MRI or EOB-MRI examinations no more than 3 days after the procedure because the ablation margin was interpreted immediately. If hepatologists diagnosed that a tumor was not covered sufficiently by the ablation zone on post-ablation MRI, RF ablation was repeated the next day after MRI to encompass the tumor completely; however, no additional ablation was performed in this study. In all patients, after treatment efficacy was confirmed by EOB-MRI, EOB-MRI was repeated every 2–4 months for 2 years, and multiphasic contrast-enhanced CT or EOB-MRI was repeated every 6 months thereafter.
A residual tumor is defined as a tumor that is not treated during the ablation session and remains at the ablation margin. LTP was defined as a newly appearing hypervascular nodule during the arterial phase that washed out during the portal phase at the edge of an ablation zone in an area which previously showed the absence of viable tissue on at least one imaging study [25, 26]. When residual tumors or LTP were detected during the follow-up period, RF ablation or TACE was used for retreatment.
Fusion imaging
To create fused images, we used an image analyzing system (Volume Analyzer Synapse VINCENT, version 5.1, Fujifilm Medical Systems, Tokyo, Japan), which was installed in a picture archiving and communication system (PACS) (Synapse, Fujifilm Medical Systems) workstation. Our aim was to accurately fuse the Couinaud sub-segmental anatomic location around the target tumor [20, 21], even if certain misregistrations occurred in other parts of the liver [3]. Image registration was repeated for lesions in other segments and lobes [3, 20].
The first step was to use the Fusion” application, which was adapted as a rigid registration method, to superimpose pre-ablation HBP images onto post-ablation HBP sequences. The registration program was started up in the axial, coronal, sagittal and 3D views. The second step was to color target nodules and the ablation zone. When the “fire” color was selected among seven colors for upper images and the “lung nodule” color was selected from 21 colors for lower images, the index tumor and the ablation margin appeared as a reddish nodule and a yellow-green area, respectively (Fig. 2). The third step was to align the pre- and post-RFA images automatically and manually. First, automatic registration was performed referring to the signal intensity of the hepatic parenchyma. Second, manual registration was performed at the sub-segmental anatomical location around the target tumor by selecting the portal vein or hepatic venous branch around the tumor. The bifurcation point of each vessel was assigned as a landmark [7, 8]. Landmarks close to the lesion were preferably used as to fuse images accurately. Ten points in the axial view, 5 points in the coronal view, and 5 points in the sagittal view were selected because 20 points in total were available in all 3 cross-sectional views in this registration program. The fourth step was to tweak the registration image using slight shift and rotation in all views. The registration error was judged in this step. After fusion imaging was generated, it was sent to the PACS server. The mean time to create one registration image was 10–15 min.
Qualitative analysis
Two radiologists with 4 and 23 years of experience in abdominal imaging independently interpreted the post-ablation HBP sequences and fusion images using a workstation. In cases of discrepancies between the two readers, a final decision was made via consensus through reassessment with a third radiologist who had 11 years of experience in abdominal imaging. They knew the diagnosis of HCC and information about tumor location and size but were unaware of the final results with regard to whether LTP occurred during the follow-up period. They were free to use processing tools such as windowing, gradation adjustment, or magnification, and to scroll the MRI examinations. First the registration error of the branches of the portal and hepatic veins in the vicinity of the target was scored using the following 3 grading levels [8]: good, no (0 mm) vascular misregistration; fair, minimal (< 2 mm) in less than 4 vessels; and poor, minimal (< 2 mm) in more than five vessels, or severe (> 3 mm) in more than 1 vessel.
The second step was to grade the ablation margin using both post-ablation HBP sequences and fusion images. First, pre-ablation T1-weighted images and arterial phase, late phase and HBP images were observed, and second, post-ablation HBP sequences and fusion images were evaluated (Fig. 3). The ablation margin grading was categorized using 4 grading levels, including visible [ablation margin (+), ablation margin zero, and ablation margin (−)] and indeterminate on both post-ablation HBP sequence and fusion imaging (Fig. 4). An indeterminate ablation margin was assigned when the central lesion could not be easily distinguished from the ablation zone [15]. The ablation margin plus [ablation margin (+)] score meant the ablation zone completely surrounded the tumor. The ablation margin zero score was for a partially discontinuous ablation margin without protrusion of the tumor beyond the border of the ablative zone. The ablation margin minus [ablation margin (−)] was a partially discontinuous ablation margin with protrusion of the tumor [12, 15]. On post-ablation HBP sequences, a visible ablation margin was defined as a central hypo- or hyperintense tumor circumscribed by a hyperintense broad middle zone with a hypointense marginal band. On fusion imaging, a visible ablation margin was defined as a central red tumor circumscribed by a broad green middle zone (Fig. 5).
Quantitative analysis
The minimum ablation margin was defined as the shortest distance between the boundaries of the tumor and the periphery of the ablation margin among axial, coronal, and sagittal images on fusion imaging. In the ablation margin (+) nodules, the minimum ablation margin was measured (Figs. 2, 5). In the ablation margin zero nodules, the ablation margin was not measured (Figs. 6, 7).
Statistical analysis
All data are shown as mean values ± standard deviations. Statistical analysis was performed using SPSS version 20 (IBM SPSS, Chicago, IL).
Inter-observer agreement regarding registration errors in 61 HCCs on fusion imaging was investigated using the Cohen k coefficient. Inter-observer agreement on the ablation margin grading on post-ablation HBP sequence and fusion imaging in 61 HCCs was analyzed using the Cohen k coefficient. The k values were interpreted as poor for k less than 0.20; fair, k of 0.21–0.40; moderate, k of 0.40–0.60; good, k of 0.61–0.80; and very good, k of 0.81–1.00. The numbers and percentages of patients evaluated as the ablation margin grading [ablation margin (+), ablation margin zero, ablation margin (−), and indeterminate] on post-ablation HBP sequence and fusion imaging were compared using the χ2 test.
To compare the baseline characteristics between ablation margin (+) and ablation margin zero HCCs on fusion imaging, categorical variables were analyzed using the χ2 test as the univariate analysis. The cumulative LTP rate was calculated using the Kaplan–Meier method and the log-rank test was used for statistical analysis (Fig. 8). A logistic regression model was used for multivariate analysis of independent factors for the ablation margin (+) on fusion imaging. The Cox proportional hazard model was used for multivariate analysis of independent factors for LTP after RF ablation. Probability values < 0.05 were considered significant.
Results
Table 1 summarizes the baseline characteristics in 29 patients with 59 HCCs.
The size and shape of the central lesions on fusion imaging and post-ablation HBP sequences were similar or slightly collapsed compared with the tumors on pre-ablation HBP images.
Assessment of ablation margin grading on fusion imaging
The assessment of registration errors for 61 HCCs on fusion imaging showed good (n = 53), fair (n = 6), and poor (n = 2) results. The inter-observer agreement level between two radiologists for registration errors in 61 HCCs on fusion imaging was very good (k = 0.686).
Two HCCs with poor results were excluded due to liver deformation and massive ascites (Fig. 1). An artificial pleural effusion was used in 15 (25.4%) of 59 HCCs; however, no lesions showed registration errors.
The assessment of the ablation margin for 59 nodules revealed 58 visible ablation margin and one indeterminate ablation margin. One indeterminate ablation margin nodule, which showed isointensity on a pre-ablation HBP image, had a central light green nodule that could not be distinguished from the green ablation zone.
During the follow-up period, one residual tumor and 11 LTP occurred in 12 of 59 (20.3%), including one of 30 (3.2%) ablation margin (+) nodules, 8 of 25 (32%) ablation margin zero nodules, and 3 of 3 (100%) ablation margin (−) nodules. The remaining 47 lesions (79.7%) had no recurrence. No residual tumor or LTP was observed in the one indeterminate ablation margin nodule. The mean time to one residual tumor and 11 LTP was 10.4 ± 6.6 months, ranging from 2 to 27 months.
No case had seeding metastases at the track lines of ablation needles in this study.
Comparison of the assessment of the ablation margin grading on fusion imaging with post-ablation HBP sequences
The ablation margin grading of 59 HCCs on post-ablation HBP sequences revealed 5 ablation margin (+), 8 ablation margin (−), one ablation margin (−), and 45 indeterminate ablation margin, and that on fusion images showed 30 ablation margin (+), 25 ablation margin zero, 3 ablation margin (−) and one indeterminate ablation margin.
The inter-observer agreement level between two radiologists for the ablation margin grading on HBP sequences was very good (k = 0.734), and that on fusion imaging was also very good (k = 0.693).
A total of 14 (23.7%) out of 59 nodules were identified on post-ablation HBP sequences (Fig. 6), and 58 of 59 (98.3%) nodules were visible on fusion images. The χ2 test (Table 2) demonstrated a significant increase (p = 0.024) from HBP sequences (5, 8, 1, and 45) to fusion imaging [30, 25, 3, and 1 in ablation margin (+), ablation margin zero, ablation margin (−), and indeterminate ablation margin].
The minimum ablation margin between the index tumor and the periphery of the ablation margin was 3.6 ± 0.9 mm, ranging from 1.4 to 5.6 mm, in 30 ablation margin (+) nodules.
Comparison between ablation margin (+) and ablation margin zero nodules on fusion imaging
Three ablation margin (−) and one indeterminate HCCs were excluded; therefore, baseline characteristics of 30 ablation margin (+) and 25 ablation margin zero HCCs were compared in Table 3. To evaluate the significant factors contributing to the ablation margin (+) on fusion imaging, age, gender, etiology, Child–Pugh score, past therapy, tumor size, multiplicity, and location were included in a multivariate logistic regression model. No independent factor was identified for the ablation margin (+) on fusion imaging.
During the follow-up period (median 37.9 months, range 12–67 months), the cumulative rates of LTP were significantly lower (p = 0.006) in the 30 ablation margin (+) nodules (3.3% at 1 years, 3.3% at 2 years, and 3.3% at 3 years) (20.0%, 28.0%, and 32.2% at 1, 2, and 3 years, respectively) in 25 ablation margin zero nodules.
Table 4 lists the clinical factors for LTP. Univariate analysis showed that the ablation margin grade was a significant risk factor for LTP using the log-rank test. Only ablation margin was identified as an independent factor for local tumors in a multivariate Cox proportional hazards model (Table 4).
Discussion
Post-treatment imaging is crucial to evaluate the therapy response by assessing residual and recurrent disease, revising the prognosis, and guiding further therapy [26]. The imaging sign of treatment success is a lack of vascular enhancement of the index tumor on CT or MRI examinations [5, 6]. Dynamic phases from the arterial phase to the portal venous phase plus T2-weighted images are crucial to evaluate residual tumors and LTP after ablation [27]. However, in the early post-ablation period, the peripheral rim enhancement surrounding the ablation zone may hide the local recurrence of HCCs [6, 8]. In this situation, careful comparison of pre- and post-ablation imaging with subsequent follow-up is needed to distinguish the anticipated periablation change and the tumor. Post-ablation HBP sequences do not show peripheral hyperemia, theoretically enabling us to distinguish the index tumor from the ablation margin; however, many index tumors are no longer visible after the procedure. In our study, fusion imaging was significantly superior to HBP sequences about in terms of tumor visibility within the ablation zone.
To date, various risk factors related to LTP after RF ablation have been identified. Among them are tumor diameter, the ablation margin, the minimum ablation margin, and location relative to abutting vessels and liver surface. The ablation zone is considered to be a coagulation necrosis with circumferential sinusoidal congestion and fibrosis surrounding the index tumor. The ablation margin has been recognized as the most important risk factor for LTP because it can be measured quantitatively on fusion imaging of pre- and post-ablation CT and MR. The mean ablation margin was 3.6 mm in this study; these data were in agreement within previous studies indicating a safety margin of 3–5 mm to be crucial [2, 3, 9, 10, 28]. The LTP rate of this study (3.3% at 2 and 3 years) in the ablation margin (+) nodules was similar to that in Nakazawa’s research (3.5% at 3 years for HCC with an ablation margin of > 5 mm) [2] and Kudo’s report (2.6% at 2 years for HCC with an ablation margin of > 5 mm) [29]. This result suggests that the accuracy of the ablation margin grading on fusion imaging may correspond with that on enhanced CT images.
To create fusion images, a rigid registration technique was used in much the same way as the previous reports on CT–CT fusion [7, 8] and MR–MR fusion images [20]. In this registration software, segmentation of the tumor by manually tracing its contour was not performed. Only two images were overlapped when the coloring of the upper and lower images was selected to distinguish the target tumor from the ablation zone. Consequently, tumors could be clearly discriminated from the ablation zone as their size and shape were similar compared with the tumor on pre-ablation HBP images.
Despite different MR scanners and different acquisition parameters including TR, TE, FOV, and section thickness on pre- and post-ablation series, no significant registration errors were identified visually with good inter-observer agreement.
On post-ablation HBP sequences, tumor invisibility within the ablation zone could have resulted from the increased signal and shrinkage when hemorrhage and coagulation necrosis completely replaced the ablation zone [15]. We scored 76.3% of nodules as indeterminate, higher than previous reports [17,18,19]. We speculated that several factors may affect tumor visibility such as tumor size and signal, ablation procedure time, background liver function, and section thickness. In contrast, 98.3% of visible target lesions within the ablation zone on fusion imaging was superior to that of previous MRI studies [18, 20].
From our data, we propose a workflow to assess the ablation margin grading on fusion imaging. An ablation margin (+) has been almost completely treated because 29 of 30 (96.7%) ablation margin (+) nodules showed no residual tumor or LTP, except for one nodule abutting the third branch of the intrahepatic portal vein (Fig. 2). We found that the multivariate analysis demonstrated that ablation margin status was an independent predictor for LTP after RF ablation, as previous studies mentioned [30]. Thus, the assessment of the ablation margin on fusion images of the pre- and post-ablation HBP series can predict LTP after RF ablation. Consequently, the early and accurate detection may allow the prompt re-ablation and can improve the efficacy of the procedure [11]. It is recommended that nodules assessed as ablation margin (−) should be re-treated with the additional ablation to obtain an adequate ablation margin, HCCs evaluated as ablation zero should be carefully observed during the follow-up period and indeterminate ablation margin lesions should be evaluated again in a side-by-side manner.
There are several limitations in the present study. First, it was retrospective. Therefore, further studies are required in a prospective trial. Second, the pathology was not confirmed. Considering pathology-radiology correlation on the post-ablation unenhanced T1-weight images and post-ablation hepatobiliary phase sequences, a red tumor covered by a broad green middle zone was pathologically assumed to be the index tumor and coagulation necrosis with a peripheral inflammatory reaction [18, 19, 31]. In this study, the coagulation necrosis and peripheral inflammatory reaction were not divided and we only dealt with the ablation zone. Moreover, the histological grade of HCCs was not identified. Because poorly-differentiated HCCs could have a lower tumor-liver contrast ratio than well-differentiated HCCs [32, 33], the tumor visibility may have been affected by fusion imaging. Third, the spatial resolution of 3D-VIBE images was lower than previous reports [17,18,19,20,21]. Therefore, thin section thickness must employ spatial resolution on sagittal and coronal images.
In conclusion, fusion imaging of pre- and post-ablation HBP series was superior to post-ablation HBP sequences and offers the possibility of predicting the LTP using ablation margin grading. When ablation margin status is classified into ablation margin zero or ablation margin (−) on fusion imaging, additional sessions of RF ablation may be considered during the follow-up period.
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Takeyama, N., Mizobuchi, N., Sakaki, M. et al. Evaluation of hepatocellular carcinoma ablative margins using fused pre- and post-ablation hepatobiliary phase images. Abdom Radiol 44, 923–935 (2019). https://doi.org/10.1007/s00261-018-1800-0
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DOI: https://doi.org/10.1007/s00261-018-1800-0