Chemoembolization Plus Microwave Ablation vs Chemoembolization Alone in Unresectable Hepatocellular Carcinoma Beyond the Milan Criteria: A Propensity Scoring Matching Study.

PURPOSE: Transarterial chemoembolization (TACE) is recommended in patients with unresectable HCC beyond the Milan criteria (MC). However, the long-term efficacy of TACE remains unsatisfactory. Percutaneous microwave ablation (MWA) is a curative therapy for early-stage HCC that provides better local tumor control than TACE; however, MWA is limited for large or multifocal lesions. We aimed to compare treatment efficacy and downstaging rate following combined TACE-MWA and TACE alone in patients with unresectable HCC beyond the MC. PATIENTS AND METHODS: Patients with unresectable HCC beyond the MC who underwent either TACE-MWA (n=91) or TACE alone (n=140) at four medical institutions were included. Potential influencing factors on overall survival (OS) and progression-free survival (PFS) were included in the Cox regression analysis. Propensity-score matching of patients treated with TACE-MWA and TACE alone was performed. Differences in OS and PFS were compared with the Log rank test. Patients who met the University of California, San Francisco criteria were eligible for assessment of the probability of downstaging within the MC. Downstaging rate was compared between the two groups.
RESULTS: In multivariate analysis, treatment with TACE alone was an independent predictor of poor PFS (P=0.011) and OS (P<0.001). Both PFS (P=0.043) and OS (P=0.002) were significantly higher in patients treated with TACE-MWA than those treated with TACE alone. The downstaging rate was higher in patients treated with TACE-MWA than those treated with TACE alone (P=0.039).
CONCLUSION: Compared with TACE alone, TACE-MWA may offer a survival benefit in terms of OS and PFS in HCC patients beyond the MC. Additionally, TACE-MWA may provide higher probability of downstaging within the MC than TACE alone, thereby increasing the possibility of liver transplantation.

Introduction

Hepatocellular carcinoma (HCC) is a major problem worldwide, with high morbidity and mortality.1,2 According to the Barcelona Clinic Liver Cancer (BCLC) system, ablation is recommended as the first-line treatment for HCC patients with BCLC-0 or as an alternative treatment option for HCC patients with BCLC-A. In contrast, transarterial chemoembolization (TACE) is recommended as the primary treatment for HCC patients with BCLC-B.1,3 Aside from ablation and TACE, transarterial radioembolization (TARE) is a liver-directed therapy that is widely used in clinical practice.4–6 Although TARE is not recommended in the latest version of the BCLC system, it may provide survival benefit in select patients.7,8 Since 1996, the Milan criteria (MC) has been widely used to select patients who are candidates for liver transplantation. In contrast, transarterial chemoembolization (TACE) is recommended for patients with unresectable HCC beyond MC.9–11 However, the long-term efficacy of TACE is still not satisfactory, mainly due to incomplete tumor necrosis and liver function damage induced by the procedure.12,13 Percutaneous microwave ablation (MWA) has long been accepted as a curative therapy for early-stage HCC and can provide better local tumor control than TACE.14,15 However, the use of ablation in large or multifocal lesions is limited.16,17 The combination of TACE and thermal ablation may increase the treatment efficacy for HCC lesions in selected patients.16–18 However, the treatment efficacy of TACE plus MWA compared with TACE alone for patients with unresectable HCC beyond MC has not yet been elucidated. In addition, the probability of downstaging within the MC following the two treatment modalities has not been compared. Therefore, the purpose of this study was to compare the therapeutic outcomes of TACE in combination with MWA with that of TACE alone for patients with unresectable HCC beyond MC and compare the downstaging rate between the two treatment modalities.

Materials and Methods

Patients

This retrospective study was approved by the institutional review board of the Second Xiangya Hospital and was performed in accordance with the Declaration of Helsinki. Written informed consent for publication from all patients was waived by the institutional review boards due to the retrospective nature of the present study and all patients’ data for analysis were anonymized.

A total of 1028 patients with unresectable HCC who underwent TACE plus MWA or TACE alone between September 2014 and September 2020 at four institutions were included in this retrospective study. The indication for TACE-MWA or TACE alone was assessed by a tumor board consisting of surgeons, hepatologists, oncologists, radiologists, and interventional radiologists. Patients meeting the following criteria were initially performed with TACE: (a) preserved liver function (Child-Pugh A or B); (b) Eastern Cooperative Oncology Group performance status 0; and (c) at least one target lesion for measurement. Patients meeting the following criteria were further performed with MWA after initial TACE: (a) the presence of a single HCC tumor ≤8 cm in diameter, or multi-nodular HCC tumors (n≤5) small than 5 cm in diameter before TACE and (b) the presence of viable residual tumor on follow-up imaging. The exclusion criteria were: (a) classification within the MC (n=304); (b) macrovascular invasion (n=169); (c) loss to follow-up (n=128); (d) distant metastasis (n=112); (e) infiltrative HCC (n=84). Ultimately, 231 patients were included in the present study and divided into a TACE-MWA (n=91) group and a TACE alone (n=140) group. Among the 231 patients, 71 patients were from institution A, 74 patients were from institution B, 45 patients were from institution C, and 41 patients were from institution D. The flowchart of the study population is shown in Figure 1.

Figure 1

Flowchart of the study population.

TACE Procedure

TACE was performed by eight board-certified senior interventional radiologists with an average experience of 13 years in liver interventions. The femoral artery was routinely catheterized. Selective hepatic arteriography was performed to demonstrate the blood supply of the tumor, following which a 2.2-F coaxial microcatheter (Carnelian; Tokai Medical Products, Aichi, Japan) was placed in the tumor feeders. Chemoembolization was performed in a superselective manner by slowly injecting the oil-epirubicin emulsion through the microcatheter and subsequently administering the Gelfoam slurry to embolize the proximal tumor feeders. The oil-epirubicin emulsion was created by mixing up to 15 mL of iodized oil (Lipiodol; Guerbet Asia Pacific Ltd., Hong Kong, China) with distilled water containing 50–120 mg of dissolved epirubicin (3:1 ratio).

MWA Procedure

Within a month of TACE, dynamic contrast-enhanced CT or MR imaging was applied to identify the target lesions to be treated with MWA. MWA was performed using a single water-cooled microwave system (KY-2000; Kangyou Medical Instrument Co., Ltd., Changzhou, China) by four board-certified senior interventional radiologists with an average experience of 11 years in liver interventions. The 14-G antenna was percutaneously inserted into the tumor under CT guidance. A single antenna was used for tumors less than 3.0 cm in diameter, while for tumors larger than 3.0 cm, an overlapping ablation technique was used as pre-procedurally planned. For multifocal lesions, a maximum of three lesions were treated in a single session, and the remaining lesions were treated approximately one week after the first MWA session. The microwave power was set at 60–80 W, and the procedure lasted for 5–25 minutes. Intraprocedural contrast-enhanced CT imaging was performed to determine the ablative safety margin of the tumor. The technical success of ablation was defined as complete ablation of the tumor with a safety margin of at least 0.5 cm in CT images.

Follow-Up

Follow-up imaging was performed within 3 months after the first treatment and then at approximately 2-month intervals. The primary outcome was progression-free survival (PFS), which was defined as the time interval between the first TACE session and death, tumor progression, or last follow-up (April 30, 2021). The secondary outcome was overall survival (OS), which was defined as the time interval between the first TACE session and death or last follow-up (April 30, 2021). Tumor progression was defined as progression of the target lesion or nontarget lesion, or occurrence of a new lesion according to the modified Response Evaluation Criteria in Solid Tumors (mRECIST). If tumor progression occurred, the choice of treatment modality for progressive HCC was dependent on the site of the tumor, liver function, and the general condition of the patient.

Data Collection

The baseline characteristics of the patients were collected, including clinical data, laboratory data, and radiological data. The clinical data included sex (male/female), age, etiology of cirrhosis (none/HBV/HCV/alcohol/cryptogenic), and Child-Pugh class (A/B). The laboratory data included platelet count and albumin, total bilirubin, and alpha-fetoprotein levels (AFP; ≤400/>400 ng/mL). The radiological data included tumor distribution (unilobar/bilobar), size of the largest tumor, and the number of tumors (single/multiple).

Downstaging Criteria

Patients within the University of California, San Francisco (UCSF) criteria were considered to be suitable for assessment of downstaging within the MC.19 Patients who met any of the following were defined as fulfilling the UCSF criteria: (a) one lesion of 5–8 cm; (b) two to three lesions with at least one lesion of 3–5 cm and a total tumor diameter up to 8 cm; or (c) four to five lesions with none greater than 3 cm and a total tumor diameter of up to 8 cm. Successful downstaging was defined as a reduction in the number and size of viable tumors to meet the MC, with a minimum follow-up of 3 months.

Statistical Analysis

Numerical data are expressed as the mean with SD or median with interquartile range (IQR). Categorical data are described using numbers and percentages. To compare the differences in baseline demographic, clinical, and biochemical characteristics between the TACE-MWA group and TACE alone group, the Student’s t-test or the Mann–Whitney U-test was used for continuous variables, and the χ2 test was used for categorical variables. The OS and PFS rates were analyzed with the Kaplan-Meier method, and the difference in OS or PFS was compared with the Log rank test. In patients with multiple tumors, the characteristics of the largest tumor were recorded for analysis. Eleven factors that may potentially influence OS and PFS were analyzed with a Cox proportional hazards regression model, and these were treatment modality (TACE-MWA/TACE alone), sex (male/female), age (≤55/>55 years), AFP level (≤400/>400 ng/mL), platelet count (≤50/>50 ×109/L), number of tumors (single/multiple), size of the largest tumor (≤50/>50 mm), tumor distribution (unilobar/bilobar), etiology of cirrhosis (none/HBV/HCV/alcohol/cryptogenic), albumin (≤35/>35 g/L), and total bilirubin (≤17.1/>17.1 µmol/L). All variables in the univariate analyses were entered into the multivariate analysis to assess their significance as independent predictors. Hazard ratios and respective 95% confidence intervals (CIs) were compared.

To minimize the effect of potential confounders on selection bias, logistic regression analysis was used to perform propensity-score matching (PSM) between the TACE-MWA group and the TACE alone group. Independent variables entered into the PSM model included sex (male/female), age (≤55/>55 years), AFP level (≤400/>400 ng/mL), platelet count (≤50/>50 ×109/L), number of tumors (single/multiple), size of the largest tumor (≤50/>50 mm), tumor distribution (unilobar/bilobar), etiology of cirrhosis (none/HBV/HCV/alcohol/cryptogenic), albumin (≤35/>35 g/L), and total bilirubin (≤17.1/>17.1 µmol/L). Each treatment group was matched according to the generated PSM using a caliper width of 0.1. The OS, PFS, and downstaging rates after PSM were compared between the two groups. Statistical analyses were performed using statistical software (SPSS version 20; International Business Machines Corporation, Armonk, NY, USA) or R software (version 4.0.2; ). Statistical tests were two-sided, and P<0.05 indicated a significant difference.

Results

Baseline Characteristics of the Study Population

The entire study population included 205 males and 26 females with a mean age of 56.4 ± 11.7 years (range: 28 to 83 years). The diagnosis of HCC was based on the pathology (n=37) or the 2018 version of the Liver Imaging Reporting and Data System (LI-RADS) criteria (n=194). There were 214 patients with Child-Pugh A HCC and 17 patients with Child-Pugh B HCC. In the entire study population, 113 patients had early-stage HCC (BCLC-A), and 118 patients had intermediate-stage HCC (BCLC-B). The baseline patient characteristics among the four institutions are illustrated in Table 1.

Table 1

The Baseline Patient Characteristics Among Four Institutions

Characteristics	Overall (n=231)	Institution A (n=71)	Institution B (n=74)	Institution C (n=45)	Institution D (n=41)	P
Age (years)	56.2±11.6	58.8±11.5	55.3±11.0	54.0±11.0	55.7±14.8	0.083
Sex (%)						0.024
Male	205 (88.7%)	65 (91.5%)	59 (79.7%)	41 (91.1%)	40 (97.6%)
Female	26 (11.3%)	6 (8.5%)	15 (20.3%)	4 (7.9%)	1 (2.4%)
Number of tumors (%)						<0.001
Single	113 (48.9%)	36 (50.7%)	32 (43.2%)	26 (57.8%)	19 (46.3%)
Multiple	118 (51.1%)	35 (49.3%)	42 (56.8%)	19 (42.2%)	22 (53.7%)
Albumin (g/L, median with IQR)	56.2±11.6	36.5±4.6	38.8±5.3	39.7±4.3	38.5±6.0	0.169
Total bilirubin (umol/L, median with IQR)	15.3 (11.6)	15.6 (13.4)	15.9 (8.0)	14.9 (7.5)	15.5 (13.4)	0.830
Platelet (×109, median with IQR)	155.0 (103.0)	143.0 (107.0)	155.0 (108.75)	176.0 (106.5)	140.0 (120.0)	0.051
Child-Pugh class (%)						0.088
A	214 (92.6%)	66 (93.0%)	67 (90.5%)	45 (100%)	36 (87.8%)
B	17 (7.4%)	5 (7.0%)	7 (9.5%)	0	5 (12.2%)
Etiologies of cirrhosis (%)						0.038
None	27 (11.7%)	12 (16.9%)	5 (6.8%)	1 (2.2%)	9 (22.0%)
HBV	188 (81.4%)	54 (76.1%)	64 (86.5%)	41 (91.1%)	29 (70.7%)
HCV	7 (3.0%)	3 (4.2%)	2 (2.7%)	0	2 (4.9%)
Alcohol	3 (1.3%)	0	2 (2.7%)	1 (2.2%)	0
Cryptogenic	6 (2.6%)	2 (2.8%)	1 (1.4%)	3 (1.3%)	1 (2.4%)
Tumor distribution (%)						0.584
Unilobar	148 (64.1%)	43 (60.6%)	52 (70.3%)	27 (60.0%)	26 (63.4%)
Bilobar	83 (35.9%)	28 (39.4%)	22 (29.7%)	18 (40.0%)	15 (36.6%)
AFP (%)						0.134
≤400 ng/mL	142 (61.5%)	40 (56.3%)	52 (70.3%)	23 (51.1%)	27 (65.9%)
>400 ng/mL	89 (38.5%)	31 (43.7%)	22 (29.7%)	22 (48.9%)	14 (34.1%)
The largest tumor size (mm, median with IQR)	75.0 (48.8)	74.0 (56.0)	63.0 (41.5)	102.0 (67.1)	84.9 (43.6)	<0.001

Abbreviations: IQR, inter-quartile range; AFP, alpha fetoprotein.

PFS Rates

The median PFS was 317 days (95% CI: 159–475) in the TACE-MWA group and 212 days (95% CI: 155–268) in the TACE alone group. There was a significant difference in the PFS rate between the two groups (Figure 2A) (P=0.003). In the univariate analysis, poor PFS was associated with treatment with TACE alone (P=0.003), larger tumors (P=0.049), and multinodular HCCs (P=0.037). In the multivariate analyses, the three variables were independent predictors of poor PFS. Detailed information on the potential risk factors for poor PFS is listed in Table 2.

Figure 2

The comparison of PFS (A) and OS (B) before PSM. Both the PFS (P=0.003) and the OS (P<0.001) are significantly higher in patients treated with TACE-MWA than those of TACE alone.

Table 2

Potential Risk Factors of Poor PFS for HCC Patients

Variables	No. of Cases	Univariate Analysis		Multivariate Analysis
		Hazard Ratio (95% CI)	P	Hazard Ratio (95% CI)	P
Modalities (TACE-MWA/TACE alone)	91/140	1.662 (1.189–2.322)	0.003	1.614 (1.116–2.332)	0.011
Sex (male/female)	205/26	0.911 (0.542–1.531)	0.724	1.258 (0.722–2.193)	0.417
Age (≤55/>55 years)	115/116	0.842 (0.613–1.157)	0.289	1.056 (0.750–1.486)	0.756
Etiologies of cirrhosis (none/HBV/HCV/ Alcohol/ Cryptogenic)	27/188/7/3/6	1.101 (0.851–1.425)	0.465	1.283 (0.968–1.701)	0.083
Platelet count (≤50/>50 ×109)	11/220	1.120 (0.548–2.289)	0.756	1.490 (0.680–3.268)	0.319
Albumin (≤35/>35 g/L)	62/169	0.924 (0.652–1.309)	0.656	0.941 (0.655–1.350)	0.740
Total bilirubin (≤17.1/>17.1 umol/L)	143/88	1.043 (0.754–1.444)	0.799	0.955 (0.673–1.355)	0.797
AFP level (≤400/>400 ng/mL)	142/89	1.078 (0.776–1.497)	0.655	1.053 (0.747–1.485)	0.767
Tumor distribution (unilobar/bilobar)	150/81	1.291 (0.930–1.792)	0.127	1.066 (0.741–1.534)	0.730
Size of the largest tumor (≤50/>50 mm)	49/182	1.512 (1.003–2.280)	0.049	2.158 (1.335–3.488)	0.002
Number of tumors (single/multiple)	113/118	1.410 (1.022–1.946)	0.037	2.083 (1.378–3.146)	<0.001

Abbreviations: PFS, progression-free survival; HCC, hepatocellular carcinoma; TACE, transarterial chemoembolization; MWA, microwave ablation; AFP, Alpha fetoprotein.

OS Rates

The mean follow-up period was 607 days in the TACE alone group and 724 days in the TACE-MWA group. During the study period, 90 patients (90/140, 64.3%) in the TACE alone group and 25 patients (25/91, 27.5%) in the TACE-MWA group died. The median OS was 1488 days (95% CI: 1119–1857) in the TACE-MWA group and 552 days (95% CI: 416–688) in the TACE alone group. The 1-, 2-, and 3-year survival rates were 92.0%, 81.1%, and 63.6% in the TACE-MWA group, respectively, and 64.7%, 39.4%, and 33.1% in the TACE alone group, respectively. The OS in the TACE-MWA group was significantly longer compared to that in the TACE alone group (Figure 2B) (P<0.001). In the univariate analysis, poor OS was associated with treatment with TACE alone (P<0.001), higher AFP level (>400 ng/mL) (P=0.039), bilobar tumor distribution (P=0.040), and larger tumors (P=0.016). In the multivariate analyses, larger tumors (P=0.029) and treatment with TACE alone (P<0.001) were independent predictors of poor OS. Detailed information on the potential risk factors for poor OS is listed in Table 3.

Table 3

Potential Risk Factors of Poor OS for HCC Patients

Variables	No. of Cases	Univariate Analysis		Multivariate Analysis
		Hazard Ratio (95% CI)	P	Hazard Ratio (95% CI)	P
Modalities (TACE-MWA/TACE alone)	91/140	2.980 (1.899–4.679)	<0.001	2.751 (1.678–4.510)	<0.001
Sex (male/female)	205/26	0.763 (0.398–1.459)	0.413	1.160 (0.571–2.357)	0.681
Age (≤55/>55 years)	115/116	0.808 (0.559–1.167)	0.255	1.095 (0.731–1.641)	0.659
Etiologies of cirrhosis (none/HBV/HCV/Alcohol/Cryptogenic)	27/188/7/3/6	0.963 (0.718–1.291)	0.800	1.028 (0.756–1.397)	0.862
Platelet count (≤50/>50 ×109)	11/220	1.127 (0.459–2.766)	0.794	1.081 (0.409–2.856)	0.875
Albumin (≤35/>35 g/L)	62/169	0.972 (0.650–1.455)	0.891	0.912 (0.604–1.376)	0.660
Total bilirubin (≤17.1/>17.1 umol/L)	143/88	1.059 (0.728–1.541)	0.763	1.134 (0.764–1.682)	0.532
AFP level (≤400/>400 ng/mL)	142/89	1.476 (1.020–2.135)	0.039	1.456 (0.982–2.160)	0.062
Tumor distribution (unilobar/bilobar)	150/81	1.476 (1.018–2.139)	0.040	1.404 (0.942–2.091)	0.095
Size of the largest tumor (≤50/>50 mm)	49/182	1.888 (1.127–3.162)	0.016	1.984 (1.073–3.666)	0.029
Number of tumors (single/multiple)	113/118	1.190 (0.823–1.719)	0.356	1.412 (0.906–2.203)	0.128

Abbreviations: OS, overall survival; HCC, hepatocellular carcinoma; TACE, transarterial chemoembolization; MWA, microwave ablation; AFP, Alpha fetoprotein.

PSM Analysis

Before PSM, there were no significant differences between the TACE-MWA group and the TACE alone group in terms of age (P=0.090), etiology of cirrhosis (P=0.483), Child-Pugh class (P=0.235), tumor distribution (P=0.299), platelet count (P=0.534), albumin (P=0.298), total bilirubin (P=0.196), or the number of tumors (P=0.224). However, there were significant differences in terms of sex (P=0.004), AFP level (P=0.026), and size of the largest tumor (P<0.001) between the two groups. After PSM, a total of 146 patients were matched, including 73 patients in the TACE-MWA group and 73 patients in the TACE alone group. There were no differences in the baseline characteristics between the two groups after PSM. The detailed baseline characteristics of the patients before and after PSM are illustrated in Table 4.

Table 4

Baseline Characteristics of Patients Before and After PSM

	Before PSM			After PSM
Characteristics	TACE+MWA (n=91)	TACE Alone (n=140)	P	TACE-MWA (n=73)	TACE Alone (n=73)	P
Sex			0.004			1.000
Male	74	131		67	67
Female	17	9		6	6
Age			0.090			0.098
≤55 years	39	76		31	41
>55 years	52	64		42	32
Etiologies of cirrhosis			0.483			0.966
None	8	19		7	5
HBV	77	111		62	63
HCV	3	4		2	2
Alcohol	2	1		1	1
Cryptogenic	1	5		1	2
Platelet count			0.534			0.719
≤50 ×109	3	8		3	5
>50 ×109	88	132		70	68
Albumin			0.298			0.715
≤35 g/L	21	41		20	22
>35 g/L	70	99		53	51
Total bilirubin			0.196			0.730
≤17.1 umol/L	61	82		48	46
>17.1 umol/L	30	58		25	27
AFP level			0.026			0.861
≤400 ng/mL	64	78		48	49
>400 ng/mL	27	62		25	24
Tumor distribution			0.299			0.385
Unilobar	62	86		45	50
Bilobar	29	54		28	23
Size of the largest tumor			<0.001			0.068
≤50 mm	33	16		26	16
>50 mm	58	124		47	57
Number of tumors			0.224			0.320
Single	40	73		31	37
Multiple	51	67		42	36

Abbreviations: PSM, propensity score matching; SD, standard deviation; IQR, interquartile range; AFP, alpha fetoprotein; INR, international normalized ratio.

Comparison of PFS and OS Rates Between the TACE-MWA Group and TACE Alone Group After PSM

After PSM, the median PFS was 380 days (95% CI: 226–728) in the TACE-MWA group and 247 days (95% CI: 146–348) in the TACE alone group. There was a significant difference in the PFS rate between the two groups after PSM (P=0.043) (Figure 3A). The median OS was 1488 days (95% CI: 1070–1906) in the TACE-MWA group and 700 days (95% CI: 208–1192) in the TACE alone group. The 1-, 2-, and 3-year survival rates were 93.6%, 80.5%, and 61.6% in the TACE-MWA group, respectively, and 72.4%, 48.9%, and 41.9% in the TACE alone group, respectively. The OS in the TACE-MWA group was significantly higher than that in the TACE alone group (P=0.002) (Figure 3B).

Figure 3

The comparison of PFS (A) and OS (B) after PSM. Both the PFS (P=0.043) and the OS (P=0.002) are significantly higher in patients treated with TACE-MWA than those of TACE alone.

Comparison of the Downstaging Rate Between the TACE-MWA Group and TACE Alone Group After PSM

After PSM, there were 48 patients in the TACE-MWA group and 26 patients in the TACE alone group within the UCSF criteria who were eligible for the assessment of downstaging probability. Among the 48 patients in the TACE-MWA group, 37 patients achieved a successful downstaging, with a downstaging rate of 77.1% (37/48). In the TACE alone group, 14 patients achieved successful downstaging, with a downstaging rate of 53.8% (14/26). The downstaging rate in the TACE-MWA group was significantly higher than that in the TACE alone group (P=0.039). Failure to downstage in the TACE-MWA group was mainly due to the occurrence of vascular invasion (n=6), local tumor progression of the target lesions (n=6), and extrahepatic metastasis (n=4). Similarly, failure to downstage in the TACE alone group was mainly due to the occurrence of vascular invasion (n=7), local tumor progression of the target lesions (n=7), and extrahepatic metastasis (n=3). Typical imaging of downstaging in the two groups is shown in Figures 4 and 5.

Figure 4

A 65-year-old male with a solitary HCC lesion in the right lobe of the liver. The lesion is 75 mm in size, and TACE is performed (A). After TACE, the MR imaging shows residual enhancement in the edge of the tumor (white arrow) (B and C). A percutaneous MWA is performed in the residual enhancement area (D). After one month of ablation, no residual tumor is detected (E and F). Four months after ablation, the patient is still within the Milan Criteria (G and H), which indicates a successful downstaging case.

Figure 5

A 75-year-old male with a solitary HCC lesion in the right lobe of the liver. The lesion is 71 mm in size (A and B), and TACE is performed. One month after TACE, there is no residual tumor detected on contrast-enhanced CT (C and D). Five months after TACE, there is no recurrence found (E and F), which indicates a successful downstaging case.

Discussion

Compared to the combination therapy of TACE and MWA, treatment with TACE alone was an independent risk factor for poor PFS (P=0.011, hazard ratio: 2.751, 95% CI: 1.678–4.510) and OS (P<0.001, hazard ratio: 1.614, 95% CI: 1.116–2.332) in HCC patients beyond MC. According to the BCLC staging system, patients with HCC beyond MC, in the absence of vascular invasion and extrahepatic spread, are classified into BCLC-A (single tumor greater than 5 cm) or BCLC-B (more than three tumors). TACE is recommended in this class when curative treatment is not feasible.20–22 However, the treatment efficacy of TACE alone is dissatisfactory as it is difficult to achieve complete tumor necrosis after the procedure.23 Thermal ablation is widely used as a curative treatment for small HCC tumors, but the treatment efficacy of thermal ablation alone is also dissatisfactory due to the high tumor burden of patients with HCC beyond MC. Bertrand et al demonstrated that the outcome of thermal ablation is only favorable in tumors smaller than 3 cm.24 Leung et al reported that the initial tumor size is a significant prognostic factor for the local recurrence of liver malignancies treated with MWA.25 Recent evidence has suggested that the combination of TACE and thermal ablation has a synergistic effect on tumors, which may improve local tumor control for HCC patients, and the results of the present study support this finding. In the present study, greater PFS (380 days vs 247 days, P=0.043) and OS (1488 days vs 700 days, P=0.002) benefits were noted in the TACE-MWA group compared to the TACE alone group after a one-to-one PSM analysis. The likely mechanisms underlying this benefit of the combination therapy are as follows: (a) MWA can result in more thorough tumor necrosis than TACE, which may improve the PFS rate, thus alleviating the tumor burden and improving the OS rate; (b) TACE may reduce the blood flow of the tumor and minimize the heat loss during thermal ablation, thus enlarging the ablative zone; (c) TACE is also effective in treating undetected satellite lesions adjacent to the main large tumor when a sufficient thermal ablative zone is not achieved; and (d) MWA can effectively destroy some hypovascular HCC tumors that do not respond well to TACE treatment alone.26–29

Another important finding of the study was that TACE following MWA may improve the downstaging rate significantly more than TACE alone. Liver transplantation is considered the standard therapy for HCC patients within MC, with a low recurrence rate (10%) and high 5-year survival rates (70%).30 However, for patients beyond MC, liver transplantation is controversial due to the relatively high post-treatment recurrence rate and shortage of liver grafts.31 Therefore, in HCC patients beyond MC, a downstaging strategy is required. In principle, downstaging can be used to select patients with HCC who are initially beyond transplant criteria but will likely benefit from a liver transplant.32 Previous studies have reported similar effectiveness of liver transplant in patients who are initially beyond MC and later successfully downstage to within MC and HCC patients who meet the MC from the outset.33,34 Several locoregional therapies have been adopted to downstage HCC patients, and various downstage rates have been reported, ranging from 11.0% to 77.0% (29). In previous studies, TACE has been reported as the most popular treatment option for downstaging.33–35 However, not all HCC patients respond well to TACE since its efficacy depends on the target tumor having a good blood supply and adequate embolization of all tumor feeders.36 In the present study, the successful downstaging rate reported in patients treated with TACE alone was only 53.8%; that is, nearly half of the HCC patients could not successfully downstage to receive liver transplantation. Although evidence showing the superiority of one downstaging modality over another is inadequate, the present study indicates that the combination therapy of TACE and MWA may result in a more successful downstaging rate than TACE alone (77.1% vs 53.8%, P=0.039).

There are several limitations to this study. First, this was a retrospective study with a small sample size. Therefore, selection bias may have influenced the results, and a further prospective study with a relatively large sample size should be conducted to confirm the findings. Second, the survival benefit of the liver transplant after successful downstaging in patients treated with TACE-MWA or TACE alone was not evaluated, as no patient received a liver transplant in the present study cohort. A further study should be conducted to confirm the survival benefit of a liver transplant after successful downstaging using TACE-MWA or TACE alone.

Conclusion

In conclusion, TACE-MWA may offer a survival benefit in terms of OS and PFS in HCC patients beyond the MC compared to TACE alone. In addition, TACE-MWA may provide a significantly higher probability of downstaging within the MC than TACE alone, thereby increasing the chances of HCC patients receiving a liver transplant.