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. 2020 Apr 22;15(2):284–294. doi: 10.5009/gnl19367

Comparison of Sorafenib versus Hepatic Arterial Infusion Chemotherapy-Based Treatment for Advanced Hepatocellular Carcinoma with Portal Vein Tumor Thrombosis

Young Eun Ahn 1,#, Sang Jun Suh 1,#, Hyung Joon Yim 1,, Yeon Seok Seo 1,, Eileen L Yoon 2, Tae Hyung Kim 1, Young Sun Lee 1, Sun Young Yim 1, Hae Rim Kim 1, Seong Hee Kang 3, Young Kul Jung 1, Ji Hoon Kim 1, Jong Eun Yeon 1, Soon Ho Um 1, Kwan Soo Byun 1
PMCID: PMC7960975  PMID: 32307975

Abstract

Background/Aims

Sorafenib is the first approved systemic treatment for advanced hepatocellular carcinoma (HCC). However, its clinical utility is limited, especially in Asian countries. Several reports have suggested the survival benefits of hepatic arterial infusion chemotherapy (HAIC) for advanced HCC with main portal vein tumor thrombosis (PVTT). This study aimed to compare the efficacy of sorafenib-based therapy with that of HAIC-based therapy for advanced HCC with main PVTT.

Methods

Advanced HCC patients with main PVTT treated with sorafenib or HAIC between 2008 and 2016 at Korea University Medical Center were included. We evaluated overall survival (OS), time-to-progression (TTP), and the disease control rate (DCR).

Results

Seventy-three patients were treated with sorafenib (n=35) or HAIC (n=38). Baseline characteristics were not significantly different between groups, except the presence of solid organ metastasis (46% vs 5.3%, p<0.001). The median OS time was not significantly different between the groups (6.4 months vs 10.0 months, p=0.139). TTP was longer in the HAIC group than in the sorafenib group (2.1 months vs 6.2 months, p=0.006). The DCR was also better in the HAIC group than in the sorafenib group (37% vs 76%, p=0.001). Subgroup analysis, which excluded patients with extrahepatic solid organ metastasis, showed the same trends for the median OS time (8.8 months vs 11.1 months, p=0.097), TTP (1.9 months vs 6.0 months, p<0.001), and DCR (53% vs 81%, p=0.030).

Conclusions

HAIC-based therapy may be an alternative to sorafenib for advanced HCC with main PVTT by providing longer TTP and a better DCR. (Gut Liver 2021;15-294)

Keywords: Carcinoma, hepatocellular; Portal vein thrombosis; Sorafenib; Hepatic artery; Chemotherapy

INTRODUCTION

Hepatocellular carcinoma (HCC) is a global health issue that presents with poor survival outcomes.1,2 Sorafenib is the firstly approved systemic treatment for HCC.3-5 It is indicated for patients with well-preserved liver function (Child-Pugh class A) and advanced tumors (i.e., Barcelona Clinic of Liver Cancer stage C). The survival benefits of sorafenib have been shown in two randomized placebo-controlled trials.3,4 In the Sorafenib Hepatocellular Carcinoma Assessment Randomized Protocol (SHARP trial; a multicenter, phase III, double-blind, and placebo-controlled trial), 602 patients with advanced HCC in North America and Europe were enrolled. Sorafenib treatment increased the median overall survival (OS) from 7.9 months in the placebo group to 10.7 months in the sorafenib group (hazard ratio, 0.69), which represented a 31% decrease in the relative mortality risk.4 In a parallel phase III trial, which was conducted in the Asian-Pacific population, 226 patients with advanced HCC were enrolled in China, Taiwan, and South Korea. It also showed longer survival in the sorafenib group than in the placebo group (6.5 months vs 4.2 months; hazard ratio, 0.68).3 Although a direct comparison between the two studies requires caution, the worsened outcome of patients included in the Asia-Pacific trial compared with that in the SHARP trial may be attributed to patient characteristics. The Asia-Pacific trial enrolled patients with more advanced disease (Eastern Cooperative Oncology Group [ECOG] 1-2 or metastatic disease) who were more likely to have worsened liver disease etiology, such as hepatitis B virus (HBV) infection. A global, non-intentional, surveillance study to evaluate the safety of sorafenib under real-life practice condition, the GIDEON (Global Investigation of Therapeutic Decisions in Hepatocellular Carcinoma and of Its Treatment with Sorafenib) study, also showed similar findings, suggesting more common worsened prognosis factors in Asian populations.6 In particular, as the geographical distribution of the main risk factors for HCC predominates as HBV in Asia (70%) than in Europe (10% to 15%) or North America (20%),1,2 decreased efficacy of sorafenib is expected in patients of the Asia-Pacifica region.

Moreover, the previously mentioned two large phase III trials enrolled patients restricted mainly to Child-Pugh class A; thus, sorafenib efficacy may decline in real practice if the range of patients is expanded to those with poor liver function. Indeed, many studies reported that the efficacy of sorafenib was reduced as the Child-Pugh score increased.7-11

Hepatic arterial infusion chemotherapy (HAIC) was developed in Japan and used for patients with advanced HCC in practice, although it is not preferred in Western countries because there are no data from randomized controlled trials. The theoretical advantage of HAIC is that the chemotherapeutic agent is more concentrated at the hepatic tumor and the adverse effects are milder than those observed with systemic chemotherapy. Currently several studies, which were conducted in Asian countries, suggested favorable outcomes of HAIC for HCC with portal vein tumor thrombosis (PVTT).12-16 In those studies, the median OS and time-to-progression (TTP) were estimated to be 7–9 months and 2–6 months, respectively, in HCC patients with PVTT who were treated with HAIC.12-16

A direct comparison between sorafenib and HAIC has not been well evaluated in a real-life setting. Importantly, the comparison of sorafenib and HAIC in a population with many chronic HBV infections and Child-Pugh class B is necessary. If the efficacy is proved to be comparable between the two treatment modalities, HAIC may be useful in patients who cannot be treated with sorafenib because of costliness, decreased liver function, or adverse effects related to sorafenib. Thus, we aimed to compare the efficacy of sorafenib and HAIC in HCC patients with main PVTT to evaluate if HAIC can be an alternative option for advanced HCC treatment.

MATERIALS AND METHODS

1. Patients’ eligibility

Between January 2008 and December 2016, 90 patients with advanced HCC were treated with sorafenib or HAIC at the Korea University Medical Center. Among them, we enrolled 73 HCC patients with main PVTT and retrospectively analyzed their clinical data. Main PVTT was defined as tumor thrombosis in the main portal trunk on radiographic images such as computed tomography or magnetic resonance images with dynamic enhance study. The study protocol was approved by the Institutional Review Board at Korea University (IRB number: AS13115) and conformed to the Declaration of Helsinki. The requirement for obtaining informed consent from patients was waived because of the retrospective nature of the study.

2. Hepatic artery catheterization and chemoport insertion

A catheter was inserted through the femoral artery using the Seldinger method. After localization of HCC, a 3-F heparin-coated catheter was inserted, and its tip was advanced to the common or proper hepatic artery. The other end of the catheter was connected to the chemoport, which was implanted in a subcutaneous pocket created in the inguinal region. The gastroduodenal and right gastric arteries were occluded with a coil to prevent gastroduodenal injury by chemotherapeutic agents.

3. Treatment protocol

Patients received repeated HAIC via the chemoport. At every cycle of chemotherapy, the tip of the catheter was ascertained by an interventional radiologist to prevent damage to other organs. HAIC was performed with an infusion of cisplatin (60 mg/m2) for 1 day and 5-flurouracil (500 mg/m2) for 3 days every 4 weeks, as previously reported.17 Sorafenib was initiated with 400 mg twice daily, and the dose was adjusted according to adverse events.

4. Response and safety evaluation and definitions

Treatment response was assessed according to the modified Response Evaluation Criteria in Solid Tumors.18 The disease control rate (DCR) was defined as the proportion of patients who had a best response rating of complete response, partial response, or stable disease, which was maintained for 4 weeks since the first manifestation of that rating. OS, which is the primary endpoint, was defined as the time from assignment of therapy for HCC with PVTT to death.19 Patients alive at the end of follow-up were censored. TTP was defined as the time from assignment of therapy for HCC with PVTT to radiological progression.18,19 Deaths during follow-up without evidence of radiological progression were censored.19 Safety and adverse events were assessed by reviewing medical records and laboratory findings according to the Common Terminology Criteria for Adverse Events v5.0 (https://ctep.cancer.gov/protocolDevelopment/electronic_applications/ctc.htm).20

5. Statistical analysis

Statistical analysis was performed using the Statistical Package for the Social Sciences software version 18 (SPSS Inc., Chicago, IL, USA). Differences between the groups were examined for statistical significance using the Student t-test or the chi-square test. The cumulative survival rate and tumor progression rate were calculated from the date of initiation of each therapy and assessed using the Kaplan–Meier life-table method, and differences were evaluated using the log-rank test. Tumor response to treatment was evaluated using the chi-square test. Univariate and multivariate analyses of factors that influenced survival were assessed using the Cox proportional hazard model. Statistical significance was defined as a two-sided p-value <0.05.

RESULTS

1. Baseline characteristics

A total of 73 patients were treated with sorafenib (n=35) and HAIC (n=38). The patients were older in the sorafenib group than in the HAIC group (58.3±9.5 years vs 53.0±11.6 years, p=0.037). The etiology of chronic liver disease was mostly chronic HBV infection, with no statistical difference between the groups (p=0.230). The proportion of patients with Child-Pugh class A liver function (69% vs 71%, p=0.817) and ECOG performance status 0-1 (69% vs 77%, p=0.892) was not different between the sorafenib and HAIC groups. About two-thirds of patients in each group were treated with sorafenib (60%) or HAIC-based (76%) therapy as the first treatment and others were treated with radiofrequency ablation or resection before. All patients were Barcelona Clinic of Liver Cancer stage C owing to portal vein invasion, and the PVTT status was Vp4 (presence of a tumor thrombus in the main trunk of the portal vein or a portal vein branch contralateral to the primarily involved lobe or both). The tumor status differed for solid organ metastasis. More patients with solid organ metastasis were treated with sorafenib than with HAIC (46% vs 5.3%, p<0.001). The proportions of infiltrative type (54% vs 63%, p=0.441) and lymph node metastasis (40% vs 34%, p=0.609) were not different between the sorafenib and HAIC groups. The most common site of metastasis, in order, was the lung, adrenal gland, and bones. Laboratory findings were not different between the groups (Table 1).

Table 1.

Baseline Characteristics

Characteristic Sorafenib-based
(n=35)		 HAIC-based
(n=38)		 p-value
Age, yr 58.3±9.5 53.0±11.6 0.037
Male sex 30 (86) 30 (79) 0.450
Etiology
CHB/CHC/alcohol/cryptogenic, n 24/2/6/3 33/2/2/1 0.230
CHB or CHC+alcohol 12 (46) 14 (54) 0.820
Child-Pugh class A/B 24 (69)/11 (31) 27 (71)/11 (29) 0.817
Performance status by ECOG 0-1/2/3 24 (69)/9 (25)/2 (6) 29 (77)/7 (18)/2 (5) 0.892
Prior treatment
None/curative (resection, RFA) 21 (60)/14 (40) 29 (76)/9 (24) 0.134
Tumor type nodular/infiltrative 16 (46)/19 (54) 14 (37)/24 (63) 0.441
LN metastasis 14 (40) 13 (34) 0.609
Solid organ metastasis 16 (46) 2 (5.3) <0.001
Lung/adrenal/bone/peritoneum, n 12/2/1/1 0/1/0/1
Laboratory findings
Platelet count, ×103/µL 196±105 162±83 0.133
Albumin, g/dL 3.53±0.40 3.48±0.43 0.623
AST, IU/mL 103±98 89±63 0.484
ALT, IU/mL 56±47 58±35 0.835
Total bilirubin, mg/dL 1.16±0.55 1.04±0.48 0.302
PT, INR 1.16±0.12 1.13±0.13 0.270
AFP, ng/mL 69,745±21,274 71,341±14,823 0.971
PIVKA-II, mAU/mL 1,437±824 1,361±821 0.714
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Data are presented as mean±SD or number (%).

HAIC, hepatic arterial infusion chemotherapy; CHB, chronic hepatitis B; CHC, chronic hepatitis C; ECOG, Eastern Cooperative Oncology Group; RFA, radiofrequency ablation; LN, lymph node; AST, aspartate aminotransferase; ALT, alanine aminotransferase; PT, prothrombin time; INR, international normalized ratio; AFP, alpha-fetoprotein; PIVKA-II, protein induced by vitamin K absence or antagonist-II.

2. Treatment response and efficacy of chemotherapy

The mean treatment durations were 2.8 (median, 2.0 months [range, 0.5 to 9.9 months]) and 3.9 (median, 2.8 months [range, 0.1 to 11.7 months]) months in the sorafenib and HAIC groups (p=0.120), respectively. In comparison with the sorafenib group, the median OS (6.4 months vs 10.0 months, p=0.139) (Fig. 1A) tended to be longer in the HAIC group but there was no statistical difference. However, the TTP (2.1 months vs 6.2 months, p=0.006) (Fig. 1B) was significantly longer in the HAIC group.

Fig. 1.

Fig. 1

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Overall survival time and time-to-progression in the whole cohort. Comparison of survival (A) and time-to-progression (B) between the sorafenib and hepatic arterial infusion chemotherapy (HAIC) groups.

Final treatment responses such as progressive disease, stable disease, partial response, and complete response were noted in 28 (80%), seven (20%), 0, and 0 patients of the sorafenib group, respectively, and 23 (60.5%), 13 (34.2%), one (2.6%), and one (2.6%) patient of the HAIC group, respectively (p=0.059) (Table 2). One patient experienced complete response in the HAIC group and was followed up for 16 months without recurrence. The best treatment responses such as above during chemotherapy was noted in 22, 10, three, and 0 patients of the sorafenib group, respectively, and nine, 22, six, and one patient of the HAIC group (p=0.001), respectively. DCRs were 37.1% and 76.3% in the sorafenib and HAIC groups, respectively (p=0.001), indicating better control in the HAIC group.

Table 2.

Efficacy and Response Rate of Sorafenib and HAIC-Based Therapy

Treatment response Overall patients (n=73) Patients without solid organ metastasis (n=55)
Sorafenib (n=35) HAIC (n=38) p-value Sorafenib (n=19) HAIC (n=36) p-value
Overall survival, mo 0.150 0.075
Median (range) 6.4 (0.8–31.0) 10.0 (1.2–30.8) 10.7 (1.2–14.3) 11.1 (1.2–30.8)
95% CI 0.6–12.2 5.9–14.1 4.2–17.2 6.0–16.2
Time-to-progression, mo 0.006 0.016
Median (range) 2.1 (0.7–10.7) 6.2 (0.2–30.8) 2.2 (1.2–10.7) 6.2 (0.2–30.8)
95% CI 1.9–2.3 3.6–8.8 1.8–2.6 4.1–8.3
Level of response, No (%) 0.150 0.463
Complete response 0 1 (2.6) 0 1 (2.8)
Partial response 0 1 (2.6) 0 1 (2.8)
Stable disease 7 (20.0) 13 (34.2) 4 (21.1) 13 (36.1)
Progressive disease 28 (80.0) 23 (60.5) 15 (79.0) 21 (58.3)
DCR, No. (%)* 13 (37.1) 29 (76.3) 0.001 10 (52.6) 29 (80.6) 0.030
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HAIC, hepatic arterial infusion chemotherapy; CI, confidence interval; DCR, disease control rate.

*DCR defined as the proportion of patients who had a “best response rating” of complete response, partial response, or stable disease, which was maintained for 4 weeks from the first manifestation of the rating.

3. Subgroup analysis

1) Patients without extrahepatic metastasis

As there was a difference between the two groups in the proportion of extrahepatic solid organ metastasis, we performed a subgroup analysis excluding patients with solid organ metastasis. The median OS showed no statistical difference between the sorafenib and the HAIC groups (8.8 months vs 11.1 months, p=0.097) (Fig. 2A). However, TTP was longer in the HAIC group (1.9 months vs 6.0 months, p<0.001) (Fig. 2B). Likewise, compared with those treated with sorafenib, patients treated with HAIC showed better DCR (53% vs 81%, p=0.030).

Fig. 2.

Fig. 2

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Overall survival time and time-to-progression in patients without extrahepatic metastasis. Comparison of survival (A) and time-to-progression (B) between the sorafenib and hepatic arterial infusion chemotherapy (HAIC) groups.

2) Patients with or without combination therapy

Details of the applied combination therapies are described in the next section. As the combination therapy might have influenced the results of the study, we have subdivided each treatment group into the monotherapy and combination therapy subgroups. The median OS was not significantly different among the four subgroups (p=0.259), whereas TTP showed significant differences among the four groups (p=0.031). Post hoc analysis revealed that the median OS was not significantly different between the sorafenib monotherapy, sorafenib with combination therapy, HAIC monotherapy, and HAIC with combination therapy subgroups (10.7 months vs 5.1 months vs 15.3 months vs 10.0 months), except the median OS between the sorafenib with combination therapy and HAIC monotherapy subgroups (p=0.032) (Fig. 3A). The TTP was 2.1, 4.4, 4.1, and 6.2 months for the four subgroups, respectively, and that of the HAIC monotherapy (p=0.043) and HAIC with combination therapy subgroups (p=0.011) was significantly longer than that of the sorafenib monotherapy subgroup (Fig. 3B) by post hoc analysis.

Fig. 3.

Fig. 3

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Overall survival time and time-to-progression in the subgroup analysis. Comparison of survival (A) and time-to-progression (B) between the sorafenib monotherapy group, sorafenib with combination therapy group, hepatic arterial infusion chemotherapy (HAIC) monotherapy group and HAIC with combination therapy group.

The DCRs were 27.6%, 83.3%, 66.7%, and 80.8% for the four subgroups, respectively (p<0.001).

3) Patients with decreased liver function

Twenty-two patients with Child-Pugh class B liver function were included. Fourteen patients had a Child-Turcotte-Pugh (CTP) score of 7 (seven in the sorafenib group and seven in the HAIC group), seven had a CTP score of 8 (four in the sorafenib group and three in the HAIC group), and one in the HAIC group had a CTP score of 9. The median OS of patients with a CTP score of 7 was 5.9 and 15.3 months (p=0.051) and that of patients with a CTP score of 8 or 9 was 3.4 and 5.9 months (p=0.32) in the sorafenib and HAIC groups, respectively. The TTP of patients with a CTP score of 7 was 2.0 and 3.9 months (p=0.332) and that of patients with a CTP score of 8 or 9 was 1.9 and 2.0 (p=0.308) in the sorafenib and HAIC groups, respectively. The DCRs of patients with a CTP score of 7 were 28% and 57% (p=0.298) and those of patients with a CTP score of 8 or 9 were 0% and 75% (p=0.040) in the sorafenib and HAIC groups, respectively.

4) Patients with poor performance status

Four patients with an ECOG score of 3 were included in the study. Two belonged to the sorafenib group, and the other two to the HAIC group. Treatment was initiated only if improvement of performance status was possible or if the patient had a strong desire for anticancer therapy.

The median OS of patients with an ECOG score of 3 was 0.8 months in the sorafenib group and 6.3 months in the HAIC group (p=0.317). The TTP of the patients with an ECOG score of 3 was 0.7 months in the sorafenib group and 4.1 months in the HAIC group (p=0.09). In all patients with an ECOG score of 3, the final treatment response was progressive disease. The best treatment response during chemotherapy was a progressive disease for two patients in the sorafenib group and stable disease for two in the HAIC group. One of the patients in the sorafenib group reported grade 3 fatigue, nausea, and abdominal pain, and one of those in the HAIC group reported grade 4 gastrointestinal bleeding, grade 2 anemia, and grade 2 aspartate aminotransferase elevation. Another patient in the HAIC group reported spontaneous bacterial peritonitis after the second treatment cycle.

The detailed courses of the individual patients are as follows: one patient in the sorafenib group received medication for 20 days with a strong hope of improvement by treatment but died of pulmonary complications. The other patient in the sorafenib group was a chronic alcoholic whose performance had been impaired by alcohol drinking. The general condition of the patient showed a trend of improvement after abstinence, so we started treatment for HCC. The treatment was discontinued due to disease progression after 70 days. The third patient was diagnosed with HCC after tumor rupture, and started HAIC after emergent hepatic artery embolization. His initially poor performance status improved during treatment as there was no more bleeding event. The treatment was stopped due to the occurrence of lung metastasis after five cycles of HAIC for 124 days. Two months after treatment discontinuation, the patient died of hepatorenal syndrome. The remaining patient was eager to be treated and was started on HAIC treatment with 25% dose reduction. The patient received seven cycles of therapy for 187 days, but the treatment was discontinued owing to disease progression. He died of gastrointestinal bleeding 1 month after treatment discontinuation.

4. Factors related to survival and tumor progression

Using Cox’s proportional hazard model, we investigated the factors related to survival. We evaluated if the treatment modality and solid organ metastasis affected survival. However, no factor was related to survival in the univariate and multivariate analyses of our study population (Table 3).

Table 3.

Multivariable Analysis for Overall Survival and Tumor Progression

Variable Factors associated with
overall survival		 Factors associated with
tumor progression
HR 95% CI p-value HR 95% CI p-value
Age 0.994 0.960–1.029 0.735 1.026 0.995–1.058 0.105
Gender 0.961 0.368–2.508 0.968 0.956 0.407–2.339 0.956
Child-Pugh class 1.958 0.227–16.882 0.541 1.725 0.577–5.156 0.329
Performance status by ECOG 1.341 0.311–5.784 0.694 0.892 0.195–4.082 0.883
Prior treatment 0.655 0.413–1.038 0.072 0.994 0.722–1.367 0.969
Infiltrative tumor 1.024 0.468–2.241 0.953 1.009 0.541–1.882 0.978
Lymph node metastasis 1.050 0.437–2.520 0.913 0.805 0.399–1.626 0.546
Solid organ metastasis 0.804 0.864–10.188 0.084 1.534 0.672–3.501 0.310
Current treatment* 0.470 0.172–1.286 0.141 0.571 0.260–1.252 0.162
AFP >200 ng/mL 1.648 0.724–3.752 0.234 1.936 0.948–3.956 0.070
Combination therapy 2.212 0.821–5.963 0.117 0.972 0.457–2.068 0.941
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HR, hazard ratio; CI, confidence interval; ECOG, Eastern Cooperative Oncology Group; AFP, alpha-fetoprotein; HAIC, hepatic arterial infusion chemotherapy.

*Sorafenib-based or HAIC-based therapy.

We also investigated factors related to tumor progression. Solid organ metastasis and treatment group were significantly related to tumor progression in the univariate analysis. However, no factor was associated with tumor progression after correcting for other factors such as age and gender (Table 3).

5. Safety and adverse events

More patients experienced hematologic adverse events (anemia and thrombocytopenia) in the HAIC group than in the sorafenib group. Dermatologic adverse events (hand-foot syndrome and scrotal erythema) occurred in the sorafenib group. Lethal side effects, such as gastrointestinal bleeding (two patients in the sorafenib group and one patient in the HAIC group) and HCC rupture (two patients in the sorafenib group and one patient in the HAIC group), occurred in both the groups. More constitutional complications occurred in the sorafenib group than in the HAIC group. Catheter-related complications (catheter obstruction and chemoport site infection) occurred in the HAIC group, and appropriate treatments, such as reperfusion and antibiotics, have been undertaken for these patients (Table 4). Adverse events according to the CTP score are described separately in Supplementary Tables 1 and 2.

Table 4.

Adverse Events Related to Treatment

Adverse events Sorafenib-based (n=35) HAIC-based (n=38)
All grades Grade 3&4 All grades Grade 3&4
Hematologic
Neutropenia 1 (2.9) 1 (2.9) 9 (23.7) 4 (10.5)
Anemia 7 (20.0) 1 (2.9) 14 (36.8) 3 (7.9)
Thrombocytopenia 3 (8.6) 0 17 (44.7) 8 (21.1)
Dermatologic
Hand-foot skin reaction 10 (28.6) 3 (8.6) 0 0
Rash 1 (2.9) 0 0 0
Scrotal erythema 1 (2.9) 0 0 0
Gastrointestinal
Dyspepsia/anorexia 9 (25.7) 2 (5.7) 5 (13.2) 1 (2.6)
Nausea/vomiting 7 (20.0) 3 (8.6) 4 (10.5) 0
Diarrhea/constipation 6 (17.1) 2 (5.7) 2 (5.3) 1 (2.6)
Abdominal pain 3 (8.6) 1 (2.9) 2 (5.3) 0
GI bleeding 2 (5.7) 1 (2.9) 1 (2.6) 1 (2.6)
HCC rupture 2 (5.7) 2 (5.7) 1 (2.6) 1 (2.6)
Constitutional
Fatigue 10 (28.6) 5 (14.3) 3 (7.9) 0
General weakness 2 (5.7) 0 3 (7.9) 2 (5.3)
Laboratory
AST elevation 8 (22.9) 8 (22.9) 6 (15.8) 5 (13.2)
ALT elevation 2 (5.7) 1 (2.9) 5 (13.2) 3 (7.9)
Bilirubin elevation 13 (37.1) 6 (17.1) 6 (15.8) 0
PT INR elevation 12 (34.3) 0 6 (15.8) 0
Hyponatremia 1 (2.9) 1 (2.9) 0 0
Complication of liver cirrhosis
Ascites aggravation 2 (5.7) 2 (5.7) 0 0
SBP 1 (2.9) 1 (2.9) 2 (5.3) 2 (5.3)
Hepatic encephalopathy 2 (5.7) 2 (5.7) 1 (2.6) 1 (2.6)
Catheter related complication
Catheter obstruction 0 0 2 (5.3) 1 (2.6)
Chemoport site infection 0 0 4 (10.5) 3 (7.9)
Hepatic artery total occlusion 0 0 1 (2.6) 1 (2.6)
Others
Infection 0 0 4 (10.5) 4 (10.5)
Febrile neutropenia 0 0 1 (2.6) 1 (2.6)
Peripheral neuropathy 1 (2.9) 0 1 (2.6) 0
Dizziness 2 (5.7) 0 1 (2.6) 0
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Data are presented as number (%).

HAIC, hepatic arterial infusion chemotherapy; GI, gastrointestinal; HCC, hepatocellular carcinoma; AST, aspartate aminotransferase; ALT, alanine aminotransferase; PT, prothrombin time; INR, international normalized ratio; SBP, spontaneous bacterial peritonitis.

The main reason for treatment discontinuation was disease progression (17 patients in the sorafenib group vs nine patients in the HAIC group). The other reasons for treatment discontinuation, in the order of frequency, were drug side effects (three patients vs nine patients), chemoport complication (0 patient vs five patients), complications of liver cirrhosis (five patients vs four patients), tumor complication (four patients vs three patients), infection (0 patient vs one patient), hepatic dysfunction (three patients vs three patients), deterioration of general condition (two patients vs two patients), and transfer to other hospitals (one patient vs two patients).

6. Combined therapy and second-line therapy

In the sorafenib group, 29 patients (83%) received sorafenib monotherapy, while six (17.1%) received combination therapy during sorafenib treatment: two patients (5.7%) received treatment combined with transarterial chemotherapy with lipiodol (TACL) and four (11.4%) received treatment combined with 3-dimensional conformal radiotherapy. More patients received combination therapy in the HAIC group. Twelve patients (31.6%) received HAIC monotherapy, while 26 patients (68%) received combined therapy: six patients (15.8%) received treatment combined with TACL, 10 (26.3%) received treatment combined with radiotherapy, nine (23.7%) received treatment combined with TACL and radiotherapy, and one (2.6%) received treatment combined with radiotherapy and percutaneous ethanol injection therapy on PVTT.

In the sorafenib group, 28 patients (80%) did not receive second-line therapy after cessation of sorafenib, while seven patients (20%) received second-line therapy: systemic cytotoxic chemotherapy (n=6; 16.9%) and TACL (n=1; 2.9%). In the HAIC group, 31 patients (82%) did not receive second-line therapy, while seven patients (18.4%) received second-line therapy: systemic cytotoxic chemotherapy (n=1; 2.6%), TACL (n=4; 11%), and sorafenib (n=2; 5.3%).

DISCUSSION

The prognosis of patients with advanced HCC is poor, especially if there is a main PVTT, which is found in 10% to 40% of patients first diagnosed with HCC.21-23 In patients with PVTT, an extrahepatic metastasis is often detected at diagnosis, resulting in fewer treatment options.21-23 OS is shorter in HCC patients with PVTT than in those without PVTT. Previous studies have shown that OS is only 2 to 4 months with supportive care in HCC patients with PVTT, which is much shorter than the 10 to 24 months in HCC patients without PVTT.22-24 According to the Barcelona Clinic of Liver Cancer staging system, HCC with PVTT is classified as an advanced stage, and sorafenib is recommended as the first-line option.1 However, survival advantages were not high when sorafenib was administered; the OS was 6 to 10 months.3,4 In addition, the initial results of the study were mainly targeted to patients with favorable residual liver function (Child-Pugh class A) and good performance status (ECOG 0-1). Therefore, sorafenib is less effective in real practice.25

In the presence of a main PVTT, tumors in the liver are often progressed and intrahepatic metastasis to the opposite lobe can occur quickly.26 Hence, it is important to control tumors in the liver. HAIC is designed to reduce the systemic side effects of chemotherapy agents and to maximize tumor control by administering high concentrations of anticancer drugs to hepatic tumors. Although HCC does not respond well to conventional anticancer drugs, the infusion of relatively large amounts of chemotherapeutic agents will enhance anti-tumor responses, even in patients with marginal liver function, and avoid ischemic complications of transarterial therapy because it does not require hepatic arterial embolization.16,27,28 However, more data on these HCC patients with PVTT may be required. In addition, only a few studies have directly compared the efficacy of sorafenib and HAIC.29,30 Therefore, this study compared the effects of sorafenib and HAIC in patients with similar liver function and performance status.

A total of 73 patients were retrospectively examined. Chronic HBV infection was the most common cause of underlying liver disease. The proportion of Child-Pugh class B patients was one-third, which suggests that more patients with decreased liver function were included compared with that in previous studies. The proportion of patients with ECOG 2 or 3 was also one-third. Owing to the retrospective design, there was a difference between the two treatment groups. Solid organ metastasis was more common in the sorafenib group than in the HAIC group. Therefore, we performed subgroup analysis excluding patients with extrahepatic metastasis, and the results were consistent.

The final therapeutic response was mostly progressive disease, which agrees with findings of previous studies.3,6,12-15 In the HAIC group, one complete response was achieved, although the number was negligible. DCR was compared between the groups according to the best response during the treatment period, and the results were better in the HAIC group than in the sorafenib group. The median OS was 6.9 months in the sorafenib group and 11.1 months in the HAIC group, but there was no significant difference between groups, although patients in the HAIC group tended to have longer OS. However, the median TTP was significantly longer in the HAIC group than in the sorafenib group. In the additional subgroup analyses, a trend toward favoring HAIC therapy was observed in patients with Child-Pugh class B in terms of OS and TTP, albeit statistical significances were not demonstrated. HAIC was relatively tolerable in two patients with an ECOG performance status of 3.

Although patients treated with HAIC-based therapy experienced more hematologic toxicity, the complications were mostly manageable. Sorafenib-based therapy was more often related to dermatologic toxicity (34%, all grades) and thus required dose adjustment.

As this study was performed based on real practice, we acknowledge that patients in the HAIC group had more chance of receiving combined treatment such as radiotherapy. According to the medical insurance reimburse guidelines in Korea, sorafenib has not been allowed to combine other locoregional therapies. This situation may have influenced the outcomes regarding objective tumor responses. However, in the further sub-analysis, no significant differences in OS and TTP were found between the monotherapy and combination therapy when the sorafenib monotherapy and sorafenib-based combination therapy groups and the HAIC monotherapy and HAIC-based combination therapy groups were compared. Therefore, further research is needed to determine the strategy for combination therapy for advanced HCC.

However, even considering these factors, HAIC-based therapy should be an alternative to sorafenib therapy in patients who cannot tolerate or afford sorafenib because HAIC-based treatment is 5 to 10 times less costly.

Currently, there are newer treatment options for advanced HCC patients, such as lenvatinib, which demonstrated non-inferior efficacy to sorafenib.31 Furthermore, second-line therapies are available using new molecular targeting therapies including regorafenib and cabozantinib, which showed survival benefits after sorafenib failure.32,33 However, most of these drugs were tested in patients with well-reserved liver function and good performance status, similar to the sorafenib trials. Hence, these drugs should also have limited applicability in real practice. Thus, we need to consider the utility of HAIC treatment even in the era of molecular target therapy. However, because the patients in this study did not receive second-line therapy with these new agents, further investigation is necessary.

This study had several limitations, including the non-randomized, retrospective design and relatively small number of patients. However, we found that advanced HCC patients with or without extrahepatic metastases showed better DCR and longer TTP with HAIC than with sorafenib treatment. Furthermore, OS tended to be longer in the HAIC group than in the sorafenib group, although statistical significance was not observed. Another limitation is the non-inclusion of newer therapies as second-line therapy. Unfortunately, these therapies were not available in Korea during the study period.

In conclusion, HAIC-based therapy may be an alternative treatment option to sorafenib for advanced HCC with main portal vein thrombosis and may result in favorable DCR in patients with or without solid organ metastasis.

Supplemental Materials

gnl-15-2-284-supple.pdf (37.3KB, pdf)

ACKNOWLEDGEMENTS

This project was funded by the Korea University Research Grant.

The authors are grateful to Prof. Jaehyung Cha at Department of Biostatistics, Korea University for analyzing the data set.

Footnotes

CONFLICTS OF INTEREST

No potential conflict of interest relevant to this article was reported.

AUTHOR CONTRIBUTIONS

Study design: H.J.Y. Data acquisition: E.L.Y., T.H.K., Y.S.L., S.Y.Y., H.R.K., S.H.K., Y.K.J., J.H.K., J.E.Y., S.H.U., K.S.B., H.J.Y., Y.S.S. Data analysis: Y.E.A., S.J.S. Funding: H.J.Y. Drafting of the manuscript: Y.E.A., S.J.S., H.J.Y. Reviewing the manuscript: E.L.Y., T.H.K., Y.S.L., S.Y.Y., H.R.K., S.H.K., Y.K.J., J.H.K., J.E.Y., S.H.U., K.S.B., H.J.Y. Critical revision of the manuscript: Y.S.S. Overall project management: H.J.Y. Approval of final manuscript: all authors.

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Associated Data

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Supplementary Materials

gnl-15-2-284-supple.pdf (37.3KB, pdf)

Articles from Gut and Liver are provided here courtesy of The Korean Society of Gastroenterology, the Korean Society of Gastrointestinal Endoscopy, the Korean Society of Neurogastroenterology and Motility, Korean College of Helicobacter and Upper Gastrointestinal Research, Korean Association for the Study of Intestinal Diseases, the Korean Association for the Study of the Liver, the Korean Society of Pancreatobiliary Disease, and the Korean Society of Gastrointestinal Cancer

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