• OPEN ACCESS

A Review of Non-operative Treatments for Hepatocellular Carcinoma with Advanced Portal Vein Tumor Thrombus

  • Michihisa Moriguchi*,
  • Mitsuhiro Furuta and
  • Yoshito Itoh
 Author information
Journal of Clinical and Translational Hepatology 2017;5(2):177-183

DOI: 10.14218/JCTH.2016.00075

Abstract

Portal vein tumor thrombus (PVTT) frequently occurs with the progression of hepatocellular carcinoma (HCC) and is an important factor in determining the prognosis of HCC. In many cases of HCC with advanced PVTT, treatment is difficult because the tumor has considerable extension into the liver, and portal hypertension is a frequent complication. The standard therapy for unresectable HCC with advanced PVTT is sorafenib therapy in patients with good hepatic function. However, the outcomes of sorafenib therapy are not completely satisfactory, making the development of another therapy an urgent task. Therefore, this review aims to summarize non-operative treatments for HCC with advanced PVTT and discuss future perspectives based on those therapies, including therapies still being developed.

Keywords

Hepatocellular carcinoma, Medical therapy management, Portal vein, Thrombus

Introduction

Hepatocellular carcinoma (HCC) is the world’s fifth most common cancer and typically has a background of chronic hepatitis or cirrhosis.1 Portal vein tumor thrombus (PVTT) is frequently seen in the clinical course of HCC, occurring in 44–62.2% of cases according to past reports.2,3 In cases of HCC with PVTT, the tolerability of patients to therapy is low because their tumors are generally aggressive, their hepatic function is poor, and there is a high rate of complications from portal hypertension. The prognosis of HCC with advanced PVTT is extremely poor, resulting in a median survival time of 2–4 months without treatment.4–6 It was recently reported that PVTT extension in hepatitis B virus-related HCC involves genetic abnormalities of KDM6A, CUL9, FDG6, AKAP3, RNF139, etc.7

Recently, a report was published stating that Vp1–3 (Japanese VP Staging Classification System)8,9 patients who underwent successful R0 or R1 resection had moderate outcomes, indicating the usefulness of surgical resection.10 However, non-operative treatment is the only available means in many cases in actual clinical practice because surgical resection is difficult in bilobar and multifocal cases and in patients with poor hepatic function.

Non-operative treatments include transarterial chemoembolization (TACE), transarterial radioembolization (TARE), hepatic arterial infusion chemotherapy (HAIC), sorafenib therapy, and radiotherapy (RT). Combinations of these treatments have also been attempted to improve outcomes. However, treatment outcomes for unresectable HCC with PVTT are not satisfactory. Particularly, management for advanced PVTT such as Vp3 (extension to the first-order branch)/Vp4 (extension to main trunk/contralateral branch) HCC with poor prognosis has room for discussion. Therefore, this review aims to discuss non-operative treatment for Vp3/Vp4 HCC, i.e. HCC with advanced PVTT, based on recent data.

PVTT classifications

Severity of PVTT is closely correlated with prognosis of HCC with PVTT.10 The Japanese VP Staging Classification System and the Eastern Hepatobiliary Classification (also known as Cheng’s Classification)11,12 can stratify HCC with PVTT.

In the Japanese VP Staging System, Vp4, Vp3, Vp2 and Vp1 are categorized as an extension to the main trunk/contralateral branch, first-order branch, second-order branch and third-order branch, respectively (Fig. 1). The median survival times (MSTs) after diagnosis of PVTT stratified by severity has been reported as 2.67 years (95% CI 2.48–3.01) for Vp1, 1.51 years (95% CI 1.36–1.65) for Vp2, 0.78 years (95% CI 0.70–0.83) for Vp3, and 0.50 years (95% CI 0.45–0.56) for Vp4,10 indicating a very poor prognosis for patients with Vp3 and Vp4. Vp3 and Vp4 are equivalent to types II/III (extension to the main trunk) and IV (extension to superior mesenteric vein) by Cheng’s Classification, respectively (Fig. 1).

Classification of hepatocellular carcinoma with portal vein tumor thrombus.
Fig. 1.  Classification of hepatocellular carcinoma with portal vein tumor thrombus.

Vp and Roman numerals express Japan’s VP classification and Cheng’s classification, respectively. Vp4, Vp3, Vp2 and Vp1 are categorized as an extension to the main trunk/contralateral branch, first-order branch, second-order branch, and third-order branch, respectively. Abbreviations: Ant, anterior branch; LHV, left portal vein; RPV, right portal vein; Seg, segmental branch; SMV, superior mesenteric vein; SpV, splenic vein.

TACE

TACE was developed by Yamada et al.13 in 1977 and has since been widely used to treat unresectable HCC. TACE is based on the following theories: The embolization of the hepatic artery leads to necrosis of the classical HCC fed by only the hepatic artery, on the other hand, the surrounding liver parenchyma would not result in infarction because it is fed predominantly by both the artery and the portal vein.13

A simultaneous combination of embolization with an anticancer agent is thought to enhance tumor necrosis through long-term retention of a high concentration of the agent in the tumor.

TACE for HCC with PVTT is likely contraindicated because of the theoretical concern for hepatic insufficiency caused by hepatic ischemia. However, recent studies have reported that TACE can be safely performed if the patient has good liver function and sufficiently developed collateral circulation around the occluded portal vein. Perioperative mortality of TACE and the incidence of TACE syndrome (post-embolization syndrome) have been reported to be below 1.2% and 28.9–94%, respectively (Table 1).14,15

Table 1.

Transarterial embolization for hepatocellular carcinoma with advanced portal vein tumor thrombus

AuthorRefTreatmentDegree of PVTT; nMedian survival time; monthsAdverse event; n/total or %
Chung14c-TACEMain; 83Main; 5.6Morbidity; 28.9%
Gastro-intestinal bleeding due to portal hypertension; 4.8%
Bacteremia (SBP); 6% (1.2%)
Renal failure; 1.2%
Niu16c-TACEType II; 52
Type III; 42
Type IV; 9
Type II; 11.0
Type III; 7.1
Type IV; 4.0
Unclear in detail
Luo17c-TACEMajor; 44 (all; 84)Major; 5.4Post-embolization syndrome (79/84)
Temporary liver decompensation (29/84)
One-month mortality 1.2%
Kalva20DEB-TACEAdvanced-stage; 80 (with PVTT only 12.5%)Gr3 AST/ALT elevation 15%
Favorable tolerant and safe
Sangro21TAREMain; 32 (9.8%)
Branch; 44 (13.5%)
Main; 9.7
Branch; 10.7
All-cause mortality at 30 and 90 days; 0.6% and 6.8%
Gr3 gastrointestinal ulceration; 1.5%
Gr3 or above Bil increase at month 3; 5.8%
Memon22TAREMain; 29
lobar; 34
(Child-Pugh A)
Main; 9.0
Lobar; 15.7
Unclear in detail
Mazzaferro23TARESecond-first branch; 29
Trunk-SMV; 6
Second-first branch; 17
Trunk-SMV; 9
No significant difference in toxicity (PVTT vs non-PVTT)

Niu et al.16 (Table 1) reported the usefulness of TACE for HCC with PVTT based on their prospective study. The MSTs of type II (Vp3) patients in the TACE and conservative arms was 11.0 and 1.43 months, respectively, and the MSTs of type III/IV (Vp4) patients in those arms was 7.1/4.0 and 1.3/1.0 months, respectively, (p < 0.01) in the sub-analysis. Luo et al.17 (Table 1) reported that the TACE arm had a significantly longer survival time than the conservative treatment arm in their prospective study, and adverse events in the study could be managed sufficiently. They reported that in their sub-analysis, the MST of even the patients with major PVTT in the TACE arm was 5.4 months, significantly longer than the 3.4 months of the conservative arm (p = 0.002). Chung et al.14 reported the safety and usefulness of TACE for Vp4 HCC. The TACE group had a significantly longer survival time than the supportive care group (MST: 5.6 months vs. 2.2 months, p < 0.001). In particular, the cases classified as Child-Pugh A had an MST of 7.4 and 2.6 months in the TACE and supportive care groups, respectively, significantly longer in the TACE group (p < 0.001). There was no treatment-related death within 4 weeks after TACE, and the incidence of adverse events was 28.9%. Although no significant difference was detected in the incidence of adverse events between the TACE and supportive care groups, complications such as gastrointestinal hemorrhage with secondary portal hypertension developed more frequently in the TACE group.14

From these results, it is likely that for Child-Pugh A cases and cases with well-developed collateral circulation around the occluded portal vein, TACE is an acceptable treatment for HCC with PVTT. However, the outcomes of TACE for Vp4 HCC are not fully satisfactory; therefore, it is important to compare those with the outcomes of other therapies.

Regarding embolic agents, those with a small particle diameter have been reported to have a higher antitumor effect and to cause less adverse events.18,19 Therefore, TACE using drug-eluting beads (DEB) is expected to be more effective than conventional TACE, in which embolization employs a gelatin sponge after arterial infusion of an emulsion of lipiodol and an anticancer agent. Although Kalva et al.20 (Table 1) reported the safety and usefulness of DEB-TACE for HCC with PVTT, there have been few definite reports on DEB-TACE for HCC with PVTT. This should be investigated in the future.

TARE

TARE is a treatment in which radioactive microspheres are injected into the tumor through its feeder artery, aiming for an embolic effect and radiotherapy. Contrary to TACE, complete embolization is not the technical endpoint of this treatment. For this reason, TARE has a weaker embolic effect and therefore can be more easily utilized for HCC with PVTT from the standpoint of hepatic function. A few reports have indicated the usefulness of yttrium-90 microspheres radiating beta rays for HCC with PVTT. Sangro et al.21 (Table 1) reported that TARE is a well-tolerated treatment, based on the severity and incidence of adverse events seen in TARE for main PVTT and branch PVTT (MSTs of 9.7 and 10.7 months, respectively). However, grade 3 or higher bilirubin levels were seen in 5.8% of patients within 3 months after the therapy, which could be due to hepatic dysfunction but were also likely due to the tumor progression or the exacerbation of the background liver disease such as cirrhosis. Memon et al.22 (Table 1) reported that the MST of the patients with Child-Pugh A disease and lobar PVTT/main PVTT who underwent TARE was 15.7/9 months. Mazzaferro et al.23 (Table 1) reported that in their phase II trial, the MST of patients with Child-Pugh A disease and first-branch/second-branch PVTT was 17 months, and the MST of patients with portal trunk-superior mesenteric vein PVTT was 9 months, showing relatively good outcomes.

Regarding adverse events, TARE is generally well tolerated. The most frequent adverse event is post-embolization syndrome (malaise, fever, nausea, abdominal pain, etc), which is seen in approximately 20–55% of patients, but can usually be managed with conservative therapy. Other adverse events that have been reported include hepatic disorder, pneumonitis, cholecystitis, bile duct stenosis, hepatic abscess, and gastrointestinal ulceration as a result of radiation, but their incidence is low.24–26

HAIC

Theoretically, HAIC should be more effective than systemic chemotherapy and reduce adverse events because it allows for injection of a high concentration of an anticancer agent directly through the feeder artery. HAIC includes hepatic arterial infusion chemotherapy by means of a port-catheter system, in which an anticancer agent is repeatedly injected after implantation of the port-catheter system and a one-shot intra-arterial infusion of chemotherapy through a catheter inserted by the Seldinger technique. Regimens using cisplatin (CDDP) and 5-fluorouracil (5-FU) as key drugs, as well as regimens using 5-FU and interferon (IFN) as key drugs, have been used in many of the reported cases for which hepatic arterial infusion chemotherapy using a port-catheter system was employed. Using low-dose 5-FU plus CDDP (LFP) for Vp3/Vp4 HCC, Ando et al.27 (Table 2) reported a response rate of 48% and an MST of 10.2 months. The most common adverse events were nausea and loss of appetite, and these were controllable with medical treatment. In 13% of the cases, treatment was discontinued because of deterioration of hepatic function, but the authors did not mention whether this deterioration was due to the tumor progression, the exacerbation of the background liver disease or technique/treatment. They did report that malfunction of the port-catheter system and/or its implantation accounted for more than 20% of the complications. Obi et al.28 (Table 2) reported that the outcomes of IFN and 5-FU combination therapy for Vp3/Vp4 HCC were a response rate of 52.6%, an MST of 6.9 months, and a 1-year survival rate of 34%. The majority of adverse events were negligible, while depression caused by IFN was the only adverse event of grade 3 or higher, which occurred in a patient for whom the treatment was discontinued. No catheter-related complications were found.

Table 2.

Hepatic arterial infusion chemotherapy for hepatocellular carcinoma with advanced portal vein tumor thrombus

AuthorRefTreatmentDegree of PVTT; n/totalMST, TTP in monthsORR, DCR; %Adverse event; % or n
Ando27LFPVp2/3; 14/3410.2ORR; 48
DCR; 77
Any grade
 nausea, appetite loss; 34%
 Peptic ulcer; 13%
 Deterioration of hepatic function; 13%
 Catheter obstruction; 10%
Obi285-FU with IFN s.cVp3; 88
Vp4; 28
6.9ORR; 52.6
DCR; 54.3
Gr3
 Stomatitis; 1
 Depression; 1
Ikeda29cisplatinVp3; 6
Vp4; 19
7.1ORR; 28
DCR; 72
Gr3
 Leukocytopenia; 5
 Thrombocytopenia; 4
 AST elevation; 10
 ALT elevation; 5

With regard to the one-shot intra-arterial infusion, we found some reports regarding intra-arterial CDDP infusion. Ikeda et al.29 (Table 2) reported that the outcomes of their phase II prospective trial of intra-arterial CDDP infusion for Vp3/Vp4 HCC were a response rate of 28% and an MST of 7.1 months. Regarding adverse events of grade 3 or higher, decreased blood cells and transient increases in transaminases were seen but required no special treatment. As stated above, HAIC for Vp3/Vp4 HCC is expected to be effective. However, there is insufficient evidence, as the number of cases in the reports is small.

In recent years, prospective trials have been conducted to verify the efficacy of HAIC as an add-on therapy for sorafenib therapy, the standard therapy for Barcelona clinic liver cancer stage C. In the phase III trial for verification of the efficacy of LFP as this add-on therapy, LFP was shown to be useful for patients with advanced PVTT, although the primary endpoint could not be satisfied.30 Meanwhile, a phase II trial showed the usefulness of one-shot intra-arterial CDDP infusion as an add-on therapy for sorafenib therapy, although no significant difference for patients with PVTT was detected in the sub-analysis.31 A future prospective phase III trial to verify the usefulness of HAIC for Vp3/Vp4 HCC is recommended.

RT

Since the liver is a very radiosensitive organ, administration of considerable doses of radiation to the liver leads to radiation-induced liver disease. Patients with HCC are complicated by a background of chronic liver disease. The presence of background cirrhosis leads to lowering of the tolerable radiation dose of the liver tissue.32,33 Therefore, it is difficult in principle to indicate radiotherapy for patients with poor hepatic function.

In recent years, the number of patients with HCC for whom radiation is indicated has increased. This is because intensive irradiation from multiple directions has enabled a decrease of the dose to normal tissues through the development of three-dimensional radiotherapy regimens, as well as advances in image-guided radiation technology to deal with respiratory fluctuation, allowing enhancement of the antitumor effect and decreasing adverse events.33

Nakazawa et al.34 (Table 3) retrospectively examined the outcomes of sorafenib therapy and RT for Vp4 HCC and reported that their analysis with propensity score matching detected a significantly longer survival time in the RT group compared to the sorafenib group. Decreased white blood cell count in one patient was the only adverse event of grade 3 or higher. Yu et al.35 (Table 3) reported that the outcomes of RT for Vp3/Vp4 HCC were complete regression in 3.6%, partial regression in 50.2%, stable disease in 25.6%, and an MST of 10.6 months, indicating the usefulness of RT.

Table 3.

Radiotherapy for hepatocellular carcinoma with advanced portal vein tumor thrombus

AuthorRefTreatmentDegree of PVTT; nMedian survival time in monthsAdverse event; n
Nakazawa34Three-dimensional conformal RTVp3; 19
Vp4; 9
10.9Gr3 or above
 Leukocytopenia; 1
Yu35Three-dimensional conformal RTHemiliver; 150
Bilateral hemiliver; 4
Main; 114
SMV; 13
11.6Gr3 or above
 Nausea; 1
 AST elevation; 40
 ALT elevation; 15
 ALP elevation; 3
 Clinical liver dysfunction; 15/260
Sugahara36Proton-beamBranch; 15
Trunk; 20
22Gr3 or above
 Leukocytopenia; 1
 Thrombocytopenia; 1

In recent years, we also identified occasional reports involving proton beam therapy for HCC. Proton beams can form an energy peak (Bragg peak) deep inside the body, enabling strong irradiation of the target in the deep site while decreasing irradiation of non-tumor sites. Sugahara et al.36 (Table 3) reported that proton beam therapy for HCC with PVTT resulted in a 2-year local control rate of 91% and a 2-year survival rate of 48%, showing good outcomes. Regarding adverse events, decreased blood cells were the only acute adverse event of grade 3 or higher, occurring in several patients, and no late adverse events of grade 3 or higher were seen.

Sorafenib

Sorafenib is an oral multikinase inhibitor37 and its usefulness for advanced HCC has been demonstrated by two global phase III trials.38,39 Moreover, in the results of the sub-analysis, the MST of patients with macroscopic vascular invasion was 4.9 and 8.1 months in the placebo and sorafenib arms (hazard ratio: 0.68 [0.49–0.93]), respectively, showing that sorafenib prolonged survival time significantly (Table 4).40 Therefore, sorafenib therapy is positioned as the standard therapy for HCC patients with PVTT who have Child-Pugh liver function class A.40

Table 4.

Sorafenib for hepatocellular carcinoma with advanced portal vein tumor thrombus

AuthorRefTreatmentDegree of PVTT; nMST, TTP in monthsORR, DCR; %Adverse event; % or n
Bruix40SorafenibMVI; 108
(details; unclear)
MST; 8.1DCR; 38.9
Jeong41SorafenibVp3; 6
Vp4; 24
TTP; 2.1
MST; 3.1
ORR; 10
DCR; 40
Gr3 or above
 Fatigue; 10%
 HFSR; 3.3%
 Liver dysfunction; 3.3%
Song42SorafenibVp2; 5
Vp3; 16
Vp4; 39
TTP; 2.1
MST; 5.5
ORR; 13.3
DCR; 45.0
Gr3 or above
 HFSR; 7
 Rash; 3
 Diarrhea; 13
 Fatigue; 8

However, Jeong et al.41 (Table 4) reported that sorafenib therapy for Vp3/Vp4 HCC had a response rate of 10%, a disease control rate of 40%, a median time to progression of 2.1 months, and an MST of 3.1 months, which are not satisfactory outcomes. In addition, Song et al.42 (Table 4) reported that the outcomes of sorafenib therapy for Vp2–4 HCC were a response rate of 13.3%, a disease control rate of 44%, a median time to progression of 2.1 months, and an MST of 5.5 months. Sorafenib is the sole non-operative standard treatment for HCC with macroscopic vascular invasion; however, its effect on Vp3/Vp4 HCC may be limited. Although there have been reports on the effect of sorafenib on HCC with PVTT, the studies did not feature sufficient numbers of patients; thus, more data must be accumulated.

Combination treatment

As mentioned above, various attempts have been made to treat HCC with PVTT, but the outcomes of monotherapies are not satisfactory. For that reason, combinations of various therapies have been attempted with the aim of outcome improvement.

Combinations of TACE and RT,43,44 TACE and sorafenib,45,46 sorafenib and RT,47 sorafenib and HAIC,31 HAIC and RT (Table 5),48 and others have been reported. As Table 5 shows, moderately good results have been obtained, but the data remain insufficient. Further investigation with prospective trials is necessary.

Table 5.

Combination therapy for hepatocellular carcinoma with advanced portal vein tumor thrombus

AuthorRefTreatmentDegree of PVTT; n (%)Median survival time in monthsEvaluation; % or nAdverse event; %
Chung43c-TACE+RTMain; 15112ORR; 25.2%30-day mortality; 0.7%
Yoon44c-TACE+RTMain or bilateral PVTT; 200 (48.5%)10.6CR; 3.6%
ORR; 27.9%
Gr3–4 hepatic toxicity; 10%
Gr2–3 gastroduodenal toxicity; 3.6%
Pan45c-TACE+sorafenibVp2; 8
Vp3; 23
Vp4; 10
13CR; 1
PR; 3
SD; 34
Gr3 or above
 HFSR; 7.3%
 Myelosuppression; 2.4%
 Hypertension; 2.4%
Zhu46c-TACE+sorafenibMain; 10
First branch; 19
Second or lower branch; 17
11.0PR; 13
SD; 13
Gr3 or above
 HFSR; 11%
 Diarrhea; 11%
 Hypertension; 4%
 Gastrointestinal hemorrhage; 9%
Chen47RT+sorafenibUnknown in detail; 24 (40%)2-year survival; 32%ORR; 55%Gr3 or above
 hepatic toxicity; 15%
Ikeda31Sorafenib+HAIC (cisplatin)Vp1; 4
Vp2; 9
Vp3; 14
Vp4; 13
9.1*Myelosuppression, hyponatremia, nausea and hiccups were more frequent than in the sorafenib alone treatment
Fujino483D-CRT+HAIC (low-dose 5FU and cisplatin, 5FU with IFN s.c.)Vp3; 18
Vp4; 23
12.1CR; 5%
PR; 24%
SD; 39%
G3 or above
 Leukopenia; 12.2%
 Thrombocytopenia; 14.3%
 AST or ALT elevation; 12.2%
 Bil elevation; 14.3%

Future prospects

With regard to non-operative treatments for HCC with advanced PVTT, not only improvement of monotherapies but also various measures including combinations of different therapies have been attempted. However, a satisfactory outcome has not been reached. Although occasionally some studies obtain promising results, they have insufficient data and require verification with a prospective trial.

Control of PVTT is likely to influence the prognosis of HCC with advanced PVTT. Because the standard therapy, sorafenib, produces a low response rate when administered as systemic chemotherapy, it appears preferable to combine it with local therapy (TACE, HAIC, RT, etc) with the expectation that local control will improve.

Regorafenib has recently been demonstrated to be effective for sorafenib-resistant HCC.49 Going forward, systemic chemotherapy with regorafenib is anticipated to be effective for HCC with advanced PVTT. In addition, systemic chemotherapy will likely require the development of agents with a high response rate against HCC with PVTT. We are awaiting the results of an ongoing phase III clinical trial of lenvatinib (NCT01761266 [E7080]), as well as from trials of immune checkpoint inhibitors (nivolumab [NCT02576509], pembrolizumab [NCT02702401; KEYNOTE-240], etc) that have completely different mechanisms than conventional anticancer agents.

Abbreviations

5-FU: 

5-fluorouracil

CDDP: 

cisplatin

DEB: 

drug-eluting beads

HAIC: 

hepatic arterial infusion chemotherapy

HCC: 

hepatocellular carcinoma

IFN: 

interferon

LFP: 

low-dose 5-FU plus CDDP

MST: 

median survival time

PVTT: 

Portal vein tumor thrombus

RT: 

radiotherapy

TACE: 

transarterial chemoembolization

TARE: 

transarterial radioembolization

Declarations

Conflict of interest

Itoh Y received research grants from Esai Co., Ltd., Merck Sharp and Dohme Co., Ltd., Sumitomo Dainihon Pharma Co., Ltd., Nihon Kayaku Co., Ltd. and Bristol-Myers Squibb Company, and received lecture fees from Esai Co., Ltd., Merck Sharp and Dohme Co., Ltd., Sumitomo Dainihon Pharma Co., Ltd. and Bristol-Myers Squibb Company. Moriguchi M received a research grant from Merck Sharp and Dohme Co., Ltd.

Authors’ contributions

Reviewed, designed and wrote the manuscript (MM), collected the data (MM, MF), revised the manuscript for important intellectual content (MM, YI).

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