Introduction
Hepatocellular carcinoma (HCC), the third leading
cause of cancer-associated mortality worldwide, is characterized by
poor prognosis and low long-term overall survival (1). Hepatitis B virus (HBV) infection is a
well-documented risk factor for hepatocarcinogenesis, and ~90% of
patients with HCC in China have chronic HBV infection and
concomitant reduced liver function (2,3).
Therefore, the prognosis of patients with HBV-associated HCC
depends on both tumor status and HBV activity.
Hepatectomy remains the standard curative treatment
for HCC, however, postoperative tumor recurrence is notbaly high,
with 5 year rates as high as 74% for patients with disease in the
intermediate or advanced stages (2).
Disease-free survival is similarly low, with 5 year rates of 26%
for patients with large/multinodular HCC and 18% for those with
macrovascular invasion (3). Tumor
recurrence is the most frequent cause of mortality in patients with
HCC. Therefore, identifying postoperative therapies that reduce the
risk of tumor recurrence is essential.
Risk factors of HCC recurrence
HCC recurrence can be classified as early, occurring
<2 years after surgery, and late, occurring >2 years after
surgery. Early recurrence is predominantly due to intrahepatic
metastasis arising from the primary tumor, while late recurrence
results primarily from de novo (multicentric) metastasis.
Risk factors of early recurrence are associated with the HCC itself
and include tumor size and number, tumor differentiation, vascular
invasion, tumor capsule and resection margin (4,5). By
contrast, risk factors of late recurrence are associated with
remnant liver tissue and include high viral load and hepatic
inflammatory activity (4,5).
These different recurrence mechanisms mean that
clinicians must carefully consider each patient's risk factor
profile following hepatectomy in order to design a treatment
strategy that targets both types of recurrence. Although official
HCC treatment guidelines do not definitively recommend adjuvant or
antiviral therapies for patients with HBV-associated HCC following
hepatectomy (6,7), increasing evidence supports their
clinical use (8–10).
Indications for adjuvant transarterial
chemoembolization
The goal of adjuvant transarterial chemoembolization
(TACE) is to destroy small intrahepatic metastases that may not
have been detected during surgery, as well as to eliminate tumor
cells that may have been released during surgical manipulation of
the liver (11). Adjuvant TACE
appears to benefit only patients with HCC at high risk of early
recurrence, including patients with multiple nodules, large tumors,
vascular invasion, poor tumor differentiation, incomplete or absent
tumor capsule, or a resection margin <1 cm. The idea that only
high-risk patients benefit from adjuvant TACE is supported by
retrospective studies (12,13) and a meta-analysis based on randomized
studies (14). This meta-analysis,
which included six randomized trials involving 659 patients with
HCC at a high risk of recurrence, revealed that adjuvant TACE
decreased 1- and 3 year mortality, however, not 5 year mortality
rates (14). One retrospective study
(15) involving 1,924 patients with
HCC following curative hepatectomy found that adjuvant TACE
improved overall survival in patients with tumors >5 cm, who
also had other risk factors, including 2–3 nodules or microvascular
invasion. However, adjuvant TACE actually reduced the overall
survival of patients with a single tumor <5 cm without
microvascular invasion. This lack of clinical benefit was confirmed
in a more recent retrospective study (16) involving 229 patients with HCC lacking
factors associated with elevated risk of recurrence or reduced
overall survival. Adjuvant TACE did not improve the overall
survival or reduce recurrence.
Indications for nucleos(t)ide analog (NA)
therapy after hepatectomy
Postoperative antiviral therapy with NAs is another
therapy commonly used following hepatectomy in patients with
HBV-associated HCC (17,18). The goal of postoperative antiviral
therapy in HBV-associated HCC is to reduce the viral load of HBV,
protect liver function, decrease tumor recurrence, increase overall
survival and improve quality of life. The only two randomized
trials (19,20) that we identified in literature
searches, as well as large cohort studies (18,19,21)
examining NA therapy, found that it significantly reduced late HCC
recurrence and improved long-term overall survival in patients with
HBV-associated HCC following curative hepatectomy. However, the
therapy fails to provide obvious clinical benefits for reducing
early tumor recurrence or improving short-term overall survival
(18–21). This may reflect the fact that the
majority of patients in these trials (19,20) were
in the early stages of HCC. A longer follow-up of these patients
suggested certain clinical benefit. The available evidence,
therefore, suggests that postoperative NA therapy affects primarily
late recurrence, and it does so by controlling hepatitis activity
and reducing chronic inflammation in the remnant liver.
Since numerous patients in advanced stages of HCC
exhibit high rates of early recurrence and low long-term overall
survival, postoperative NA therapy is likely to be more effective
in patients with early-stage HCC following curative hepatectomy.
Indeed, this indication is supported by subgroup analyses in
retrospective studies (22–24), which showed that postoperative NA
therapy can significantly improve disease-free and overall survival
in patients in relatively early stages of HCC. However, no
significant clinical benefit was observed for those in relatively
late stages of HCC (Table I).
 | Table I.Previous studies evaluating
postoperative antiviral therapy and survival, stratified by tumor
stage. |
Table I.
Previous studies evaluating
postoperative antiviral therapy and survival, stratified by tumor
stage.
|
| Disease-free
survival | Overall survival |
|
|---|
|
|
|
|
|
|---|
| Author | Sample size
(T/C) | Liver function (T),
A/B | Drug used | Early stage HCC | Late stage HCC | Early stage HCC | Late stage HCC | (Refs.) |
|---|
| Chan et al,
2011 | 42/94 | 42/0 | Lamivudine (100 mg/d)
or entecavir (0.5 mg/d) | P=0.04a or 0.04b | P=0.84c or 0.58d | P=0.02a or 0.004b | P=0.10c or 0.97d | (22) |
| Ke et al,
2013 | 141/337 | 141/0 | Lamivudine (100
mg/d) | – | – | BCLC A/B stage:
P=0.035 | BCLC C stage:
P=0.775 | (23) |
| Zhang et al,
2014 | 40/47 | 33/6 | Entecavir (0.5
mg/d) | Tumor size ≤3:
P=0.006 | Tumor size >3:
P=0.209 | Tumor size ≤3:
P=0.184 | Tumor size >3:
P=0.246 | (24) |
Feasibility of adjuvant TACE combined with
NA therapy
These considerations highlight the fact that the
indications for adjuvant TACE differ from those for postoperative
NA therapy in certain respects. This is important to take into
consideration when treating patients with HBV-associated HCC
following hepatectomy, particularly since the two therapies are the
ones most frequently administered to such patients in HBV-endemic
areas (25,26). This raises the question of whether the
two therapies can be combined for an improved prognosis. Systematic
searches of PubMed, EMBASE, the Cochrane Library revealed two small
retrospective studies (27,28) investigating the efficacy of adjuvant
TACE combined with antiviral therapy for HBV-associated HCC
following hepatectomy. The first retrospective study (27) involved 60 patients, of whom 41
received both therapies and 19 received only TACE. The two groups
exhibited similar 1, 2 and 3 year recurrence rates. The other study
(28) included 176 patients with
Child-Pugh A liver function, of whom 58 received combination
therapy and 118 received TACE alone. The two groups exhibited
similar disease-free survival (P=0.322), however, the combination
group revealed a marginally improved overall survival (P=0.048).
However, when analyses were performed with 51 pairs of propensity
score-matched patients, the combination group exhibited
significantly higher overall survival (P=0.033) and marginally
higher disease-free survival (P=0.048). The authors concluded that
the combination of adjuvant TACE and NA therapy may prevent HCC
recurrence and improve the overall survival following curative
hepatectomy (28).
The optimal indications for combined adjuvant TACE
and NA therapy remain to be elucidated (29). The two retrospective studies (27,28)
mentioned above included patients with advanced-stage HCC, and no
subgroup analyses based on tumor stage were performed (27,28). Based
on the indications for adjuvant TACE or postoperative NA
monotherapy on their own, patients who have HBV-associated,
relatively early-stage HCC and who are at high risk of recurrence
may be the most suitable candidates for the two therapies combined.
Adjuvant TACE is not, however, recommended for patients who have
early-stage HBV-associated HCC and who lack risk factors of
recurrence (15,16). Combination therapy may also be
appropriate for patients with HBV-associated HCC in advanced
stages. Although postoperative NA therapy in such patients may not
significantly prolong their survival (22–24), it
can decrease the rate of HBV reactivation and improve liver
function (30,31). Two previous studies suggested that the
combination of TACE and NA therapy in such patients can lead to
significantly higher overall survival compared with TACE alone
(32,33).
Physicians and patients must weigh the pros and cons
of treatment options, including associated costs, for managing
HBV-associated HCC following hepatectomy. Long-term treatment with
NAs will be expensive. Additionally, drug resistance and side
effects must also be determined. The most extensive evidence must
also be taking into consideration, since future studies may change
the picture presented here.
Future perspective
Several international guidelines already recommend
antiviral therapy for patients with chronic HBV, however, no
standardized international guidelines exist regarding postoperative
antiviral therapy for patients with HBV-associated HCC following
hepatectomy at present. In general, the clinical practice of
antiviral therapy in HBV-associated HCC is based on the management
of chronic hepatitis B. The primary goal of antiviral therapy with
NAs is to continuously suppress virus replication in order to
prevent progression of fibrosis and cirrhosis, and thereby reduce
the incidence of liver failure and HCC recurrence. Postoperative
antiviral therapy with NAs not only improves liver function, but
also reduces the incidence of HBV reactivation and long-term tumor
recurrence. The net result is an increase in long-term overall
survival. While it is possible that patients at any stage of
HBV-associated HCC can benefit from postoperative NA therapy, the
precise indications and contradictions of this treatment, as well
as the optimal drugs and doses, remain to be clarified. Future
studies must elucidate how postoperative NA therapy prevents tumor
recurrence and improves overall survival.
No international guidelines definitively recommend
adjuvant TACE for patients with HCC following hepatectomy, however,
evidence is mounting to suggest a clinical benefit to patients at
high risk of recurrence. The present review concluded that, on the
basis of existing evidence, the most suitable candidates for
adjuvant TACE combined with antiviral NA therapy are patients who
exhibit HBV-associated HCC and are at a high risk of
recurrence.
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