Prediction of Post-resection Prognosis Using the ADV Score for Huge Hepatocellular Carcinomas ≥13 cm

Article information

J Liver Cancer. 2021;21(1):45-57
Publication date (electronic) : 2021 March 31
doi : https://doi.org/10.17998/jlc.21.1.45
Department of Surgery, Asan Medical Center, University of Ulsan College of Medicine, Seoul, Korea
Corresponding author: Shin Hwang, Department of Surgery, Asan Medical Center, University of Ulsan College of Medicine, 88 Olympic-ro 43-gil, Songpa-gu, Seoul 05505, Korea, Tel. +82-2-3010-3930, Fax. +82-2-3010-6701, E-mail; shwang@amc.seoul.kr, https://orcid.org/0000-0002-9045-2531
Received 2020 November 19; Revised 2021 January 12; Accepted 2021 January 20.

Abstract

Background/Aims

Multiplication of α-fetoprotein, des-γ-carboxy prothrombin, and tumor volume (ADV score) is a surrogate marker for post-resection prognosis of hepatocellular carcinoma (HCC). This study aimed to validate the predictive power of the ADV score-based prognostic prediction model for patients with solitary huge HCC.

Methods

Of 3,018 patients, 100 patients who underwent hepatic resection for solitary HCC ≥13 cm between 2008 and 2012 were selected.

Results

The median tumor diameter and tumor volume were 15.0 cm and 886 mL, respectively. Tumor recurrence and overall survival (OS) rates were 70.7% and 66.0% at one year and 84.9% and 34.0% at five years, respectively. Microvascular invasion (MVI) was the only independent risk factor for disease-free survival (DFS) and OS. DFS and OS, stratified by ADV score with 1-log intervals, showed significant prognostic contrasts (P=0.007 and P=0.017, respectively). DFS and OS, stratified by ADV score with a cut-off of 8-log, showed significant prognostic contrasts (P=0.014 and P=0.042, respectively). The combination of MVI and ADV score with a cut-off of 8-log also showed significant prognostic contrasts in DFS (P<0.001) and OS (P=0.001) considering the number of risk factors. Prognostic contrast was enhanced after combining the MVI and ADV score.

Conclusions

The prognostic prediction model with the ADV score could reliably predict the risk of tumor recurrence and long-term patient survival outcomes in patients with solitary huge HCC ≥13 cm. The results of this study suggest that our prognostic prediction models can be used to guide surgical treatment and post-resection follow-up for patients with huge HCCs.

INTRODUCTION

Hepatocellular carcinoma (HCC), one of the most common malignancies worldwide, is one of the leading causes of cancer-related death.1 Huge HCCs with maximal tumor diameter greater than 13 cm or tumor volume greater than 1,000 mL are occasionally encountered during the initial diagnosis of a liver mass. Although outcomes of both surgical and non-surgical treatments for huge HCCs are usually unsatisfactory, 2 a small proportion of patients show acceptably favorable outcomes after hepatic resection (HR). Thus, HR is considered the first-line treatment for huge resectable HCCs in patients with preserved hepatic function.36 In patients with huge HCCs, post-resection tumor recurrence is very frequent despite complete tumor resection. Thus, overall patient survival is determined by the curability of HR and subsequent treatment for HCC recurrence, along with the remnant liver functional reserve.3

Considering the very high incidence of early post-resection recurrence in patients with huge HCCs, it is beneficial to discern patients with a low risk of tumor recurrence and a high probability of prolonged survival. We have previously demonstrated that multiplication of α-fetoprotein (AFP), des-γ-carboxy prothrombin (DCP; proteins induced by vitamin K antagonist or absence-II), and tumor volume (TV) (AFP-DCP-TV [ADV] score) is an integrated surrogate marker of post-resection and post-transplant prognosis for HCC.79 The prognostic predictive power of the ADV score is high enough in patients with small- to large-sized HCCs but relatively limited for those with huge HCCs. This study aimed to validate the prognostic impact of the ADV score on patients who underwent resection for solitary huge HCC with a maximal diameter of ≥13 cm.

METHODS

1. Study design and patient selection

This was a single-center retrospective study involving a single arm of patients with solitary huge HCC ≥ 13 cm. HR was preferentially performed for patients with huge HCCs who had resectable tumors and preserved liver function. Our institutional liver cancer surgery database was searched extensively to identify patients who underwent HR for solitary HCC ≥ 13 cm between January 2008 and May 2012. The total number of cases of HR for HCC during the study period was 3,018.10 Only patients who underwent HR with curative intent were included in this study. Patients who did not undergo AFP or DCP measurements within 14 days prior to surgery were excluded as their exact ADV score could not be calculated. Patients with DCP measurements showing high cut-off values such as >2,000, >20,000, or >75,000 mAU/mL were also excluded because of limitations in the quantitative calculation of the ADV score. Of the 3,018 patients, 100 (3.3%) were included as the final study cohort.

The medical records of the included study patients were retrospectively reviewed. Patients were followed up until October 2020 through review of their medical records and with the assistance of the National Health Insurance Service, resulting in a follow-up period of ≥ 100 months or until patient death. The study protocol was approved by the Institutional Review Board at the Asan Medical Center (IRB no. 2019-1347). The requirement for informed consent from patients was waived due to the retrospective nature of this study. This study was performed in accordance with the ethical guidelines of the World Medical Association Declaration of Helsinki 2013.

The primary purpose of this study was to estimate tumor recurrence and patient survival in accordance with the ADV score. The secondary purpose was to determine cut-off values of the ADV score that would be clinically applicable to the resection of huge HCCs.

2. Preoperative evaluation, surgical procedures, and follow–up

Preoperative imaging evaluation for HCC included dynamic abdominal and pelvic computed tomography (CT), chest CT, magnetic resonance imaging, and 2-18F-fluoro-2-deoxy-d-glucose positron emission tomography (FDG-PET) scan. Visual comparison of uptake in the HCC region and surrounding non-tumor liver tissues on FDG-PET scan was performed. If the contour of the tumor was definitely identifiable, it was regarded as a hypermetabolic uptake. The hepatic functional reserve was assessed using an indocyanine green retention rate at 15 minutes and evidence of portal hypertension on imaging and endoscopic studies.

The extent of HR was determined based on the proportion of future liver remnant volume after considering tumor-free resection margins and hepatic functional reserve. Perioperative evaluation, perioperative follow-up, and treatment for tumor recurrence have been described previously.3,79,1113

3. Calculation of ADV score

Blood concentrations of AFP and DCP were measured during preoperative assessment. The upper normal ranges of AFP and DCP at our institution were 7.5 ng/mL and 40 mAU/mL, respectively. As huge HCCs are often not spheroid in shape, the TV was calculated using pathology report data with a formula to measure the volume of an ellipsoid mass as “(4/3)×π×a×b×c” (a, b, and c are semi-axes). Multiplication of AFP (ng/mL), DCP (mAU/mL), and TV (mL) indicates the ADV score, which is expressed on a logarithmic scale (log10 is simply presented as log).7

4. Statistical analysis

Continuous variables were analyzed using the Student’s t-test or Mann-Whitney U test. Incidence variables were compared using the chi-square test or Fisher’s exact test. Survival curves were estimated using the Kaplan-Meier method and compared using the log-rank test. Cox proportional hazard regression analysis was used to obtain the hazard ratio and 95% confidence interval. Harrell’s concordance index (c-index) was used for the quantitative assessment of prediction accuracy. A P-value<0.05 was considered to indicate a statistically significant difference. Statistical analyses were performed using SPSS version 22 (IBM Corp., New York, NY, USA) and Stata version 15 (Stata Corp., College Station, TX, USA).

RESULTS

1. Clinical features of patients

The clinical and pathological features of all 100 study patients are summarized in Table 1. Hepatitis B virus (HBV) infection was present in 77 (77.0%) patients. Thirteen (13.0%) patients had a history of treatment for HCC before HR, including transarterial chemoembolization (TACE)/radioembolization with or without other treatment modalities in 10 patients and systemic chemotherapy in three patients. Preoperative right portal vein embolization for right hepatectomy was performed in three (3.0%) patients. Preoperative laboratory examinations showed median values of 1,300 ng/mL (range, 1.2–1,420,000) for AFP and 9,080 mAU/mL (range, 16–101,073) for DCP. The FDG-PET study showed hypermetabolic uptake in 73 (84.9%) of 86 patients.

Clinicopathological features of the study patients (n=100)

2. Operative and pathological findings

Extents of HR are summarized in Table 2. R0 and R1 resections were performed in 88 (88.0%) and 12 (12.0%) patients, respectively. The median tumor diameter was 15.0 cm (range, 13.0–24.5 cm) and median TV was 886 mL (range, 452–3,385 mL) (Fig. 1). Pathological studies revealed microvascular invasion (MVI) in 73 (73.0%) patients, macrovascular invasion in 18 (18.0%) patients, satellite nodules in 25 (25.0%) patients, and liver cirrhosis in 28 (28.0%) patients (Table 1). In the 10 patients who underwent TACE preoperatively, none showed tumor necrosis of more than 50%.

Extents of hepatic resection

Figure 1

Comparison of preoperative computed tomography (CT) scan, resected right liver specimen, and CT scan taken 3 months after hepatic resection in patients who underwent right hepatectomy. The maximal tumor diameters were 13 cm (A), 17 cm (B), and 20 cm (C).

3. Tumor recurrence and patient survival

One patient died during the first month after HR due to sepsis. Thus, the 1-month perioperative mortality rate was 1.0%. Seven patients died during the first 3 months, with an overall 3-month mortality rate of 7.0%. During the follow-up period of more than 100 months, tumor recurrence was identified in 84 patients. Prognostic analysis indicated that the cumulative 6-month, 1-year, 3-year, and 5-year tumor recurrence rates were 59.1%, 70.7%, 82.6%, and 84.9%, respectively (Fig. 2A). All-cause death was observed in 78 patients. The 6-month, 1-year, 3-year, and 5-year overall survival (OS) rates were 85.0%, 66.0%, 49.0%, and 34.0%, respectively (Fig. 2B).

Figure 2

Kaplan-Meier estimation of post-resection tumor recurrence (A) and overall patient survival (B).

The sites of the first tumor recurrence were intrahepatic in 61 (72.6%) patients, extrahepatic in 19 (22.6%) patients (lung in 13, bone in 3, adrenal gland in 2, peritoneum in 1), and multiple intrahepatic and extrahepatic in four (4.8%) patients. The lung was the most frequent initial extrahepatic metastatic site (n=13). Every available locoregional treatment was performed according to the sites and patterns of tumor recurrence. However, seven patients received only the best supportive care due to worsened general conditions and/or rapid tumor progression. Due to suboptimal responses of locoregional treatments for tumor recurrence, 35 (41.7%) patients finally underwent systemic chemotherapy, including sorafenib and other chemotherapeutic agents.

4. Risk factor analysis for tumor recurrence and patient survival

Results of univariate and multivariate analyses for tumor recurrence and patient survival are summarized in Table 3. In the univariate analyses, significant risk factors for disease-free survival (DFS) were HBV infection, hypermetabolic FDG-PET findings, MVI (Fig. 3), macrovascular invasion, satellite nodules, and R1 resection, whereas significant risk factors for OS were AFP ≥ 100 ng/mL, hypermetabolic FDG-PET findings, MVI, satellite nodules, and R1 resection. The multivariate analyses demonstrated that MVI was the only independent risk factor for both DFS and OS (Table 4).

Univariate and multivariate analyses of the risk factors associated with tumor recurrence and patient survival

Figure 3

Comparison of the disease-free survival (A) and overall survival (B) curves according to the status of microvascular invasion (MVI).

Multivariate analyses with microvascular invasion and ADV score with a cut-off of 8log

5. Prognostic analysis using the ADV score for DFS and OS

Patients were stratified according to their ADV scores using 1log (10-fold) intervals as follows: eight (8.0%) patients with ADV scores of ≤5.9log; seven (7.0%) with ADV scores of 6.0–6.9log; seven (7.0%) with ADV scores of 7.0–7.9log; 16 (16.0%) with ADV scores of 8.0–8.9log; 15 (15.0%) with ADV scores of 9.0–9.9log; 18 (18.0%) with ADV scores of 10.0–10.9log; nine (9.0%) with ADV scores of 11.0–11.9log; 14 (14.0%) with ADV scores of 12.0–12.9log; and six (6.0%) with ADV scores of ≥ 13.0log. DFS stratified according to the ADV score at 1log intervals showed significant prognostic contrasts (P =0.007; Fig. 4A). OS stratified according to the ADV score at 1log intervals also showed significant prognostic contrasts (P =0.017; Fig. 4B).

Figure 4

Comparison of the disease-free survival (A) and overall survival (B) curves according to the α-fetoprotein, des-γ-carboxy prothrombin, and tumor volume (ADV) score of 1log intervals.

To enhance the prognostic contrast and to select patients with truly poor prognosis, patients were reclassified into two subgroups with ADV score ranges of ≤7.9log and ≥8log after cluster analysis. Survival analysis according to these two cut-off values showed significant prognostic contrasts in DFS (P =0.014; Fig. 5A) and OS (P =0.042; Fig. 5B).

Figure 5

Comparison of the disease-free survival (A) and overall survival (B) curves according to the α-fetoprotein, des-γ-carboxy prothrombin, and tumor volume (ADV) score with a cut-off of 8.0log.

6. Prognostic analysis using a combination of MVI and the ADV score

Risk factor analysis showed that MVI was the only independent risk factor for DFS and OS. Harrell’s c-index, according to MVI, was 0.63 and 0.62 for DFS and OS, respectively. An ADV score with a cut-off of 8log was also a significant prognostic factor. Harrell’s c-index, according to the ADV score with a cut-off of 8log, was 0.57 and 0.56 for DFS and OS, respectively.

Additional multivariate analyses with these two factors showed that MVI was an independent risk factor for DFS (P =0.001) and OS (P =0.001). ADV score with a cut-off of 8log showed a marginal significance for DFS (P =0.098) and OS (P =0.12). Although the prognostic impact of these two parameters was not equally strong, we considered them as two independent risk factors; the combination of MVI and the ADV score with a cut-off of 8log (MVI-ADV score) resulted in three subgroups with 0, 1, and 2 risk factors. This prognostic prediction model using the MVI-ADV score showed significant prognostic contrasts in DFS (P <0.001; Fig. 6A) and OS (P =0.001; Fig. 6B). Harrell’s c-index, according to the MVI-ADV score, was 0.68 and 0.67 for DFS and OS, respectively.

Figure 6

Comparison of the disease-free survival (A) and overall survival (B) curves according to the number of risk factors (presence of microvascular invasion and α-fetoprotein, des-γ-carboxy prothrombin, and tumor volume [ADV] score ≥8.0log).

DISCUSSION

Tumor size is traditionally considered one of the most important prognostic factors for the post-resection prognosis of HCC. We have previously demonstrated that post-resection prognosis gradually worsens with increasing tumor size from 1 cm to 10 cm regardless of the MVI status.11 In addition, the incidence of MVI reportedly increases with HCC size.14 We found that the incidence of MVI showed a progressive increase from 4.1% for HCCs <2 cm to 30.7% for HCCs of 8.1–9.9 cm.11 In the present study, huge HCCs ≥ 13 cm presented with MVI in 73% of cases. It is frequently observed that HCC becomes biologically more aggressive with progressive growth of the tumor, showing a higher incidence of MVI and higher expression of AFP and DCP. Consequently, the prognosis of patients with large HCCs worsens with tumor growth. Contrarily, a small proportion of patients with huge HCCs have shown unexpectedly favorable long-term survival after HR.15 These patients may benefit from HR. Thus, accurate prediction of post-resection prognosis is essential for deciding the treatment plan for patients with huge HCCs.

Before predicting post-resection prognosis, the feasibility of HR should be considered. It is generally accepted that there is no limit to the tumor size that precludes HR, particularly for solitary large HCC, if a patient’s hepatic functional reserve permits the corresponding extent of HR. There are two important aspects regarding the operability of huge HCCs: operative safety and surgical curability. HR of huge HCCs usually requires demanding surgical procedures known to increase the risk of massive bleeding. It is important to perform step-by-step approaches, such as initial feeding artery ligation and anterior approach for hepatic parenchymal transection, to minimize intraoperative bleeding.1618 A large abdominal incision with or without extension to the chest wall helps provide a wide operative field, which facilitates mobilization of the huge tumor-bearing right liver. As a huge tumor occupies a certain portion of the liver, the feasible extents of HR are often comparable to those of partial hepatectomy. It is reasonable to design the extent of HR after considering patient safety first. Thus, there is no reason to stick to systematic resection.3,711,1922 In fact, nearly all HRs for huge HCCs are not considered as systematic resections because of the high incidence of intrahepatic metastases in the future remnant liver.23,24

We have previously developed a prognostic prediction model for HR of large HCCs ≥ 10 cm using four independent parameters: AFP ≥ 100 ng/mL, hypermetabolic FDG-PET findings, MVI, and satellite nodules.3 This prognostic prediction model has been validated through a multicenter study,25 in which its predictive power has been demonstrated to be reliably high. Cluster analysis has enabled us to successfully stratify patients into three subgroups with 0–1, 2, and 3–4 risk factors. However, this prediction model includes two pathological parameters that are unavailable during preoperative assessment. We developed a prognostic prediction model with the ADV score to eliminate this limitation. The ADV score is an integrated surrogate marker of post-resection prognosis for HCC as well as a quantifiable parameter reflecting the oncological aggressiveness of HCC. The clinical usability of the ADV score has been well demonstrated in an increasing number of studies regarding HR and liver transplantation. 79,25

Reliable calculation of the ADV score before surgery is a matter of concern for the preoperative prediction of patients with HCC. We used CT volumetry to measure individual TVs. The definition provided in the Modified Response Evaluation Criteria in Solid Tumors (mRECIST)26 was applied to measure viable TV in patients who underwent prior HCC treatment. In patients who have undergone TACE before HR, TV can be estimated through volumetric measurement of the contrast-enhancing portions of tumors, and lipiodolized zones were considered as non-enhancing lesions as adopted in the mRECIST criteria. This can offset the different therapeutic effects of preceding HCC treatments. It has been reported that the results of pretransplant imaging have reliable correlations with explant/resection pathology regarding the size of viable tumors.2729 Although we did not measure TV before HR in the present study, we believe that there exists a close correlation between the pathology report-based TV and CT volumetry-based TV using the mRECIST criteria. In our recent study on living donor liver transplantation for HCC, the correlation analyses between the pretransplant and pathological findings in 843 patients showed high correlations between viable tumor number (Spearman’s correlation coefficient rho [ρ]=0.845, P <0.001), maximal tumor size (ρ=0.688, P <0.001), total TV (ρ=0.736, P <0.001), and ADV score (ρ=0.895, P <0.001).30

In our previous study with 526 cases of HCC ≥ 8 cm,25 the cut-off of the ADV score was set at 7log after cluster analysis. Patient grouping according to a combination of ADV at 7log and FDG-PET findings exhibited significant differences in DFS and OS, which were comparable to those of the above-mentioned prognostic prediction model with four risk factors. However, the prognostic model combining the ADV score at 7log and FDG-PET findings was not sufficiently reliable for patients with huge HCCs because the ADV score cut-off of 7log was too low to stratify the patients with huge HCCs. Thus, in the present study, we raised the cut-off ADV score to 8log, which resulted in clear prognostic contrast in DFS and OS. In practice, the reliable cut-off value of the ADV score varies depending on the characteristics of the study group. The cut-off ADV score was lowered to 4log for patients with solitary HCC ≤ 5 cm, whereas it was raised to 7log for those with HCC ≥ 8 cm and to 9log for those with HCC combined with portal vein tumor thrombus.79,25

Prognostic prediction with only the ADV score is available before HR; thus, it can be used for treatment planning. After HR, additional information on MVI is available; thus, a combination of the ADV score and MVI can enhance the power of prognostic prediction. In the present study, a combination of MVI and the ADV score cut-off at 8log enabled us to stratify the patients into three subgroups with 0, 1, and 2 risk factors, and DFS and OS were inversely correlated with the number of risk factors. Our prognostic models with only the ADV score and MVI-ADV score combination can be separately applied to clinical practice before and after HR. We have applied them to determine the intervals of follow-up imaging studies, particularly during the first year. We also used the preoperative ADV score using CT volumetry to design the tailored extent of HR.

We have previously reported that de novo or residual intrahepatic metastasis was detected in 41.9% of patients who have undergone HR for large HCCs ≥ 10 cm and preemptive transarterial chemoinfusion (TACI)/TACE at postoperative 1 month.3,19,31 A combination of surgery with curative intent for huge HCCs and subsequent postoperative 1-month TACI/TACE appears to be a reasonable therapeutic option in the current setting in Korea. We have previously demonstrated that satellite nodules were an independent risk factor for intrahepatic metastasis at postoperative 1 month. Thus, performing preemptive 1-month TACI/TACE for HCC with satellite nodules has been strongly suggested.3,19 Although the prognosis of patients with intrahepatic metastasis at 1 month was still inferior to that of patients without early intrahepatic metastasis, we presume that timely or early detection and treatment of small metastatic HCC lesions would benefit these patients, without causing any harm.32

The present study has some limitations. This was a single-center retrospective study in an HBV-endemic area. Hence, it will be necessary to validate our results in other regions to extend our results to patients with HCC of various etiologies. Another limitation was that we selected only patients with solitary HCC to avoid bias from inevitable confounding variables.

In conclusion, the prognostic prediction model using the ADV score could reliably predict the risk of tumor recurrence and long-term patient survival outcomes in patients with solitary huge HCC ≥ 13 cm. The results of this study suggest that our prognostic prediction model can be used to guide surgical treatment and post-resection follow-up in patients with huge HCCs.

Notes

FUNDING

This study was supported by a Research Fund from the Korean Liver Cancer Association (Grant No. 2019 to Shin Hwang).

AUTHOR CONTRIBUTIONS

Conceptualization: Hwang S. Data curation: Kim KH, Moon DB, Ahn CS and Park GC. Formal analysis: Hwang S. Funding acquisition: Hwang S. Methodology: Ha TY, Song GW and Jung DH. Project administration: Hwang S. Visualization: Hwang S. Writing-original draft: Hwang S. Writing - review & editing: Hwang S.

Conflicts of Interest

The authors have no conflicts to disclose.

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Article information Continued

Figure 1

Comparison of preoperative computed tomography (CT) scan, resected right liver specimen, and CT scan taken 3 months after hepatic resection in patients who underwent right hepatectomy. The maximal tumor diameters were 13 cm (A), 17 cm (B), and 20 cm (C).

Figure 2

Kaplan-Meier estimation of post-resection tumor recurrence (A) and overall patient survival (B).

Figure 3

Comparison of the disease-free survival (A) and overall survival (B) curves according to the status of microvascular invasion (MVI).

Figure 4

Comparison of the disease-free survival (A) and overall survival (B) curves according to the α-fetoprotein, des-γ-carboxy prothrombin, and tumor volume (ADV) score of 1log intervals.

Figure 5

Comparison of the disease-free survival (A) and overall survival (B) curves according to the α-fetoprotein, des-γ-carboxy prothrombin, and tumor volume (ADV) score with a cut-off of 8.0log.

Figure 6

Comparison of the disease-free survival (A) and overall survival (B) curves according to the number of risk factors (presence of microvascular invasion and α-fetoprotein, des-γ-carboxy prothrombin, and tumor volume [ADV] score ≥8.0log).

Table 1

Clinicopathological features of the study patients (n=100)

Characteristic Value
Age (years) 55.1±11.9 (20–79)

Sex
 Male 78 (78.0)
 Female 22 (22.0)

Background liver disease
 Hepatitis B virus infection 77 (77.0)*
 Hepatitis C virus infection 2 (2.0)
 Alcoholic liver disease 19 (19.0)
 Others 2 (2.0)

Preoperative laboratory profiles
 Total bilirubin (mg/dL) 1.1±0.5
 Aspartate aminotransferase (IU/L) 113.1±110.9
 Alanine aminotransferase (IU/L) 62.3±115.5
 Albumin (g/dL) 3.5±0.5
 Prothrombin time (INR) 1.43±1.21
 Platelet count (/μL) 245.3±99.1×103

Serum AFP
 <100 ng/mL 33 (33.0)
 ≥100 ng/mL 67 (67.0)
 Median (ng/mL) 1,300 (1.2–1,420,000)

Serum DCP
 <200 mAU/mL 15 (15.0)
 ≥200 mAU/mL 85 (85.0)
 Median (mAU/mL) 9,080 (16–101,073)

FDG-PET findings (n=86)
 Isometabolic 13 (15.1)
 Hypermetabolic 73 (84.9)

ICG-R15 (%) 15.6±9.6

History of preoperative HCC treatment
 No 87 (87.0)
 Yes 13 (13.0)

Preoperative portal vein embolization
 No 97 (97.0)
 Yes 3 (3.0)

Tumor diameter (cm) 16.2±2.9
 Median (range) 15.0 (13.0–24.5)

Tumor volume (mL) 1,092.2±629.2
 Median (range) 886 (452–3,385)

Microvascular invasion
 Absent 27 (27.0)
 Present 73 (73.0)

Macrovascular invasion
 Absent 82 (82.0)
 Present 18 (18.0)

Satellite nodules
 Absent 75 (75.0)
 Present 25 (25.0)

Most common Edmondson-Steiner tumor differentiation (n=523)
 I and II 35 (35.0)
 III and IV 65 (65.0)

Liver cirrhosis
 Absent 72 (72.0)
 Present 28 (28.0)

Values are presented as mean±standard deviation (range) or number (%) unless otherwise indicated.

INR, International Normalized Ratio; AFP, α-fetoprotein; DCP, des-γ-carboxy prothrombin; FDG-PET, 2-18F-fluoro-2-deoxy-d-glucose positron emission tomography; ICG-R15, indocyanine green retention test at 15 minutes; HCC, hepatocellular carcinoma.

*

Including one case of hepatitis B and C virus co-infection.

Table 2

Extents of hepatic resection

Value
Extent of hepatectomy
 Right trisectionectomy 4 (4.0)
 Right hepatectomy±caudate resection 58 (58.0)
 Right anterior sectionectomy 5 (5.0)
 Right posterior sectionectomy 5 (5.0)
 Central bisectionectomy 5 (5.0)
 Left trisectionectomy 1 (1.0)
 Left hepatectomy±caudate resection 15 (15.0)
 Left medial sectionectomy 2 (2.0)
 Left lateral sectionectomy 3 (3.0)
 Partial hepatectomy 2 (2.0)

Concurrent extrahepatic bile duct resection 3 (3.0)

Curability of hepatic resection
 R0 resection 88 (88.0)
 R1 resection 12 (12.0)

Values are presented as number (%).

Table 3

Univariate and multivariate analyses of the risk factors associated with tumor recurrence and patient survival

Parameter Case No. Tumor recurrence Patient survival


Univariate analysis Multivariate analysis Univariate analysis Multivariate analysis




Median DFS period (months) P-value Hazard ratio 95% CI P-value Median OS period (months) P-value Hazard ratio 95% CI P-value
Background liver disease 0.031 0.24 0.31 ND
 Non-HBV 23 9.4 1 25.7
 HBV 77 3.7 1.40 0.79–2.56 38.0

Preoperative AFP 0.40 ND 0.048 0.18
 <100 ng/mL 33 3.7 56.3 1
 ≥100 ng/mL 67 4.2 17.7 1.40 0.85–2.30

Serum DCP 0.64 ND 0.21 ND
 <200 mAU/mL 15 5.5 47.2
 ≥200 mAU/mL 85 3.8 28.8

FDG-PET findings 0.004 0.19 0.024 0.21
 Isometabolic 13 3.7 1 95.7 1
 Hypermetabolic 73 8 1.87 0.74–4.74 18.5 1.87 0.71–4.91

Microvascular invasion <0.001 0.007 <0.001 0.020
 Absent 27 34.6 1 88.6 1
 Present 73 3.1 2.42 1.27–4.61 7.1 2.10 1.12–3.91

Macrovascular invasion 0.031 0.46 0.53 ND
 Absent 82 4.5 1 34.5
 Present 18 2.7 1.24 0.71–2.18 15.5

Satellite nodule 0.001 0.071 0.011 0.99
 Absent 75 5.5 1 38.1 1
 Present 25 2.9 1.63 0.96–2.77 9.6 1.54 0.92–2.59

Tumor diameter 0.68 ND 0.66 ND
 <15 cm 44 3.7 39.2
 ≥15 cm 56 4.1 18.5

Tumor volume 0.52 ND 0.73 ND
 <886 mL 49 3.7 37.3
 ≥886 mL 51 4.4 27.7

Liver cirrhosis 0.85 ND 0.49 ND
 Absent 72 4.5 32.3
 Present 28 3.0 25.7

Type of curability 0.091 0.61 0.036 0.13
 R0 resection 88 4.5 1 37.3 1
 R1 resection 12 2.1 1.20 0.61–2.38 10.6 1.68 0.87–3.26

DFS, disease-free survival; 95% CI, 95% confidence interval; OS, overall survival; ND, not done; HBV, hepatitis B virus; AFP, α-fetoprotein; DCP, des-γ-carboxy prothrombin; FDG-PET, 2-18F-fluoro-2-deoxy-d-glucose positron emission tomography.

Table 4

Multivariate analyses with microvascular invasion and ADV score with a cut-off of 8log

Disease-free survival Overall survival


Hazard ratio P-value 95% CI Hazard ratio P-value 95% CI
Microvascular invasion 0.001 0.001
 Absent 1
 Present 3.67 2.09–6.45 2.72 1.51–4.93

ADV score 0.098 0.12
 ≤7.9log 1 1
 ≥8.0log 1.4 0.91–2.29 1.45 0.96–2.33

ADV score, α-fetoprotein, des-γ-carboxy prothrombin, and tumor volume score; 95% CI, 95% confidence interval.