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European Radiology
Erschienen in: European Radiology 10/2020

Open Access 08.05.2020 | Hepatobiliary-Pancreas

Combined hepatocellular-cholangiocarcinoma: which preoperative clinical data and conventional MRI characteristics have value for the prediction of microvascular invasion and clinical significance?

verfasst von: Xiaolong Wang, Wentao Wang, Xijuan Ma, Xin Lu, Shaodong Li, Mengsu Zeng, Kai Xu, Chun Yang

Erschienen in: European Radiology | Ausgabe 10/2020

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Abstract

Objectives

To explore which preoperative clinical data and conventional MRI findings may indicate microvascular invasion (MVI) of combined hepatocellular-cholangiocarcinoma (cHCC-CCA) and have clinical significance.

Methods

The study enrolled 113 patients with histopathologically confirmed cHCC-CCA (MVI-positive group [n = 56], MVI-negative group [n = 57]). Two radiologists retrospectively assessed the preoperative MRI features (qualitative analysis of morphology and dynamic enhancement features), and each lesion was assigned according to the LI-RADS. Preoperative clinical data were also evaluated. Logistic regression analyses were used to assess the relative value of these parameters as potential predictors of MVI. Recurrence-free survival (RFS) rates after hepatectomy in the two groups were estimated using Kaplan–Meier survival curves and compared using the log-rank test.

Results

The majority of cHCC-CCAs were categorized as LR-M. On multivariate analysis, a higher serum AFP level (OR, 0.523; 95% CI, 0.282–0.971; p = 0.040), intratumoral fat deposition (OR, 14.368; 95% CI, 2.749–75.098; p = 0.002), and irregular arterial peritumoral enhancement (OR, 0.322; 95% CI, 0.164–0.631; p = 0.001) were independent variables associated with the MVI of cHCC-CCA. After hepatectomy, patients with MVI of cHCC-CCA showed earlier recurrence than those without MVI (hazard ratio [HR], 0.402; 95% CI, 0.189–0.854, p = 0.013).

Conclusion

A higher serum AFP level and irregular arterial peritumoral enhancement are potential predictive biomarkers for the MVI of cHCC-CCA, while intratumoral fat detected on MRI suggests a low risk of MVI. Furthermore, cHCC-CCAs with MVI may have worse surgical outcomes with regard to early recurrence than those without MVI.

Key Points

• Higher serum levels of AFP combined with irregular arterial peritumoral enhancement are independent risk factors for the MVI of cHCC-CCA, while fat deposition might be a protective factor.
• cHCC-CCA with MVI may have a higher risk of early recurrence after surgery.
• Most cHCC-CCAs were categorized as LR-M in this study, and no significant difference was found in MVI based on LI-RADS category.
Hinweise
Xiaolong Wang and Wentao Wang contributed equally to this work.

Publisher’s note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Abkürzungen
AFP
Alpha-fetoprotein
APHE
Arterial phase hyperenhancement
CA19-9
Cancer antigen 19-9
CEA
Carcinoembryonic antigen
cHCC-CCA
Combined hepatocellular-cholangiocarcinoma
CI
Confidence interval
DWI
Diffusion-weighted imaging
Gd-DTPA
Gadopentate dimeglumine
HBP
Hepatobiliary phase
HCC
Hepatocellular carcinoma
ICC
Intrahepatic cholangiocarcinoma
LI-RADS
Liver Imaging Reporting and Data System
LR-M
Probably or definitely malignant, not HCC specific
MRI
Magnetic resonance imaging
MVI
Microvascular invasion
NPV
Negative predictive value
OR
Odds ratio
OS
Overall survival
PLCs
Primary liver carcinomas
PPV
Positive predictive value
RFS
Recurrence-free survival
TACE
Transarterial chemoembolization

Introduction

Combined hepatocellular-cholangiocarcinoma (cHCC-CCA) is a relatively uncommon subtype of primary hepatic malignant tumors, accounting for 2–5% of primary liver carcinomas (PLCs) [13]. Some studies have shown that cHCC-CCA has a biological behavior and prognosis that are intermediate between those of hepatocellular carcinoma (HCC) and intrahepatic cholangiocarcinoma (ICC) [4]; however, some reports have also stated that cHCC-CCA has a significantly worse prognosis than HCC and ICC, even after curative resection [5]. At present, the risk factors identified as being related to prognosis of cHCC-CCA are not uniform across studies because of the relatively low incidence and variations in sample size. Currently, studies have indicated that vascular invasion, lymph node metastasis, satellite nodules, and tumor size are major predictive factors for the prognosis of cHCC-CCA [68]. Studies have also shown that the level of cancer antigen 19-9 (CA19-9) or the presence of cirrhosis is a factor affecting the prognosis of cHCC-CCA [9, 10]. Scholars have not yet come to a consensus regarding the prognostic factors of cHCC-CCA. Although previous studies have confirmed that microvascular invasion (MVI) is a prognostic factor for tumor recurrence and is associated with poor survival outcomes in HCC [1114] and ICC [15, 16], the relationship between prognosis and the presence of MVI in cHCC-CCA patients has not yet been established.
Currently, multiple magnetic resonance imaging (MRI) techniques have been used to improve the preoperative prediction of MVI in HCC [1721]. Some imaging findings, such as “arterial peritumoral enhancement,” “tumor margin,” and “peritumoral hypointensity on hepatobiliary phase (HBP),” have been reported to be related to MVI in HCC [20]; some studies have shown that “incomplete tumor capsule” has a significant relationship with MVI in HCC [21]. A small number of studies have also used MRI to predict the MVI of mass-forming intrahepatic cholangiocarcinoma [22]. Currently, almost all the existing MRI studies have only described the imaging features or clinical characteristics of cHCC-CCA compared to those of pure HCC and ICC, usually with a small sample size [2329]. Recently, studies have utilized LR-M features (including rim arterial phase hyperenhancement (APHE), peripheral “washout” appearance and delayed central enhancement) defined in version 2017 of the Liver Imaging Reporting and Data System (LI-RADS) to identify cHCC-CCA and HCC, and shown that LI-RADS categorization may provide prognostic information on cHCC-CCAs after surgery [30, 31]. However, these studies did not attempt to identify valuable preoperative MRI features indicating MVI in cHCC-CCA patients. Therefore, the purpose of this study was to evaluate the value of preoperative clinical data and conventional MRI findings including morphology, enhanced features, and the LI-RADS category for the preoperative prediction of the MVI of cHCC-CCA. Furthermore, the effect of MVI risk on the early recurrence of cHCC-CCA after surgery was estimated by the follow-up recurrence-free survival (RFS).

Materials and methods

Patient selection

This retrospective study was approved by our institutional review board, and the need for informed patient consent was waived. Between January 2016 and June 2019, in total, 192 consecutive patients were confirmed by postoperative pathology to have cHCC-CCA and without extrahepatic metastasis by preoperative examinations. The inclusion criteria were as follows: (a) primary liver lesions without any prior treatment; (b) the MRI examinations were performed within 30 days before hepatectomy, and the MRI scans satisfied the diagnostic criteria; (c) there was a single mass without intrahepatic metastasis or lesions with multiple origins; and (d) the maximum diameter of the lesion was ≥ 1 cm. Finally, 79 cases were excluded for the following reasons: previous treatment history (n = 17, 8 cases of hepatectomy and 9 cases of transarterial chemoembolization [TACE] therapy); no MRI scans within 1 month before surgery (n = 20); poor MRI quality, including respiratory motion artifact effects (n = 2); two or more lesions of cHCC-CCA in the same liver (n = 35); and the maximum diameter of the lesion was less than 1 cm (n = 5). Finally, 113 patients with cHCC-CCA were enrolled in this study (Fig. 1).

MRI acquisition

All patients were examined with a 24-channel 1.5-T magnetic scanner (uMR 560; United Imaging Healthcare). Routine plain-scan liver protocols consisted of a transverse T2-weighted breath-hold fat-suppressed fast spin-echo sequence, T1-weighted breath-hold in-phase and opposed-phase gradient echo sequence, and free-breath diffusion-weighted imaging (DWI) with a transverse single-shot spin-echo planar sequence (b value, 0, 50, and 500 s/mm2). Dynamic imaging was performed with a breath-hold T1-weighted 3-dimensional fat-suppressed quick spoiled gradient echo sequence before the intravenous administration of gadolinium-diethylenetriamine pentaacetic acid (Gd-DTPA) (Magnevist; Bayer HealthCare). Gd-DTPA was administered at a dose of 0.1 mmol/kg at a rate of 2 ml/s, followed by a 20-ml saline flush using a power injector (Spectris; Medrad). The arterial phase acquisition was triggered automatically by monitoring when the contrast media reached the ascending aorta. For subsequent acquisitions, dynamic T1-weighted MRI at 70–90 s (the portal venous phase) and 160–180 s (the delay phase) was performed. The detailed parameters of each acquisition sequence are shown in Table 1.
Table 1
Parameters of T1-weighted imaging, T2-weighted imaging and diffusion-weighted imaging
Parameter
FS-T2-weighted
T1-weighted IP and OP imaging
FS-T1-weighted quick3D BH
DWI
Repetition time (ms)
2693
115.8
4.4
2807
Echo time (ms)
85.6
4.7 and 2.2
2.2
75.7
Matrix size
201 × 288
230 × 288
192 × 256
115 × 128
Field of view (mm2)
380 × 360
400 × 280
400 × 280
380 × 300
Slice thickness (mm)
6.0
6.0
3.0
6.0
Slice gap (mm)
1.2
1.2
0
1.2
FS fat-suppression, IP in-phase, OP opposed-phase, 3D three dimensional, BH breath-hold, DWI diffusion-weighted imaging

Imaging analysis

All MRI scans were retrospectively analyzed together using a picture archiving and communication system (PACS; Pathspeed, GE Medical Systems Integrated Imaging Solutions) by two radiologists (X.L.W. and C.Y., with 7 and 13 years of experience in abdominal imaging, respectively). Both radiologists were aware that all patients had cHCC-CCA but were blinded to other clinical data, laboratory tests, and pathology results. A third experienced abdominal radiologist (K.X.) with more than 30 years of experience was invited to resolve any disagreements between the two observers.

Qualitative analysis

The following qualitative imaging parameters of the lesions were evaluated on the plain scan: (a) shape of the tumors (globular, lobulated or irregular); (b) contour (smooth or nonsmooth margin); (c) homogeneous or heterogeneous on T2WI; (d) tumor location (right, left, both, or other liver lobe); (e) hemorrhage/hemosiderin; (f) intratumoral fat deposition; (g) necrosis; (h) upper abdominal lymphadenopathy (lymph nodes > 1 cm on the short axis); (i) peritumoral bile duct dilatation; and (j) hepatic capsular retraction. Dynamic enhancement characteristics were as follows: (A) arterial phase—(a) hypervascularity or nonhypervascularity; (b) homogeneity or heterogeneity enhancement; and (c) peritumoral enhancement patterns (assessed as detectable enhancing portion adjacent to the tumor border [wedge shaped], an extensive enhancement surrounding the tumor border [irregular shaped], or absent); (B) portal venous phase—(d) washout (nonperipheral washout or peripheral washout) and (e) enhancing capsule (complete, incomplete, or absent); (C) in the targetoid mass—(f) rim-APHE; (g) peripheral washout; (h) progressive central enhancement; and (i) targetoid diffusion restriction. In addition, all the lesions were categorized based on the LI-RADS v2018, LR-M (definitely or probably malignant, not HCC specific, including rim APHE, peripheral washout, and delayed and progressive concentric enhancement). Threshold growth was excluded because many patients had only one preoperative MRI examination.

Clinical data and MVI pathological evaluation

The following clinical data were collected from the medical records: (a) demographic characteristics (age, sex); (b) etiology (hepatitis B or C virus infection, schistosomiasis, average daily alcohol consumption > 100 g/day, without obvious causes); (c) largest tumor diameter (divided into the 1–5 cm group and the > 5 cm group); (d) liver functional parameters (alanine aminotransferase [ALT], aspartate aminotransaminase [AST], γ-glutamyltranspeptidase [GGT], albumin [ALB], total bilirubin [TB], and direct bilirubin [DB]; and (e) tumor biomarkers (α-fetoprotein [AFP], carcinoembryonic antigen [CEA], and cancer antigen 19-9 [CA19-9]).
The pathological characteristics of the hepatectomy specimens were evaluated by a team of experienced pathologists (each individual had more than 12 years of experience in reading histopathological slices), who were blinded to the MRI and clinical results. MVI was defined as tumor cells within a vascular space lined by endothelium located in the periphery of the tumor at the tumor and liver parenchyma interface that was visible only by microscopy. The enrolled patients were divided into two groups (MVI-positive and MVI-negative) based on pathological characteristics.

Follow-up RFS after surgery

All of the enrolled 113 patients with cHCC-CCAs underwent R0 liver resection (no residual tumor) within 30 days after the first MRI examination, with the surgical techniques and perioperative management the same as in previous reports [4]. Follow-up for RFS consisted of chest radiography, laboratory tests including serum AFP or protein induced by vitamin k absence or antagonist-II (PIVKA-II), and abdominal MRI at 1 month after surgery; if there was no recurrence, the patient was reexamined every 2–3 months. If only the level of a tumor marker increased without any radiographic evidence of a new tumor, follow-up was continuous until a tumor presented on imaging, at which point the time of recurrence was recorded.

Statistical analysis

All statistical analyses were performed using SPSS 20.0 and MedCalc software (version 15.0). Normally distributed data are expressed as the means ± standard deviations, and comparisons between the two groups were performed using independent sample t tests. The data with skewed distributions are expressed as the medians (25%, 75%), and comparisons between the two groups were performed using rank sum tests. Categorical variables are reported as the numbers of cases and percentages, and χ2 or Fisher’s exact tests were used. Comparisons between groups of categorical variables were performed by one-way analysis of variance. Parameters were analyzed using univariate and multivariate logistic regression to determine whether they were independent risk factors predicting MVI (the univariate analysis was performed first, and only those parameters found to have statistical significance were used in the stepwise multivariate logistic regression). A p value less than 0.05 indicated a significant difference. The odds ratio (OR) and 95% confidence interval (CI) were calculated. The sensitivity, specificity, accuracy, positive predictive value (PPV), and negative predictive value (NPV) were calculated for each significant finding and combinations of significant findings on multivariate logistic regression with regard to predicting MVI. The RFS after hepatectomy in two groups were estimated using Kaplan–Meier survival curves and compared using the log-rank test.

Results

Patient clinical and MR characteristics

The comparisons of patient clinical characteristics stratified by the MVI status and data are detailed in Table 2. The results revealed MVI-positive lesions in 56 patients (49.6%) and MVI–negative lesions in 57 patients (50.4%). There were significant differences in the tumor size > 5 cm and the level of serum AFP ≥ 400 ng/ml between MVI-positive and MVI-negative groups (p = 0.006 and p = 0.022, respectively), but when the serum level of AFP was between 20 and 400 ng/ml, there was no significant differences between the two groups. No significant differences (p > 0.05) were found in age, sex, etiology, liver functional parameters, or the levels of CA19-9 and CEA between the two groups (Table 2).
Table 2
Clinical characteristics of cHCC-CCA according to MVI
Clinical parameters
MVI-positive
(n = 56)
MVI-negative
(n = 57)
p value
Age (years) a
56.9 ± 11.4
52.7 ± 11.6
0.0561
Sex (male:female)
37:19
40:17
0.640
Largest diameter (cm)a
5.4 ± 3.2.
3.7 ± 1.9
0.0009
  1–5 cm
26 (46.4)
41 (71.9)
0.006
  > 5 cm
30 (53.6)
16 (28.1)
 
Etiology
  
0.290
  Hepatitis B virus
42 (75.0)
48 (84.2)
 
  Hepatitis C virus
1 (1.8)
0 (0)
 
  None or other
13 (23.2)
9 (15.8)
 
Liver functional parameters
  Total bilirubin > 20 (μmol/L)
8 (14.3)
9 (15.8)
0.823
  Direct bilirubin > 7 (μmol/L)
7 (12.5)
12 (21.1)
0.224
  Alanine aminotransferase > 40 (IU/L)
15 (26.8)
18 (31.6)
0.575
  Aspartate aminotransferase > 40 (IU/L)
13 (23.2)
10 (17.5)
0.454
  γ-Glutamyltranspeptidase > 60 (IU/L)
26 (46.4)
28 (49.1)
0.774
  Albumin < 35 (g/L)
3 (5.4)
2 (3.5)
0.679
Tumor markers
  Alpha-fetoprotein ≥ 20 and < 400 (ng/ml)
21 (37.5)
22 (38.6)
0.796
  Alpha-fetoprotein ≥ 400 (ng/ml)
18 (32.1)
8 (14.0)
0.022
  Cancer antigen 19-9 > 37 (U/ml)
13 (23.2)
14 (24.6)
0.867
  Carcinoembryonic antigen > 5 (ng/ml)
12 (21.4)
8 (14.0)
0.303
Data are numbers of patients (percentage), unless otherwise specified
aData are means ± standard deviations
Data were compared using the Fisher’s exact test. The ages were compared using an independent sample t test. Excepted where indicated, data were compared using the χ2 test
Among the recorded MRI characteristics (Table 3), tumor shape (p = 0.025), hemorrhage/hemosiderin (p = 0.032), intratumoral fat deposition (p = 0.013), upper abdominal lymphadenopathy (p = 0.010), the arterial phase peritumoral enhancement pattern (p < 0.001), and peritumoral bile duct dilatation (p = 0.044) were significantly associated with MVI. Most (89/113, 78.8%) of the cHCC-CCA could be properly categorized as LR-M (Fig. 2), and no significant difference in MVI was found based on the LI-RADS category (p = 0.819). Other features did not differ between the two groups (Table 3).
Table 3
Comparison of qualitative data obtained on MRI features stratified by MVI status
MRI features
MVI-positive
(n = 56)
MVI-negative
(n = 57)
p value
Shape
  
0.025
  Irregular
7 (12.5)
3 (5.3)
 
  Lobulated
38 (67.8)
30 (52.6)
 
  Globular
11 (19.6)
24 (42.1)
 
Contour smooth
14 (25.0)
20 (35.1)
0.242
Homogeneity T2
34 (60.1)
39 (68.4)
0.392
Hemorrhage / hemosiderin
16 (28.6)
7 (12.3)
0.032
Fat deposition
3 (5.4)
13 (22.8)
0.013
Necrosis
20 (35.7)
14 (24.6)
0.196
Upper abdominal lymphadenopathy
22 (39.3)
10 (17.5)
0.010
Location
  
0.953
  Right liver lobe
40 (71.4)
41 (71.9)
 
  Left live lobe
13 (23.2)
12 (21.1)
 
  Caudate lobe or border area
3 (5.4)
4 (7.0)
 
Arterial phase hyperenhancement
50 (89.2)
56 (98.2)
0.061
Arterial phase homogeneity enhancement
2 (3.6)
9 (15.8)
0.053
Arterial phase peritumoral enhancement
  
< 0.001
  Absent
13 (23.2)
39 (69.4)
 
  Wedge shaped
19 (33.9)
9 (15.8)
 
  Irregular
24 (42.9)
9 (15.8)
 
Washout at portal venous phase
28 (50.0)
30 (52.6)
0.780
Enhancing capsule
  Complete
11 (19.6)
14 (24.6)
0.275
  Incomplete
12 (21.4)
6 (10.5)
 
  Absent
33 (58.9)
37 (64.9)
 
Targetoid mass
  Rim arterial phase hyperenhancement
27 (48.2)
33 (57.9)
0.303
  Peripheral washout
12 (21.4)
18 (31.6)
0.222
  Progressive central enhancement
38 (67.8)
43 (75.4)
0.371
  Targetoid diffusion restriction
1 (1.8)
5 (8.8)
0.206
  Peritumoral bile duct dilatation
14 (25.0)
6 (10.5)
0.044
  Surface retraction
1 (1.8)
1 (1.8)
1.000
LI-RADS categorization
  
0.819
  LR-4
1 (1.8)
1 (1.8)
 
  LR-5
12 (21.4)
10 (17.5)
 
  LR-M
43 (76.8)
46 (80.7)
 
  LR-TIV
7 (12.5)
2 (3.5)
0.124
The data are presented as the number (%) of patients
†Data were compared using the Fisher’s exact test. LR-4 probably HCC, LR-5 definitely HCC, LR-M definitely or probably malignant, not HCC specific, LR-TIV tumor in vein

Univariate and multivariate analyses

Univariate logistic regression analysis showed that there were eight risk factors that were significantly related to the MVI of cHCC-CCA (Table 4). A larger tumor size (p = 0.002), a higher serum level of AFP (p = 0.013), an irregular shape (p = 0.005), hemorrhage/hemosiderin (p = 0.036), intratumoral fat deposition (p = 0.014), upper abdominal lymphadenopathy (p = 0.012), arterial phase homogeneity enhancement (p = 0.044), and irregular arterial peritumoral enhancement (p < 0.001) were associated with MVI. These parameters were analyzed using multivariate logistic regression. Higher serum levels of AFP (odds ratio [OR], 0.523; 95% confidence interval [CI], 0.282–0.971; p = 0.040), intratumoral fat deposition (OR, 14.368; 95% CI, 2.749–75.098; p = 0.002), and irregular arterial peritumoral enhancement (OR, 0.322; 95% CI, 0.164–0.631; p = 0.001) were independent variables associated with the MVI of cHCC-CCA.
Table 4
Univariate and multivariate analyses of risk factors for the MVI of cHCC-CCA
Risk factor
Univariate analysis
Multivariate analysis
Odds ratio (95% CI)
p value
Odds ratio (95% CI)
p value
Age (years)a
0.968 (0.936–1.001)
0.060
Sex (male:female)
0.828 (0.375–1.828)
0.640
Largest diameter (cm)
0.772 (0.655–0.908)
0.002
1.010 (0.788–1.94)
0.937
Alpha-fetoprotein ≥ 400 (ng/ml)
0.533 (0.324–0.876)
0.013
0.523 (0.282–0.971)
0.040
Cancer antigen 19-9 > 37 (U/ml)
1.077 (0.453–2.558)
0.060
Carcinoembryonic antigen > 5 (ng/ml)
0.490 (0.187–1.282)
0.146
Shape
  Irregular
0.387 (0.199–0.753)
0.005
0.718 (0.293–1.758)
0.469
  Lobulated*
  Globular*
Contour smooth
1.621 (0.719–3.658)
0.244
Hemorrhage/hemosiderin
0.350 (0.131–0.933)
0.036
0.910 (0.252–3.280)
0.885
Fat deposition
5.220 (1.398–19.490)
0.014
14.368 (2.749–75.098)
0.002
Necrosis
0.972 (0.453–2.085)
0.942
Upper abdominal lymphadenopathy
0.328 (0.138–0.783)
0.012
0.358 (0.118–1.087)
0.070
Arterial phase homogeneity enhancement
5.062 (1.041–24–596)
0.044
1.932 (0.295–12.643)
0.492
Arterial phase peritumoral enhancement
  Absent*
  Wedge shaped*
  Irregular
0.332 (0.201–0.550)
< 0.001
0.322 (0.164–0.631)
0.001
Enhancing capsule
0.675 (0.320–1.426)
0.303
Targetoid mass
  Rim arterial phase hyperenhancement
1.477 (0.703–3.103)
0.303
  Peripheral washout
1.692 (0.724–3.952)
0.224
  Progressive central enhancement
1.455 (0.639–3.315)
0.373
  Targetoid diffusion restriction
5.288 (0.598–46.794)
0.134
  Peritumoral bile duct dilatation
0.353 (0.125–0.998)
0.053
  Surface retraction
0.982 (0.060–16.097)
0.990
LR-M
1.205 (0.539–2.690)
0.650
aData are the means ± standard deviations
*Data were used as the reference variable. LR-M definitely or probably malignant, not HCC specific
The sensitivity, specificity, accuracy, PPV, and NPV for the prediction of MVI by the three significant factors and their combination are shown in Table 5. When all three factors were combined (Fig. 3), the specificity was 98.2% (56/57), and the sensitivity was 12.5% (7/56).
Table 5
Diagnostic performance of independent risk factors for the prediction of MVI in cHCC-CCA
Factors
Sensitivity
Specificity
Accuracy
PPV
NPV
Alpha-fetoprotein ≥ 400 (ng/ml)a
32.1 (18/56)
86.0 (49/57)
59.3 (67/113)
69.2 (18/26)
56.3 (49/87)
Without intratumoral fat depositionb
94.6 (53/56)
22.8 (13/57)
58.4 (66/113)
54.6 (53/97)
81.3 (13/16)
Irregular peritumoral enhancementc
42.9 (24/56)
84.2 (48/57)
63.7 (72/113)
72.7 (24/33)
60.0 (48/80)
Combination of a and b
32.1 (18/56)
87.7 (50/57)
60.2 (68/113)
72.0 (18/25)
56.8 (50/88)
Combination of b and c
39.3 (22/56)
91.2 (52/57)
65.5 (74/113)
81.5 (22/27)
60.5 (52/86)
Combination of a and c
17.9 (10/56)
96.5 (55/57)
57.5 (65/113)
83.3 (10/12)
54.5 (55/101)
Combination of all three factors
12.5 (7/56)
98.2 (56/57)
55.8 (63/113)
87.5 (7/8)
53.3 (56/105)
Data are presented as percentages. Data in parentheses are the numbers of subjects used to calculate the percentage
aAlpha-fetoprotein ≥ 400 (ng/ml)
bWithout intratumoral fat deposition
cIrregular peritumoral enhancement
PPV positive predictive value, NPV negative predictive value

RFS outcomes after surgery

All 113 patients with cHCC-CCAs received R0 liver resection (no residual tumor) within 30 days after the first MRI examination. After hepatectomy, patients with MVI of cHCC-CCA had a median RFS of 10.8 months (range 1–25 months), while those without MVI had a median RFS of 25.4 months (range 1–40 months), and the early recurrence rates (< 2 years) were estimated to be 83.9% (47/56) and 49.1% (28/57), respectively. There was a significant difference in RFS between patients with MVI-positive and MVI-negative tumors (hazard ratio [HR], 0.402; 95% CI, 0.189–0.854, p = 0.013). Kaplan–Meier survival curves were generated (Fig. 4).

Discussion

Our results illustrated that a higher serum level of AFP and irregular arterial phase peritumoral enhancement may indicate a higher risk of the MVI of cHCC-CCA, while intratumoral fat detected on MRI suggests a lower risk. Combining these three findings for the prediction of MVI resulted in specificity greater than 98%. In addition, cHCC-CCAs with MVI may have worse surgical outcomes with regard to early recurrence than those without MVI.
Previously, a few studies reported that a higher serum level of AFP was one of the independent risk factors associated with MVI in HCC [32, 33] and ICC [34] patients. Our findings also showed that a higher serum level of AFP was an independent predictor of MVI in cHCC-CCA, but when the serum level of AFP was between 20 and 400 ng/ml, there were no significant differences in MVI. Furthermore, some studies have suggested that the clinical characteristics of cHCC-CCA are similar to those of HCC; for example, the majority of cHCC-CCAs occur against a background of positive hepatitis B serology and cirrhosis, and the patients are predominately male [28, 35]. Our results were consistent with these studies. In this study, the patients had a sex ratio (male: female) of 77:36, and most patients (79.6%) had been infected with the hepatitis B virus; however, no significant differences in age, sex, or etiology were found regard to in MVI.
Intratumoral fat deposition was an additional significant factor for predicting a lower risk of the MVI of cHCC-CCA in our study, which was consistent with some reports. Min et al [36] described that intratumoral fat was one of the independent variables for suggesting a lower risk of the MVI of HCC. A few studies have suggested that intratumoral fatty changes are associated with favorable tumor grades on histologic examination and a lower likelihood of MVI; therefore, fat-containing lesions may predict a more favorable prognosis than non-fat-containing lesions [36, 37]. Moreover, as is well known, fatty changes in HCC are associated with ischemia, which may be related to a reduced normal portal vein blood supply [38]. Increased intratumoral fat may indicate less aggressive HCC, as evidenced by the fact that HCC with diffuse fat tends to grow slowly. Because our sample size for fat-containing cHCC-CCA with MVI was relatively small, the relationship between intratumoral fat and the prognosis of cHCC-CCA remains to be further studied.
Our study also showed that irregular arterial phase peritumoral enhancement was a significant MRI finding predicting the MVI of cHCC-CCA. Many reports [18, 20, 39] have shown that arterial peritumoral enhancement is an independent predictive factor of MVI in HCC. To date, few studies have described the relationship between peritumoral enhancement of cHCC-CCA and MVI. The mechanism of hemodynamic changes in this type of MRI feature is interpreted as a decrease in or disappearance of portal blood flow due to tumor thrombosis in the microportal branch around the tumor, resulting in compensatory hepatic arterial hyperperfusion [40]. In addition, although previous studies have reported that a large tumor size could be considered a major predictor of HCC with MVI [36], it has not always been considered an independent predictor of the MVI of HCC [18, 19]. In this study, tumor size, tumor shape, intratumoral hemorrhage, upper abdominal lymphadenopathy, and arterial phase heterogeneity enhancement were important risk factors for the MVI of cHCC-CCA in univariate analysis, but they were not independent factors predicting MVI.
It has been reported that MVI is one of the most important prognostic factor for the early recurrence of HCC after hepatic resection or radiofrequency ablation [20, 39]; we also found that cHCC-CCAs with MVI may have worse surgical outcomes with regard to early recurrence than those without MVI. Recent studies [30] have reported that patients with cHCC-CCAs in the LR-M category had a higher early recurrence rate (≤ 6 months) than those with cHCC-CCAs in the LR-5/4 categories. While there was no significant difference in RFS, cHCC-CCAs mimicking HCCs on imaging (LR-5/4) may have improved surgical outcomes. Unlike this study, a substantial proportion of cHCC-CCAs were categorized as LR-M (78.8%, 89/113) in our study; nevertheless, no significant difference in the MVI of cHCC-CCA was found based on the LI-RADS categories.
This study has several limitations. First, because this research was a single-center and retrospective study, there might have been selection bias. Second, tumor size and the number of lesions were confined to larger than 1 cm in maximum diameter and a single mass in this study; therefore, the conclusions cannot be generalized to other size lesions or two or more lesions. Third, the data for overall survival (OS) were not available; thus, the relationship between the MVI of cHCC-CCA and OS requires further research in the future. Fourth, in this study, Gd-DTPA was used as a contrast agent for MRI; therefore, further research is warranted on gadoxetic acid–enhanced MRI for the identification of the MVI of cHCC-CCA. Fifth, our sample size for fat-containing cHCC-CCA with MVI was relatively small which resulted in a low diagnostic sensitivity when all the three parameters were combined; therefore, more patients needed to be enrolled to clarify the diagnostic efficacy. Finally, in our study, cHCC-CCA was assessed only as either MVI-positive or MVI-negative. In a recent study [41], MVI was further categorized into different grades based on the number of vessels invaded. Further study is needed to assess the relationship between preoperative clinical or MRI findings and different grades of MVI of cHCC-CCA.
In summary, the proportion of MVI-positive patients accounts for approximately half of all cHCC-CCA patients. Higher serum levels of AFP and irregular arterial peritumoral enhancement were independent variables associated with the MVI of cHCC-CCA, while fat deposition might be a protective factor. In addition, cHCC-CCA with MVI may have a higher early recurrence rate after surgery.

Compliance with ethical standards

Guarantor

The scientific guarantor of this publication is Chun Yang.

Conflict of interest

The authors of this manuscript declare no relationships with any companies whose products or services may be related to the subject matter of the article.

Statistics and Biometry

No complex statistical methods were necessary for this paper.
Written informed consent was waived by the Institutional Review Board.

Ethical approval

This retrospective study performed at one institution was approved by the Institutional Review Board of Zhongshan Hospital of Fudan University.

Methodology

• Retrospective
• Diagnostic or prognostic study
• Performed at one institution
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://​creativecommons.​org/​licenses/​by/​4.​0/​.

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Metadaten
Titel
Combined hepatocellular-cholangiocarcinoma: which preoperative clinical data and conventional MRI characteristics have value for the prediction of microvascular invasion and clinical significance?
verfasst von
Xiaolong Wang
Wentao Wang
Xijuan Ma
Xin Lu
Shaodong Li
Mengsu Zeng
Kai Xu
Chun Yang
Publikationsdatum
08.05.2020
Verlag
Springer Berlin Heidelberg
Erschienen in
European Radiology / Ausgabe 10/2020
Print ISSN: 0938-7994
Elektronische ISSN: 1432-1084
DOI
https://doi.org/10.1007/s00330-020-06861-2

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