Zhang, Zhu, Hu, and Wu: Contrast-enhanced ultrasound imaging features and clinical characteristics of combined hepatocellular cholangiocarcinoma: comparison with hepatocellular carcinoma and cholangiocarcinoma

Abstract

Purpose

The purpose of this study was to retrospectively compare the clinical characteristics and imaging features on (CEUS) of combined hepatocellular cholangiocarcinoma (CHC) with those of hepatocellular carcinoma (HCC) and cholangiocarcinoma (CC).

Methods

The clinical information and CEUS features of 45 patients with CHC from 2015 to 2019 and 1-to-1-matched control subjects with HCC and CC (45 each) were compared.

Results

Simultaneous elevation of α-fetoprotein (AFP) and cancer antigen (CA) 19-9 was more common in CHC than in HCC and CC. In the arterial phase, hyperenhancement (homogeneous and heterogeneous) was more common in CHC (73.3%) and HCC (100%), while peripheral rim-like enhancement was more common in CC (55.6%). In the portal phase, marked washout was significantly more frequent in CHC and CC than in HCC (42.2% and 53.3% vs. 6.7%). In the delayed phase, marked washout was more common in CHC (82.2%) and CC (93.3%) than in HCC (40.0%). The washout time (WT) was much shorter in CHC and CC than in HCC (33.8±13.1 seconds and 30.1±11.6 seconds vs. 58.4±23.5 seconds). Using the combination of simultaneous elevation of AFP and CA 19-9 with marked washout in the delayed phase and a WT <38 seconds or arterial hyperenhancement to differentiate CHC from HCC or CC, the accuracy, sensitivity, and specificity were 74.4%, 93.3%, and 55.6% and 71.1%, 80.0%, and 62.2%, respectively.

Conclusion

Although some CEUS imaging features of CHC, HCC, and CC overlap, the combination of tumor markers and CEUS features can be helpful in differentiating CHC from HCC and CC.

Introduction

Hepatocellular carcinoma (HCC) and cholangiocarcinoma (CC) account for the vast majority of primary liver malignancies, while combined hepatocellular cholangiocarcinoma (CHC)-also referred to as a "biphenotypic" tumor-comprises a distinct minority, accounting for 0.4%-14.5% [1]. Although CHC has been categorized into three distinct types based on the relative separation of the different CC and HCC components, only those consisting of intermixed components and transitional cell types appear to represent true combination tumors, whereas other types may exist along the spectrum of collision tumors [2]. The prognosis of CHC appears to be worse than that of HCC and similar to that of CC due to the high frequency of vascular invasion and lymph node metastasis [2-4]. At present, according to guidelines, surgical resection, transplantation, and percutaneous ablation constitute the treatment strategy for HCC [5], while for CC, resection has been regarded as the first-line approach [6]. However, the most appropriate treatment for CHC remains unclear, even though radical liver resection likely yields the greatest survival benefit in limited-stage patients [7]. Therefore, the conundrum of the preoperative diagnosis is a potential factor shaping treatment selection.
A few studies have evaluated the imaging characteristics of CHC based on contrast-enhanced computed tomography (CECT) [8,9] and magnetic resonance imaging (MRI) [8,10,11]. Theoretically, because CHC comprises HCC and CC components, the imaging features of both HCC and CC would be visualized, with either an HCC-like or CC-like appearance predominating [8]. Contrast-enhanced ultrasonography (CEUS) has been found to be clinically valuable in the diagnosis of focal liver lesions for years, as it can non-invasively reflect the blood perfusion of tumor tissue in real time [12]. However, only sporadic reports have investigated the CEUS features of CHC [13-16]. Furthermore, because of its rarity, limited studies have assessed the diagnostic performance of CEUS in the differential diagnosis of CHC from HCC and CC.
Regarding the clinical features, cancer antigen (CA) 19-9 and α -fetoprotein (AFP), which are useful adjuncts to imaging in patients with CC and HCC, respectively, are the main tumor markers of interest. Although prior studies have suggested that once both AFP and CA 19-9 are simultaneously elevated or are elevated in discordance with the imaging features (mainly CECT or MRI), a diagnosis of CHC should be considered [8,17]. However, the diagnostic performance of this widely accepted algorithm for the differential diagnosis of CHC and HCC or CC has not yet been investigated.
Therefore, the purpose of this study was to evaluate the diagnostic performance of CEUS and clinical features in distinguishing CHC from HCC and CC, and to identify preoperative clues that may indicate the diagnosis and better guide clinical management decisions.

Materials and Methods

Patients

Institutional review board approval with a consent waiver was obtained for this retrospective study. Our institutional pathology database was searched for consecutive CHC tumors between January 2015 and June 2019, and these results were cross-referenced with the radiology database, excluding any patients without preoperative CEUS. The pathology and radiology databases were also searched for HCC and CC cases over the same period. Due to the relative rarity of CHC, the number of HCC and CC cases far exceeded that of CHC cases; therefore, a random number generator software tool was used to randomly choose HCC and CC cases according to a 1:1 proportion. As a result, 135 patients-including 45 with CHC, 45 with HCC, and 45 with CC-were included in this retrospective study. All patients underwent hepatectomy and the diagnosis was confirmed through a postoperative pathology report.

CEUS Examinations

The CEUS examinations were performed by an experienced sonologist (R.F.H.) with more than 20 years of liver ultrasonography experience using two scanners (C1-5, 1-5 MHz, Logiq E9, GE Healthcare, Chicago, IL, USA; C5-1, 1-5 MHz, IU22, Philips Medical Systems, Foster City, CA, USA). On grayscale ultrasonography, the tumor number, location, and size were recorded. Then, CEUS was performed with a low mechanical index of <0.1, and 2.4 mL of contrast agent (SonoVue, Bracco, Switzerland) was antecubitally injected as a bolus followed by a 5-mL saline flush. The timer was started at the contrast agent injection (0 second), and the lesion was scanned continuously for up to 3 minutes. As a routine examination procedure, the technical settings were fixed for CEUS: dynamic range, 65-70 dB; frame rate, 12-15 fps; gain, 75%; and one focus below the lesion. The entire vascular phase was recorded on a hard drive for further analysis.
In this study, a per-patient analysis was performed. In patients with more than one hepatic lesion, only the largest and best-visualized lesion was targeted because CEUS could not be used to scan multiple nodules simultaneously after a single injection of contrast agent.

CEUS Interpretation

All the CEUS videos were reviewed and evaluated by two experienced sonologists (T.Z. and L.W.) in consensus. The entire vascular phase consisted of three phases: arterial (0-30 seconds after the injection), portal (31-120 seconds after the injection), and delayed phase (>120 seconds after the injection) [18].
In the arterial phase, the enhancement pattern was defined by a comparison of enhancement behavior between the tumor and liver parenchyma, and was classified as follows (Figs. 1-5): (1) homogeneous hyperenhancement: entirely hyperenhanced without any defects compared with the liver parenchyma; (2) heterogeneous hyperenhancement: mixed hyperenhancement in both the peripheral and central parts, with enhancement defects; (3) peripheral hyperenhancement: irregular rim-like hyperenhancement at the periphery of the lesion, with sparse filiform and punctiform internal enhancement; and (4) isoenhancement/hypoenhancement: enhancement of the lesion to a similar or lesser degree compared with the liver parenchyma.
In the portal and delayed phases, the presence of washout and washout degree were evaluated. Washout was defined as hypoenhancement of the lesion in the portal or delayed phase preceded by arterial hyperenhancement. In patients with arterial peripheral or heterogeneous hyperenhancement, washout was confined to the hyperenhanced portion within the lesion. The washout degree in the portal and delayed phase was classified as marked washout (obviously lower echogenicity than that of the liver parenchyma), mild washout (slight hypoechogenicity compared to the surrounding liver parenchyma) and no washout (similar or slightly higher echogenicity relative to the liver parenchyma preceded by hyperenhancement in the arterial phase).
Furthermore, time-related CEUS parameters were visually recorded. Enhancement time (ET) was defined as the time interval between the contrast agent injection (0 second) and its emergence within the lesion; time to peak (TTP) was defined as the time interval between the emergence of contrast agent within the lesion and peak enhancement; and washout time (WT) was defined as the time interval between the emergence of contrast agent and the time point of hypoechogenicity within the lesion.

Statistical Analysis

All statistical analyses were performed using SPSS version 24.0 (IBM Corp., Armonk, NY, USA). The clinical and CEUS characteristics of the patients were expressed as mean±standard deviation and range or as count and proportion. The chi-square test or Fisher exact test was applied to compare differences in categorical variables. The independent-sample t test was used to compare differences in time-related parameters, including ET, TTP, and WT. P-values of <0.05 were considered to indicate statistically significant differences. We calculated the accuracy, sensitivity, and specificity of the features that played a statistically significant role in the differential diagnosis.

Results

Clinical Characteristics

The comparisons of the clinical characteristics of CHC, HCC, and CC are summarized in Table 1. The percentage of hepatitis B infections and the percentage of patients with a fibrotic or cirrhotic hepatic background showed no significant differences among the three entities. Elevated AFP was more common in CHC (55.6%) and HCC (71.1%) than in CC (2.2%), while CA 19-9 was more common in CHC (28.9%) and CC (40.0%) than in HCC (2.2%). Simultaneous elevation of AFP and CA 19-9 was observed in 17.8% (8 of 45) of CHCs and 2.2% (1 of 45) of HCCs, and in no CCs. The tumor size of CHCs was comparable with that of HCCs (P=0.247), while it was significantly smaller than that of CCs (P=0.035).

CEUS Imaging Features

The CEUS imaging features of the three entities are summarized in Table 2.
In the arterial phase, hyperenhancement (either homogeneous or heterogeneous) was much more common in CHC and HCC than in CC (73.3% and 100% vs. 37.8%), while peripheral enhancement was predominantly displayed in CC (62.2% vs. 0% in HCC and 26.7% in CHC).
In the portal phase, washout was detected in 95.6% of CHCs, 62.2% of HCCs, and 100% of CCs. Additionally, the frequency of marked washout was much higher in CHC (42.2%) than in HCC (6.7%) (P<0.001), and was comparable to that in CC (53.3%) (P=0.291).
In the delayed phase, the frequency of marked washout in CHC and CC was comparable (82.2% vs. 93.3%, P=0.108), and significantly higher than in HCC (40.0%). The majority of HCCs displayed mild washout (57.8%).
Therefore, the most common enhancement pattern of CHC was hyperenhancement (homogeneous or heterogeneous) in the arterial phase followed by marked washout in the delayed phase, and the second most common enhancement pattern of CHC was peripheral hyperenhancement in the arterial phase followed by marked washout in the delayed phase. However, based on the enhancement pattern, eight and 12 CHCs were misdiagnosed as HCCs and CCs, respectively, because they showed a typical HCC enhancement pattern (hyperenhancement with mild washout in the delayed phase) or a typical CC enhancement pattern (peripheral enhancement in the arterial phase with marked washout in the delayed phase).
Of the time-related CEUS parameters, ET and TTP showed no significant differences among the three different entities. The WT in CHC (33.8±13.1 seconds) was comparable to that in CC (30.1±11.6 seconds) (P=0.229), but was much shorter than that in HCC (58.4±23.5 seconds) (P=0.002).

Diagnostic Efficacy of CEUS and Clinical Features

The diagnostic efficacy of CEUS features and clinical tumor markers is presented in Table 3.
For differentiating between CHC and HCC, the combination of the enhancement pattern, tumor marker, and WT showed the highest diagnostic value, with accuracy, sensitivity, and specificity of 74.4%, 93.3%, and 55.6%, respectively.
For differentiating between CHC and CC, this combination also showed higher efficacy than CEUS enhancement features and tumor markers alone, with accuracy, sensitivity, and specificity of 71.1%, 80.0%, and 62.2%, respectively.

Discussion

With the wide application of ultrasound contrast agents in clinical practice, CEUS has notably improved the diagnostic performance of ultrasonography for several diseases, especially for the differentiation of focal liver lesions, with diagnostic performance that is even comparable to that of CECT and MRI [18]. Thus, in this retrospective study, the value of CEUS in combination with clinical features for differentiating between CHC, HCC, and CC was evaluated, thereby making a novel contribution to the literature.
Regarding clinical features, although AFP and CA 19-9 are useful adjuncts for the diagnosis of HCC and CC, respectively [19], neither of them alone is sensitive or specific enough to identify CHC. However, the combination of these tumor markers may improve the sensitivity of the diagnosis. In present study, simultaneous elevation of AFP and CA 19-9 was more frequently detected in CHC (17.8%) than that in HCC (2.2%) or CC (0%), a pattern that is comparable with the findings of prior studies [20]. Although the sensitivity of this criterion was relatively low for differentiating these entities (17.8%), the high specificity and negative predictive value demonstrated its strong ability to prevent CHC from being misdiagnosed as HCC or CC. In such cases, the diagnosis of CHC could be made with greater confidence.
In previous studies, the discordance between tumor marker elevation and imaging morphology (e.g., elevated CA 19-9 with imaging findings of HCC, or elevated AFP with imaging findings of CC) has been reported to be suggestive of CHC [8]. However, those results were based on the imaging features derived from CECT and dynamic contrast-enhanced MRI, in which the enhancement features of HCC and CC are clearly distinct, with arterial hyperenhancement followed by washout in the portal venous or equilibrium phase being characteristic of HCC [8,21], and peripheral arterial enhancement with progressive enhancement in the portal venous or equilibrium phase being characteristic of CC [8,22]. However, considerable overlap of CEUS features between HCC and CC has been reported, in accordance with the present study. Thus, the discordance between CEUS features and tumor markers was not analyzed in our study.
Histologically, CHC is a combination of intermixed HCC and CC components. Therefore, the well-known imaging features of HCC and CC may provide a framework for approaching the diagnosis of CHC [8]. It has been reported that the ratio of HCC and CC components within the lesion can serve as a distinct CHC imaging appearance [8]. Arterial hyperenhancement followed by portal or delayed washout is considered to be the most characteristic CEUS feature of HCC [5,23], and the common CEUS findings of CC include peripheral arterial rim-like enhancement with portal or delayed washout [23]. However, some CC lesions may also demonstrate similar enhancement patterns to those of HCC, especially in small lesions and those with a cirrhotic background [24], for which reason CEUS was dropped from the list of diagnostic techniques recommended for cirrhotic nodules in the guideline of the European Association for the Study of the Liver, European Organization for Research and Treatment of Cancer in 2012 [25]. Therefore, it is unreliable to use only the enhancement and washout pattern to differentiate CHC from HCC and CC, since there are considerable overlaps between CHC and both CC and HCC.
In recent studies, the time and degree of washout have been proposed and proven important for differentiating between HCC and CC components [14,15,20]. In our study, although arterial hyperenhancement and the presence of washout in the portal and delayed phases showed no differences between HCC and CHC, a marked degree of washout in the delayed phase was much common in CHC than in HCC (82.2% vs. 40.0%). Li et al. [14] reported that marked washout in the delayed phase was present in 76% of CHCs, but only in 10% of HCCs. Therefore, marked washout in the delayed phase may have the potential to provide diagnostic clues for CHC. In our study, when marked washout in the delayed phase was used as a criterion for differentiating CHC from HCC, the sensitivity and specificity were 82.2% and 60.0%, respectively. However, the corresponding values reported by Li et al. [14] were much higher (78% and 90%, respectively). This discrepancy may be due to differences in the tumor size, tumor differentiation, hepatic background, ratio of HCC and CC components within CHC, and other factors between the two studies. The value of WT has not yet been explored in the diagnosis of CHC. According to previous studies on the differential diagnosis of HCC and CC, early washout (<60 seconds) was more common in CC than in HCC (87.9% vs. 16.0%) [26], and the majority of CCs displayed washout within 43 seconds [20,26,27]. In our study, the WT was much shorter in CHC than in HCC (33.8±13.1 seconds vs. 58.4±20.5 seconds), and 57.8% (26 of 45) of CHCs displayed a WT <38 seconds, versus only 17.8% (8 of 45) of HCCs. However, in our study, WT was calculated differently from previous studies. Since the time of the emergence of contrast agent within the lesion may vary considerably due to individual differences in cardiac function, we defined WT as the interval between the emergence of contrast agent in the lesion and hypoenhancement, while in other studies, time 0 was set at the injection of the contrast agent. Nevertheless, the basic pattern of more rapid washout in CHC than in HCC remains clear. In our study, by using the combination of marked washout in the delayed phase, a WT <38 seconds, and simultaneous elevation of AFP and CA 19-9 to differentiate CHC from HCC, the sensitivity and specificity could be increased to 93.3% and 55.6%, respectively. However, since the ratio of histologically predominant components within the lesion may vary considerably, a larger sample size of CHCs should be studied in the future.
Concerning the CEUS features of CHC and CC, washout degree in the portal and delayed phases, as well as WT, showed no significant differences. In the arterial phase, hyperenhancement was more common in CHC than in CC (73.3% vs. 37.8%, P=0.001). Ye et al. [16] also demonstrated that peripheral rim-like arterial enhancement was an independent risk factor for CHC. When arterial hyperenhancement was used as the criterion to differentiate CHC from CC, the sensitivity and specificity in our study were 73.3% and 62.2%, respectively. The sensitivity was higher, and the specificity was somewhat lower than the values reported by Li et al. [14] (55% and 78%, respectively). However, in the study of Li et al. [14], the range of tumor size was large (6 cm), and the patient population was relatively small (30 CHCs, 30 HCCs, and 32 CCs). Furthermore, the prevalence of cirrhosis in patients with CHC and HCC was much higher than that in patients with CC (52% and 60% vs. 22%) in their study [14], while in our study, the prevalence of cirrhosis for each entity was comparable and was much higher than was observed for the corresponding types in the study of Li et al. [14]. This may cause differences in the diagnostic efficacy of CEUS feature of hyperenhancement in the differential diagnosis, because it has been reported that smaller tumors and higher frequencies of liver cirrhosis are associated with a higher likelihood of detecting arterial hyperenhancement within CC lesions [24]. This hypothesis should be further validated with studies concerning the CEUS features of CHCs with differences in size and hepatic background. Using the combination of simultaneous elevation of AFP and CA 19-9, the sensitivity and specificity were 80.0% and 62.2%, respectively.
There are some limitations of our study that should be noted. First, the sample size of CHC was relatively small due to its rarity, and the influence of tumor size and hepatic background on CEUS features was not analyzed. Second, due to the nature of the retrospective study design, correlations between the CEUS features of CHC and histopathological findings were not investigated. Furthermore, we separately compared CEUS features between CHC and HCC and between CHC and CC, and an intermingled differential diagnosis among the three tumor types was not conducted. Third, only CEUS was used to differentiate CHC from HCC and CC in our study, but more imaging modalities should be utilized to improve the diagnostic efficacy, such as CECT, dynamic contrast-enhanced MRI, and some other functional imaging modalities, including parametric imaging and positron emission tomography.
In conclusion, although the CEUS features of CHC, HCC, and CC may overlap, the combination of tumor markers, marked washout in the delayed phase, and a WT <38 seconds was confirmed to be helpful for differentiating between CHC and HCC, and the combination of tumor markers and arterial hyperenhancement may provide a differential diagnostic clue between CHC and CC.

Notes

Author Contributions

Conceptualization: Zhang HC. Data acquisition: Zhu T. Data analysis or interpretation: Wu L. Drafting of the manuscript: Zhang HC. Critical revision of the manuscript: Hu RF. Approval of the final version of the manuscript: all authors.

Conflict of Interest

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

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Contrast-enhanced ultrasound imaging in a 51-year-old woman with pathologically proven hepatocellular carcinoma (arrows).

A. On grayscale ultrasonography, a small hypoechoic lesion measuring 22 mm is demonstrated in the right lobe. B. In the arterial phase, the lesion shows homogeneous hyperenhancement (21 seconds). C, D. In the portal and delayed phase, the lesion shows mild washout (95 seconds at C, and 166 seconds at D).
usg-19093f1.jpg
Fig. 1.

Contrast-enhanced ultrasound (CEUS) imaging in a 56-year-old man with pathologically proven combined hepatocellular cholangiocarcinoma (arrows).

A. On grayscale ultrasonography, a lobulated hypoechoic lesion measuring 46×35 mm is detected in the right lobe. B. A CEUS image reveals homogeneous hyperenhancement in the arterial phase (21 seconds). C. Mild washout is observed in the portal phase (40 seconds). D. In the delayed phase, the lesion demonstrates marked washout (150 seconds).
usg-19093f2.jpg
Fig. 2.

Contrast-enhanced ultrasound (CEUS) imaging in a 51-year-old man with pathologically proven cholangiocarcinoma (arrows).

A. On grayscale ultrasonography, the lesion demonstrates isoechogenicity with a lobulated shape and peripheral halo. The tumor size was 46×38 mm. B. A CEUS image reveals homogeneous hyperenhancement in the arterial phase (22 seconds). C. Mild washout is observed in the portal phase (38 seconds). D. In the delayed phase, the lesion demonstrates marked washout (142 seconds).
usg-19093f3.jpg
Fig. 3.

Contrast-enhanced ultrasound (CEUS) imaging in a 62-year-old man with pathologically proven cholangiocarcinoma (arrows).

A. Grayscale ultrasonography demonstrates a hypoechoic round lesion measuring 51×49 mm. B. In the arterial phase, a CEUS image reveals heterogeneous hyperenhancement (24 seconds). C. Rapid washout is observed in the portal phase (44 seconds). D. In the delayed phase, the lesion demonstrates marked washout (150 seconds).
usg-19093f4.jpg
Fig. 4.

Contrast-enhanced ultrasound (CEUS) imaging in a 44-year-old woman with pathologically proven combined hepatocellular cholangiocarcinoma (arrows).

A. On grayscale ultrasonography, a round hypoechoic lesion measuring 24×20 mm is detected in the right lobe. B. A CEUS image reveals peripheral rim-like hyperenhancement in the arterial phase (18 seconds). C. Rapid washout is observed in the portal phase (47 seconds). D. In the delayed phase, the lesion demonstrates marked washout (132 seconds).
usg-19093f5.jpg
Fig. 5.
Table 1.
Comparisons of the clinical characteristics of CHC, HCC, and CC
Clinical feature CHC HCC CC P-value (CHC vs. HCC) P-value (CHC vs. CC)
Age (yr) 0.282 0.463
 Mean±SD 52.2±10.8 46.8±13.6 54.7±15.2
 Range 36-69 28-76 34-80
Sex 0.362 0.180
 Male/female 33/12 29/16 27/18
Tumor size (cm) 0.247 0.035
 Mean±SD 4.2±1.9 3.7±2.4 5.2±2.0
 Range 1.9-6.5 2.0-9.5 3.3-8.0
Tumor numbera) 0.091 0.649
 1/2/>2 30-3-12 37-6-2 32-4-9
Tumor locationb) 0.479 0.206
 Left/right/both 5/39/1 3/40/2 9/33/3
Hepatic backgroundc) 0.116 0.398
 Cirrhosis 26 31 22
 Fibrosis 15 11 16
 Normal 4 3 7
Tumor markers
 Elevated AFP 25 32 1 0.126 <0.001
 Elevated CA 19-9 13 1 18 <0.001 0.267
 Simultaneous elevation 8 1 0 0.014 0.003
HBV infection 0.292 0.561
 Positive 39 42 37
 Negative 6 3 8

CHC, combined hepatocellular cholangiocarcinoma; HCC, hepatocellular carcinoma; CC, cholangiocarcinoma; SD, standard deviation; AFP, α-fetoprotein; CA, cancer antigen; HBV, hepatitis B virus.

a) Comparison between solitary and multiple lesions.

b) Comparison between left lobe and right lobe.

c) Comparison between cirrhotic and non-cirrhotic background.

Table 2.
Comparisons of the CEUS enhancement features of CHC, HCC, and CC
CEUS enhancement feature CHC HCC CC P-value (CHC vs. HCC) P-value (CHC vs. CC)
Arterial phasea) <0.001 0.001
 Homogeneous hyperenhancement 21 29 8
 Heterogeneous hyperenhancement 12 16 9
 Peripheral enhancement 12 0 28
 Isoenhancement/hypoenhancement 0 0 0
Portal phaseb) <0.001 0.291
 Mild washout 24 25 21
 Marked washout 19 3 24
 No washout 2 17 0
Delayed phasec) <0.001 0.108
 Mild washout 8 26 3
 Marked washout 37 18 42
 No washout 0 1 0
Enhancement time (sec) 20.3±3.6 19.7±4.4 19.0±3.9 0.420 0.496
Time to peak (sec) 13.9±4.4 15.0±5.1 13.2±4.2 0.313 0.681
Washout time (sec) 33.8±13.1 58.4±23.5 30.1±11.6 0.002 0.229

CEUS, contrast-enhanced ultrasonography; CHC, combined hepatocellular cholangiocarcinoma; HCC, hepatocellular carcinoma; CC, cholangiocarcinoma.

a) Comparison between peripheral enhancement and hyperenhancement (homogeneous and heterogeneous hyperenhancement).

b) Comparison between marked washout and no/mild washout.

c) Comparison between marked washout and no/mild washout.

Table 3.
Diagnostic efficacy of CEUS and clinical features in the differential diagnosis
Accuracy (%) Sensitivity (%) Specificity (%)
CHC vs. HCC
 Marked washout in the delayed phase 71.1 82.2 60.0
 Simultaneous elevation of AFP and CA 19-9 57.8 17.8 97.8
 WT <38 sec 70.0 57.8 82.2
 Combination 74.4 93.3 55.6
CHC vs. CC
 Hyperenhancement in the arterial phase 67.8 73.3 62.2
 Simultaneous elevation of AFP and CA 19-9 58.9 17.8 100
 Combination 71.1 80.0 62.2

CEUS, contrast-enhanced ultrasonography; CHC, combined hepatocellular cholangiocarcinoma; HCC, hepatocellular carcinoma; AFP, α-fetoprotein; CA, cancer antigen; WT, washout time; CC, cholangiocarcinoma.

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