Sonography of hepatic hemangioma accompanied by arterioportal shunt

Article information

Clin Mol Hepatol. 2014;20(1):85-87
Publication date (electronic) : 2014 March 26
doi : https://doi.org/10.3350/cmh.2014.20.1.85
Department of Radiology, Asan Medical Center, University of Ulsan College of Medicine, Seoul, Korea.
Corresponding author: Kyoung Won Kim. Department of Radiology, Asan Medical Center, University of Ulsan College of Medicine, 88 Olympic-ro 43-gil, Songpa-gu, Seoul 138-736, Korea. Tel. +82-2-3010-4385, Fax. +82-2-476-4719, kimkw@amc.seoul.kr

INTRODUCTION

Hepatic hemangiomas frequently accompany arterioportal shunt with an incidence of up to 26%.1 CT and MR findings of these tumors with arterioportal shunt have been well addressed; they tend to show rapid contrast enhancement than those without shunt on dynamic studies.1 However, it is still worthwhile to detail sonographic features of such tumors, because they are frequently found at screening sonography incidentally and further or follow-up study can be simplified if they can be differentiated from malignant tumors. In this article, we present suggestive sonographic findings of hepatic hemangioma attributed to an accompanied arterioportal shunt.

CASE

A 58-year-old man visited our hospital with right upper quadrant pain. His clinical history did not include any specific disease, family history was unremarkable, and physical examination was unremarkable. The results of routine laboratory investigations were unremarkable as well. Serologic tests for hepatitis A, B, and C were negative.

Hepatic sonography showed increased liver echogenicity, suggestive of hepatic steatosis. Gallbladder was unremarkable, and there was no remarkable abnormal finding in the biliary tree and pancreas as well. In the subcapsular area of the right hepatic lobe, there was a 2-cm, well-defined nodule with echo-poor appearance, surrounded by large geographic perinodular hypoechoic area, suggestive of peritumoral sparing of hepatic steatosis (Fig. 1). There was no thrombus at the portal branch, in the spared area of hepatic steatosis around the tumor. Doppler study revealed hypervascularity of the tumor and the reverse hepatofugal flow of the peritumoral portal vein parallel to the feeding artery, indicating the presence of arterioportal shunt accompanying the tumor. Based on grayscale and Doppler sonographic findings, hepatic hemangioma with arterioportal shunt was highly suspected.

Figure 1

A 58-year-old man with hepatic steatosis and hepatic hemangioma accompanying arterioportal shunt. (A) Oblique sagittal sonogram shows increased liver echogenicity, suggestive of hepatic steatosis. There is about 2-cm, well-defined hypoechoic nodule (arrowheads) in the subcapsular area of the right hepatic lobe, surrounded by large geographic, less hypoechoic area (arrows), suggestive of peritumoral sparing of hepatic steatosis. A hepatic tumor accompanying arterioportal shunt is highly suspected. (B) Color Doppler sonogram shows spotty intratumoral flow signals (arrowheads). Also noted is reverse, hepatofugal flow of the peritumoral portal vein (deep blue color, arrows) parallel to the feeding artery (light orange color, small arrows), indicating the presence of arterioportal shunt accompanying the tumor. (C) Unenhanced CT scan shows decrease of hepatic attenuation, suggestive of hepatic steatosis, and also shows subtle hyperdense area (arrows) around tumor (arrowheads), which corresponds to geographic peritumoral hypoechoic area at sonography, suggesting peritumoral sparing of steatosis. (D) Coronal postcontrast CT during hepatic arterial phase shows strong enhancement of tumor (arrowheads) and large, wedge-shaped peritumoral parenchymal enhancement (arrows). (E) Coronal post-contrast CT during portal venous phase shows persistent homogeneous enhancement of tumor (arrowheads). Peritumoral parenchymal hyperenhancement is also appreciated.

Unenhanced and postcontrast dynamic CT scans were performed for further evaluation of hepatic tumor. Unenhanced CT scan showed decrease of hepatic parenchymal attenuation, suggestive of hepatic steatosis. The tumor was seen as low attenuation nodule in the subcapsular area of the right hepatic lobe, surrounded by subtle hyperdense area, suggesting peritumoral sparing of steatosis. Dynamic contrast-enhanced CT showed strong homogenous enhancement of the tumor, surrounded by large wedge-shaped parenchymal hyperenhancement during the arterial phase. The tumor showed persistent enhancement similar to hepatic vessels and the surrounding parenchymal hyperenhancement was also appreciated during the venous phase. Several small nodules (< 1 cm) with similar enhancement pattern as the one described above were also noted in both hepatic lobes. The diagnosis of hepatic hemangiomas with arterioportal shunt was made by typical CT features.

DISCUSSION

Most commercial ultrasound scanners are equipped with Doppler function, and Doppler study is widely used as a part of routine examination for liver tumors. The value of Doppler sonography for the evaluation of hepatic hemangioma has been generally underestimated, presumably because most typical hemangiomas have slow intratumoral flow below the sensitivity limits of Doppler technique. However, in contrast to the dissatisfying results of Doppler sonography in typical slow-flow hemangiomas, it has been reported that Doppler sonography can commonly depict large penetrating arteries, intratumoral flow, and peritumoral hepatofugal portal flow in patients with atypical high-flow hemangiomas with arterioportal shunt.2,3 Because the performance of Doppler sonography is generally attenuated with lesion depth, such findings are more commonly appreciated when the lesion is located shallow from the ultrasound transducer.2 In addition to the high-flow hemangiomas with arterioportal shunt, many hypervascular hepatic tumors other than, such as hepatocellular carcinomas, focal nodular hyperplasias, and hepatic adenomas may show intratumoral blood flow on Doppler sonography. However, the peritumoral hepatofugal portal flow is an uncommon finding among various hypervascular tumors other than high-flow hemangiomas with arterioportal shunt and hepatocellular carcinomas. Hepatofugal portal flow associated with hepatocellular carcinoma is usually seen in cases with tumor thrombus in the portal vein.4 Therefore, the presence of peritumoral hepatofugal portal flow on Doppler sonography in the absence of portal vein thrombus may be an important sign that enhance the suspicion of high-flow hemangiomas with arterioportal shunt.

It has been shown that the speed of enhancement on dynamic post-contrast study is correlated with the sonographic pattern. The tumors with rapid enhancement on dynamic studies tend to be hypoechoic sonographically, and those with slow enhancement tend to be hyperechoic.5 In addition, it is interesting that, in the presence of hepatic steatosis, an arterioportal shunt associated with high-flow hemangiomas may result in peritumoral sparing of steatosis. Some investigators speculated that the intrahepatic, regional alteration of portal flow (dilution of portal blood by nonlipid-rich arterial blood by arterioportal shunt) may be an important factor as the cause of the focal sparing of steatosis.6 Therefore, in the presence of hepatic steatosis, high-flow hemangiomas with arterioportal shunt tend to appear as hypoechoic masses surrounded by geographic peritumoral less hypoechoic area.7

SUMMARY

Arterioportal shunt accompanying hepatic hemangioma can be diagnosed on Doppler sonography, by demonstrating the hepatofugal flow at the peritumoural portal branch parallel to the feeder. In the presence of hepatic steatosis, an arterioportal shunt associated with high-flow hemangiomas may result in peritumoral sparing of steatosis so that the tumor appear as hypoechoic masses surrounded by geographic peritumoral less hypoechoic area. A precise sonographic appreciation of such findings may ensure an accurate sonographic diagnosis of these tumors.

Notes

The authors have no conflicts to disclose.

Abbreviations

CT

Computed tomography

MR

Magnetic resonance

References

1. Kim KW, Kim TK, Han JK, Kim AY, Lee HJ, Choi BI. Hepatic hemangiomas with arterioportal shunt: findings at two-phase CT. Radiology 2001;219:707–711. 11376258.
2. Lim KJ, Kim KW, Jeong WK, Kim SY, Jang YJ, Yang S, et al. Colour Doppler sonography of hepatic haemangiomas with arterioportal shunts. Br J Radiol 2012;85:142–146. 21385916.
3. Naganuma H, Ishida H, Konno K, Hamashima Y, Komatsuda T, Ishida J, et al. Hepatic hemangioma with arterioportal shunts. Abdom Imaging 1999;24:42–46. 9933672.
4. Kudo M. Imaging blood flow characteristics of hepatocellular carcinoma. Oncology 2002;62(Suppl 1):48–56. 11868785.
5. Yu JS, Kim MJ, Kim KW, Chang JC, Jo BJ, Kim TH, et al. Hepatic cavernous hemangioma: sonographic patterns and speed of contrast enhancement on multiphase dynamic MR imaging. AJR Am J Roentgenol 1998;171:1021–1025. 9762989.
6. Arita T, Matsunaga N, Honma Y, Nishikawa E, Nagaoka S. Focally spared area of fatty liver caused by arterioportal shunt. J Comput Assist Tomogr 1996;20:360–362. 8626890.
7. Kim KW, Kim AY, Kim TK, Kim SY, Kim MJ, Park MS, et al. Hepatic hemangiomas with arterioportal shunt: sonographic appearances with CT and MRI correlation. AJR Am J Roentgenol 2006;187:W406–W414. 16985113.

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Figure 1

A 58-year-old man with hepatic steatosis and hepatic hemangioma accompanying arterioportal shunt. (A) Oblique sagittal sonogram shows increased liver echogenicity, suggestive of hepatic steatosis. There is about 2-cm, well-defined hypoechoic nodule (arrowheads) in the subcapsular area of the right hepatic lobe, surrounded by large geographic, less hypoechoic area (arrows), suggestive of peritumoral sparing of hepatic steatosis. A hepatic tumor accompanying arterioportal shunt is highly suspected. (B) Color Doppler sonogram shows spotty intratumoral flow signals (arrowheads). Also noted is reverse, hepatofugal flow of the peritumoral portal vein (deep blue color, arrows) parallel to the feeding artery (light orange color, small arrows), indicating the presence of arterioportal shunt accompanying the tumor. (C) Unenhanced CT scan shows decrease of hepatic attenuation, suggestive of hepatic steatosis, and also shows subtle hyperdense area (arrows) around tumor (arrowheads), which corresponds to geographic peritumoral hypoechoic area at sonography, suggesting peritumoral sparing of steatosis. (D) Coronal postcontrast CT during hepatic arterial phase shows strong enhancement of tumor (arrowheads) and large, wedge-shaped peritumoral parenchymal enhancement (arrows). (E) Coronal post-contrast CT during portal venous phase shows persistent homogeneous enhancement of tumor (arrowheads). Peritumoral parenchymal hyperenhancement is also appreciated.