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Infantile hepatic hemangioendothelioma


Jaterní infantilní hemangioendoteliom

Jaterní infantilní hemangioendoteliom je vzácný benigní vaskulární tumor pocházející z mezenchymální tkáně jater. Přestože jde o nádor benigní, může způsobit až život ohrožující komplikace. V této kazuistice popisujeme případ 5týdenního kojence s tumorózním ložiskem v pravém jaterním laloku. Zobrazovací metody ukazovaly na diagnózu infantilního hemangioendoteliomu, ale přítomnost hepatoblastomu nebylo možné zcela vyloučit. Vzhledem k riziku život ohrožujících komplikací byl nádor chirurgicky odstraněn. Histologický rozbor potvrdil diagnózu infantilního hemangioendoteliomu.

Klíčová slova:

jaterní infantilní hemangioendoteliom – infantilní hemangioendoteliom – hemangioendoteliom jater


Authors: Unzeitig Michal 1;  Hladík Michal 1;  Bajčiová Viera 2;  Skotáková Jarmila 3;  Tůma Jiří 4;  Ježová Marta 5;  Mottl Hubert 1
Authors place of work: Department of Pediatrics, Hemato-Oncology Unit, University Hospital Ostrava 1;  Department of Pediatric Oncology, Children’s University Hospital Brno 2;  Department of Pediatric Radiology, Children’s University Hospital Brno 3;  Department of Pediatric Surgery and Orthopedics, Children’s University Hospital Brno 4;  Department of Pathology, Children’s University Hospital Brno 5
Published in the journal: Čes-slov Pediat 2022; 77 (5): 293-296.
Category: Case Report
doi: https://doi.org/10.55095/CSPediatrie2022/047

Summary

Infantile hepatic hemangioendothelioma (IHH) is a rare, benign vascular tumor that originates from mesenchymal tissue in the liver. Although IHH is benign, it may develop life-threatening complications. We describe a 5-week-old female with a tumorous mass in the right hepatic lobe. Imaging methods pointed to an IHH diagnosis, but we could not rule out hepatoblastoma. Due to the risk of life-threatening complications, the tumor was surgically removed. Histological analysis confirmed the diagnosis of IHH.

Keywords:

hepatic hemangioendothelioma – hemangioendothelioma of the liver – infantile hemangioendothelioma – hemangioendothelioma in infants

Introduction

Liver tumors are quite rare in children. Infantile hepatic hemangioendothelioma (IHH) is the most common benign liver tumor in infancy and the third most common liver tumor in children; however, it is rarely encountered in clinical practice. Although IHH is benign, it is also aggressive, and it may cause life-threatening complications, fulminant hepatic failure, or malignant transformation. Moreover, IHH can be readily mistaken for hepatoblastoma. Here, we describe the detection, diagnosis, and treatment of IHH in a 5-weekold infant.

Case report

A 5-week-old girl was admitted to the hospital for a suspected liver tumor detected on an abdominal ultrasound. The birth was a normal spontaneous delivery, after 36 + 6 weeks of gestation. The Apgar score was 8-9-10, and the birth weight was 3030 g. Prior to the physical examination, she showed no symptoms, but her parents had observed excessive weight gain. During a routine physical examination, the pediatrician discovered abdominal distension. The liver margin was palpable at 1 cm below the right costal margin. Nevus flammeus lesions were also found in the frontal and parietal areas of the head and on the right ear.

A routine blood examination showed moderate anemia (hemoglobin, 90 g/l) and the platelet count was within the normal range. Liver tests were normal, apart from slightly increased gamma-glutamyl transferase (1.91 μkat/l). The thrombin time was extended to 23.2 s, and D-dimer levels were elevated to 5.88 mg/L. At 5 weeks, the alpha-fetoprotein (AFP) level was moderately elevated (8263 µg/l).

Abdominal ultrasonography revealed extensive expansion in the right lobe of the liver. The image was dominated by a heterogeneously hypoechogenic mass, and the expansion was bounded by a quite poorly defined hyperechogenic rim. Numerous calcifications were also observed within the mass. Doppler imaging showed that the tumor was massively perfused with wide, regularly pulsating blood vessels (Fig. 1).

Fig. 1: Abdominal ultrasonogram shows heterogeneous hypoechogenic mass (arrows) in the right lobe with numerous calcifications.
Fig. 1: Abdominal ultrasonogram shows heterogeneous hypoechogenic
mass (arrows) in the right lobe with numerous calcifications.

A contrast CT showed peripheral enhancement in the arterial phase and an irregular central density in the venous phase, probably due to calcifications, hemorrhage, and necrosis (Fig. 2).

Fig. 2: CT images of infant abdomen. A – Contrast CT in the arterial phase shows hypodense liver mass with peripheral enhancement (arrows). B – In the venous phase, the central area of the mass is filled with hyperintense material (arrows), irregular due to calcifications, hemorrhage, and necrosis.
Fig. 2: CT images of infant abdomen. A – Contrast CT in the arterial
phase shows hypodense liver mass with peripheral enhancement
(arrows). B – In the venous phase, the central area of the mass is
filled with hyperintense material (arrows), irregular due to calcifications,
hemorrhage, and necrosis.

An unenhanced MRI showed a bulky tumor located in the right lobe of the liver, which pressed caudally on the right kidney and medially on the inferior vena cava. After intravenous gadolinium administration, a dynamic MRI demonstrated early peripheral enhancement of irregularly-shaped nodes, with delayed centripetal filling in the central region (Fig. 3).

Fig. 3: MRI images of infant abdomen before and after treatment. A – T2-weighted MR image demonstrates a large hyperintense mass. B – Hypointense mass on T1-weighted images. C – MR imaging after administration of gadolinium shows peripheral enhancement with absence of gadolinium in the center of the mass. D – MR imaging month and a half after surgery shows no recurrence.
Fig. 3: MRI images of infant abdomen before and after treatment.
A – T2-weighted MR image demonstrates a large hyperintense
mass. B – Hypointense mass on T1-weighted images. C – MR imaging
after administration of gadolinium shows peripheral enhancement
with absence of gadolinium in the center of the mass. D – MR
imaging month and a half after surgery shows no recurrence.

These images pointed to a diagnosis of IHH, but hepatoblastoma could not be ruled out. In hepatoblastoma, AFP levels are typically elevated, and this tumor showed moderate AFP elevation. A liver biopsy was considered unsafe, due to the high risk of life-threatening bleeding. Thus, we decided to perform a right-sided hemihepatectomy with cholecystectomy.

Histologically, the tumor was relatively poorly defined and infiltrative, and vascular spaces of varying sizes dominated. The vessels were lined with plump endothelial cells with no evidence of hyperchromasia. The vessels were supported by a hypocellular myxoid stroma that contained chaotically distributed bile ductules. Among the blood vessels, we observed plentiful calcifications, pockets of extramedullary hematopoiesis, signs of hemorrhage, and sporadic thrombosis. These vessels showed no GLUT1 (glucose transporter 1) immunoreactivity. Therefore, the histological analysis confirmed the diagnosis of IHH type 1 (GLUT1-negative; Fig. 4).

Fig. 4: Vascular lesion with indistrict margins. It is composed of capillary-type vessels and irregular dilated vessels within fibrotic scar-like stroma and entrapped hepatocytes and bile ducts (hematoxylin-eosin, 50×).
Fig. 4: Vascular lesion with indistrict margins. It is composed of
capillary-type vessels and irregular dilated vessels within fibrotic
scar-like stroma and entrapped hepatocytes and bile ducts
(hematoxylin-eosin, 50×).

The infant recovered well post-operatively. A control MRI, performed one and a half month post-surgery, showed no recurrence.

Discussion

IHH is a benign tumor derived from the mesenchymal tissue of the liver, and it occurs in girls twice as often as it occurs in boys. In 85% of cases, the tumor manifests within the first six months of life.(1) The center of the tumor harbors areas of necrosis, thrombosis, and calcification.(2,3) Clinical and laboratory findings are non-specific, and a liver biopsy is often not recommended, due to the risk of life-threatening bleeding.(4)

The most common symptoms of IHH are abdominal distension, a palpable mass, and hepatomegaly. Other symptoms include skin hemangiomas, anemia, thrombocytopenia, jaundice, hypothyroidism accompanied by elevated TSH levels, failure to thrive, poor feeding, and intestinal obstruction. Life-threatening complications can also develop, such as arteriovenous shunts within the tumor that lead to congestive heart failure and Kasabach-Merritt syndrome (consumptive coagulopathy caused by trapped thrombocytes).( 5) Other complications include tumor rupture with secondary shock, fulminant hepatic failure, or a malignant transformation into angiosarcoma.(6)

There are two types of IHH. Type I IHH comprises variablesized vascular channels lined with a single layer of plump, immature endothelial cells. The supporting fibrous stroma contains chaotically distributed bile ductules.(7) Often, calcification and pockets of extramedullary hematopoiesis are present. Type II IHH has a more disorganized appearance, and the vascular spaces are lined with larger, pleomorphic cells with hyperchromatic nuclei. No bile ductules are present in type II.(8,9)

Mo et al.(10) classified IHH according to positive and negative GLUT1 immunoreactivity in endothelial cells. GLUT1- positive IHH is characterized by multiple small nodules without vascular malformation, arteriovenous shunting, or calcification. Moreover, in many cases, the tumor responds to corticosteroid and interferon treatment. GLUT1-negative IHH is characterized by a single large mass with central necrosis, large abnormal vessels, hemorrhagic areas, and calcification. Compared to GLUT1-positive IHH, GLUT1-negative IHH more frequently evolves to cardiomegaly, anemia, congestive heart failure, and coagulopathy. Conservative treatment typically has no effect, and surgical intervention is necessary.

The main imaging modalities for diagnosing IHH include abdominal ultrasonography, CT, and MRI. An abdominal ultrasound typically reveals a solid, well defined, hypoechoic or isoechoic lesion, accompanied by hyperechoic calcifications.( 11) When substantial arteriovenous shunts are present, anechoic regions may be observed with detectable flow.(7) MRIs reveal a hypointense mass on T1-weighted images and a hyperintense mass on T2-weighted images. After administering gadolinium, the periphery is enhanced during the arterial phase, and the central area is filled after variable delays during the venous phase. CT scans typically demonstrate a well-defined hypodense mass. Contrast-enhanced CTs show an enhancement pattern similar to that observed with contrast-enhanced MRI.(2,12)

The differential diagnosis includes hepatoblastoma, metastatic neuroblastoma, mesenchymal hamartoma, cavernous hemangioma, and angiosarcoma.(9,13)

Hepatoblastoma is the most common primary hepatic neoplasm that typically occurs in the first 2 years of life. This malignant, embryonic tumor typically forms a large solitary lesion in the right liver lobe, accompanied by highly elevated AFP levels.(14) The imaging features and clinical findings of a hepatoblastoma and IHH may be similar, which makes differentiation difficult.(6) For this tumor, surgical resection is the most important part of the treatment.

IHH treatment is based on imaging findings. Conservative therapy commonly includes steroids and α-interferon to accelerate the natural involution of the tumor. Surgical resection is typically indicated when life-threatening symptoms are present, or when the mass cannot be radiologically distinguished from malignancy. Xin Long et al.(4) recommended a hepatectomy in patients with high AFP, even in the absence of symptoms. An unresectable IHH may become resecable after medical therapy. Hepatic artery embolization is considered for patients that fail to respond to medical treatment and are not candidates for surgery. A liver transplant is possible as a last resort.(4,14,15)

In conclusion, solitary liver tumors in infants under 1 year old are not always associated with a hepatoblastoma. Symptoms and laboratory findings of IHH are typically nonspecific, and life-threatening complications may appear. Imaging methods provide the basis for a differential diagnosis of this tumor. Lack of experience with this tumor leads to different treatment approaches. Conducting a GLUT1 immunoreactivity screening in endotelial cells could provide the needed insight in determining further treatment.

Corresponding author:

MUDr. Michal Unzeitig

Dr. Slabihoudka 6185/9

708 00 Ostrava-Poruba

michal.unzeitig@fno.cz


Zdroje

1. Roos JE, Pfiffner R, Stallmach T, et al. Infantile hemangioendothelioma. Radiographics 2003; 23(6): 1649–55.

2. Halefoğlu AM. Magnetic resonance imaging of infantile hemangioendothelioma. Turk J Pediatr 2007; 49(1): 77–81.

3. Parmar RC, Bavdekar SB, Borwankar SS, et al. Infantile hemangioendothelioma. Indian J Pediatr 2001; 68(5): 459–61.

4.  ong X, Wang Y, Zheng K, Zhang B. Infantile hepatic haemangioendothelioma resection in a newborn: A case report and literature review. J Int Med Res 2020; 48(7): 300060520934325.

5. Lu CC, Ko SF, Liang CD, et al. Infantile hepatic hemangioendothelioma presenting as early heart failure: report of two cases. Chang Gung Med J 2002; 25(6): 405–10.

6. Lu M, Greer ML. Hypervascular multifocal hepatoblastoma: dynamic gadolinium- enhanced MRI findings indistinguishable from infantile hemangioendothelioma. Pediatr Radiol 2007; 37(6): 587–91.

7. Pan FS, Xu M, Wang W, et al. Infantile hepatic hemangioendothelioma in comparison with hepatoblastoma in children: clinical and ultrasound features. Hepat Mon 2013; 13(8): e11103.

8. Dachman AH, Lichtenstein JE, Friedman AC, Hartman DS. Infantile hemangioendothelioma of the liver: a radiologic-pathologic-clinical correlation. Am J Roentgenol 1983; 140(6): 1091–6.

9. Zenge JP, Fenton L, Lovell MA, Grover TR. Case report: infantile hemangioendothelioma. Curr Opin Pediatr 2002; 14(1): 99–102.

10. Mo JQ, Dimashkieh HH, Bove KE. GLUT1 endothelial reactivity distinguishes hepatic infantile hemangioma from congenital hepatic vascular malformation with associated capillary proliferation. Hum Pathol 2004; 35(2): 200–9.

11. Chiorean L, Cui XW, Tannapfel A, et al. Benign liver tumors in pediatric patients - Review with emphasis on imaging features. World J Gastroenterol 2015; 21(28): 8541–61.

12. Feng ST, Chan T, Ching AS, et al. CT and MR imaging characteristics of infantile hepatic hemangioendothelioma. Eur J Radiol 2010; 76(2): e24–9.

13. Sari N, Yalçin B, Akyüz C, et al. Infantile hepatic hemangioendothelioma with elevated serum alpha-fetoprotein. Pediatr Hematol Oncol 2006; 23(8): 639–47.

14. Moon SB, Kwon HJ, Park KW, et al. Clinical experience with infantile hepatic hemangioendothelioma. World J Surg 2009; 33(3): 597–602.

15. Kim EH, Koh KN, Park M, et al. Clinical features of infantile hepatic hemangioendothelioma. Korean J Pediatr 2011; 54(6): 260–6.

Štítky
Neonatology Paediatrics General practitioner for children and adolescents

Článok vyšiel v časopise

Czech-Slovak Pediatrics

Číslo 5

2022 Číslo 5
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