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Extremely high alpha-fetoprotein-producing adrenal hepatoid adenocarcinoma

Tawasapon Thambamroong 1,1 Naiyarat Prasongsook,1 Kantang Satayasoontorn,2 Siriwimon Saichaemchan

1Medical Oncology Division, Department of Internal Medicine, Phramongkutklao Hospital, Bangkok, Thailand 2Department of Pathology, Phramongkutklao Hospital, Bangkok, Thailand

Correspondence to

Dr Tawasapon Thambamroong; t.thambamroong@pmk.ac. th and Assistant Professor Siriwimon Saichaemchan; xray5401@yahoo.com

NP and SS contributed equally.

Accepted 17 June 2021

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C BMJ Publishing Group Limited 2021. No commercial re-use. See rights and permissions. Published by BMJ.

To cite: Thambamroong T, Prasongsook N, Satayasoontorn K, et al. BMJ Case Rep 2021;14:e239830. doi:10.1136/bcr-2020- 239830

SUMMARY

Hepatoid adenocarcinoma (HAC) is a rare tumour that produces an alpha-fetoprotein (AFP) mimicking hepatocellular carcinoma (HCC). Adrenal HAC is exceedingly rare. Here we report extremely high AFP- producing adrenal HAC, the first case in Thailand. A 47-year-old man presented with left flank pain and weight loss for 2 months. A palpably huge left flank mass was observed on physical examination. CT revealed a 7 cm enhanced mass involving the left adrenal gland and multiple contrast-enhanced hypodense masses in both liver lobes. The largest was a 3.7 cm at liver segment- VII without cirrhotic background, with an AFP level of 321 495 ng/ml. Both adrenal and liver biopsies were performed. This patient received a diagnosis of advanced adrenal HAC. Unfortunately, the tumour progressed, causing massive upper gastrointestinal bleeding and death. Adrenal HAC is challenging to diagnose, which multifocal HCC, pheochromocytoma and adrenocortical carcinoma should be excluded. Surgical resection is preferred among resectable patients. However, no systemic therapy has been standardised.

BACKGROUND

Hepatoid adenocarcinoma (HAC) originates from various organs, such as the ovaries, lungs, gall bladder, pancreas, duodenum and adrenal glands. The stomach is the most common site of the tumour.1 This is the first report of adrenal HAC with an extremely high alpha-fetoprotein (AFP) level.

CASE PRESENTATION

A 47-year-old man presented with severe left flank pain and progressive dyspnoea for 2 months. A CT scan of the chest and whole abdomen revealed a 5.5 ×7 cm enhanced mass involving the left adrenal gland and left hemidiaphragm, inferior vena cava (IVC) thrombosis and multiple hypodense liver lesions. Enlarged para-aortic, aortocaval and gastrohepatic lymph nodes were observed up to 3 cm and hypodense lesions scattered in both lobes of the liver. The largest was 3.7x3.3 cm at hepatic segment VII, for which all were contrast enhanced in the portovenous phase without a cirrhosis back- ground (figure 1A).

The serum AFP level was 321 495 ng/ml and otherwise, within normal limits. The 24-hour urine normetanephrine was investigated for preopera- tive evaluation before the left adrenal gland biopsy and to exclude pheochromocytoma condition.

A non-significant elevation was observed of the 24-hour urine normetanephrine level.

Biopsies of the left adrenal and liver mass were performed. The pathological report showed carcinoma with hepatocytic differentiation. The immunohistochemistry (IHC) studies showed immunoreactive with CAM5.2, arginase-1 and glypican-3; focally weakly positive for AE1/AE3 but negative for CK7, CK20, CK19, inhibin A, chro- mogranin A, synaptophysin, S100 and HepPar-1 (figure 2). Therefore, this patient received a diag- nosis of advanced adrenal HAC with multiple liver metastases regarding clinical presentation, imaging, histology and IHC staining.

We planned to start palliative chemotherapy combining cisplatin and etoposide. Unfortunately, the patient developed massive upper gastrointes- tinal (GI) bleeding 3 weeks after the biopsy. CT of the abdomen demonstrated an increase in the size of the left adrenal gland invading the stomach (figure 1B). His clinical status deteriorated rapidly developing hypovolaemic shock from severe upper GI bleeding and he died 2 days later.

An autopsy report demonstrated that a gross tumour originated from the left adrenal gland and directly invaded the stomach and adjacent organs, causing massive GI bleeding. The micro- scopic examination showed the micro-invasion of metastatic disease in the stomach and adjacent organs, disrupting the normal tissue layers. The tumour metastasised to the lungs, pleura, liver and peritoneum.

INVESTIGATIONS

CT of the chest and whole abdomen revealed a 5.5x7 cm enhanced mass at the left adrenal gland involving the left hemidiaphragm, multiple hypodensity lesions with contrast enhanced in portovenous phase at both lobes of the liver, the largest mass was 3.7 cm in diameter at liver segment VII, and IVC thrombosis. Moreover, multiple lymphadenopathies were observed at para-aortic, aortocaval and gastrohepatic lymph nodes, up to 3 cm (figure 1). The same charac- teristics from related reports showed a hypoden- sity lesion, with contrast enhancing in the venous phase on the CT.2-4 This contrasted with typical hepatocellular carcinoma (HCC) imaging based on the American Association for the Study of Liver Diseases 2018 and Liver Imaging Reporting and Data System five criteria, referring to more than 1 cm liver mass arterial hyperenhancement with

BMJ

Figure 1 (A) CT scan with four-phase contrast shows an irregular infiltrative heterogeneous enhanced mass involving the left hemidiaphragm and left adrenal gland mass with several hypodense lesions scattered throughout the lobes of the liver. No radiological evidence supports liver cirrhosis. (B) The CT study shows an interval increase in the left adrenal gland mass, now measuring about 11.2×15.2×5.5 cm. Interval increased extension of necrotic soft tissue and multiple matted necrotic nodes involving the left hemidiaphragm, pericardial fat pad, pericardium, periaortic, gastrohepatic and peripancreatic regions, which are unprecedented. This lesion shows the direct invasion of the distal oesophagus and gastric cardia, causing proximal oesophageal dilation. Increased extension of tumour thrombus in inferior vena cava extending into the right hepatic vein ascends to the right atrium and extension in the left inferior pulmonary vein reaching into the left atrium. These conditions progress within 3 weeks after the first CT study.

S

9.000 Plany/Coronal Coronal

WC:40 MA:400

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MAS 135

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9800 CF V-Phan/Coronal V-Phase

CT whole abdomen CM

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CT whole dodomen CM

PLAN BOUY 3- 4 RAN PLAIN

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CT Whole fogja 30 CE DELAYED PHASE D PHASE

CT Whole Abdomen OM PHASE V PHASE

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MAS 247

rapid washout on the portovenous phase in the cirrhotic liver background.5

Extremely high-serum AFP was observed, namely, 321 ng/ mL and 495 ng/mL. However, liver and adrenal gland biopsies should be performed regarding atypical features of HCC using CT imaging. The 24-hour urine normetanephrine was investi- gated for preoperative evaluation before performing biopsy at the left adrenal gland and to exclude pheochromocytoma condi- tion. A non-significant elevation of the 24-hour urine norme- tanephrine level was noted; therefore, left adrenal and liver biopsies were performed. Pathological reports revealed carci- noma with hepatocytic differentiation. IHC studies showed immunoreactivity with CAM5.2, arginase-1 and glypican-3, which was focally weakly positive for AE1/AE3 but negative for CK7, CK20, CK19, inhibin A, chromogranin A, synaptophysin, S100 and HepPar-1, (figure 2) similar to related reports (table 1).

DIFFERENTIAL DIAGNOSIS

Distinguishing between adrenocortical carcinoma (ACC) with multiple liver metastases and adrenal HAC is difficult using clin- ical presentation and CT imaging. Both ACC and adrenal HAC

Figure 2 (A) Sections of liver nodule core biopsies show an epithelial neoplasm consisting of the proliferated polygonal epithelial cells arranged in 6-7 cell thick trabeculae and nested separately by flat endothelial lining sinusoidal spaces. The neoplastic cells contain vesicular and slightly pleomorphic irregular thick nuclear membrane nuclei, prominent nucleoli and rare mitoses. Intranuclear cytoplasmic inclusions are noted. Adjacent normal liver parenchyma is present on the right side of the picture. These biopsies appear to have positive stain for AE1/AE3, arginase-1, glypican-3 and CAM5.2, but a negative stain for CK7, CK20, inhibin, S100, synaptophysin or chromogranin A. Hepatocellular carcinoma or hapatoid adenocarcinoma is suggested from these results. (B) Sections of adrenal mass core biopsies show an epithelial neoplasm within a desmoplastic stroma. The adrenal mass shares similar histological features to the liver nodule; positive stain for AE1/AE3, arginase-1, glypican-3 and CAM5.2 and negative stain for CK7, CK20, inhibin, S100, synaptophysin or chromogranin A. No residual non-neoplastic adrenal tissue was present in the core biopsies. Thus, we can conclude the resemblance of both liver nodules and adrenal mass.

H&E

AE1/AE3

Arginase-1

Hep-Par 1

CK7

CK20

Glypican 3

CAM 5.2

A

2

Inhibin

S100

Synaptophysin

Chromogranin A

H&E

AE1/ΑΕ3

Arginase-1

Hep-Par 1

CK7

CK20

Glypican 3

CAM 5.2

B

Inhibin

S100

Synaptophysin

Chromogranin A

are rare and similar in age distribution, the fourth to fifth decade of life. However, men frequently appear to develop HAC more often than women but without sufficient confirmatory evidence. Nevertheless, HAC mostly produces high-serum AFP, ranging from 4730 ng/ml to 700 000 ng/ml as reported in retrospec- tive studies.3 Moreover, liver metastasis at first diagnosis is the most common presentation in HAC. HCC was excluded for this patient due to atypical diagnostic criteria from dynamic CT imaging. In addition, IHC staining proved to be a crucial guide for diagnosis. For epithelial neoplasm negative for CK7 and CK20, ACC and HCC are included. However, ACC should occasionally be shown positive for HepPar-1 staining. More- over, glypican-3 staining maintains a high positive rate in HAC. Therefore, IHC stains for the patient were compatible with primary adrenal HAC.

Table 1 Patient demographics and clinicopathological and treatment characteristics

No Authors	Sex	Age, years Tumour location	Size	AFP, ng/ml	Treatment	Immunohistochemistry	Outcome
1 Current authors	M	47 Left adrenal gland	11.2×15.2×5.5cm3	321 495	Supportive treatment	ΑΕ1/ΑΕ3 ©, arginase-1 ©, CAM5.2 , glypican-3 , HepPar1 4 and Ki-67 20%, alpha-inhibin ℮, chromogranin A ℮, S100 Θ, synaptophysin e	Death at 3 weeks after diagnosis
2 Yoshioka et al6	M	57 Left adrenal gland	8×5 cm2	30 500	Thoracoabdominal nephro- adrenalectomy	N/A	N/A
3 Yi et al *13	M	57 Left adrenal gland	3.5×2.2×2 cm3	570	Surgery	HepPar14, AFP , ferritin @, CEA , CK8 4, CK18 4, «1-ACT, ₡1-AT @	N/A
4 Malya et al1	F	48 Right adrenal gland	4×5 cm2	3900	Surgery+radiotherapy+5FU and gemcitabine	AFP , glipan , CK8 ©©, HepPar1, CK170, CK190, luminal/ focal +, polygonal CEA @	N/A
5 Jing et a/* 14	M	53 Left adrenal gland	13×10×8 cm3	31 353	Oxaliplatin+capecitabine	HepPar1 ©, CK Φ, AFP D, Ki-67 30%, CD34 ©	Alive at 7 months of follow-up
6 Liu et al2	M	60 Right adrenal gland	5×7 cm2	6.39	Surgery	HepPar1 ©, glapican-3 ©, CD34 ©, CK , AFP Θ, a-inhibin Θ, CgA e and CEA	Alive at 30 months of follow- up
7 Zhang and Hua*	M	57 Left adrenal gland	13×10×9cm3	>13 000	Surgery+oxaliplatin+gemcitabine	ΕΜΑ Φ, CK8 Φ, AFP Φ, hepatocyte , CK18 +, CD10 ©	Alive at 7 months of follow-up
8 Lin et al3	M	64 Left adrenal gland	9.3×8.9×9.7 cm3	2.75	mFOLFOX6×4 cycles, transcatheter arterial chemoembolisation, apatinib	TTF-1 6, CK5/6 e, P63 Θ, NSE Θ, synaptophysin , chromogranin A Θ, CK8/18 +, CK19 , CK7 9, CD 20 €, hepatocyte O, vimentin Θ, HepPar1©	Death at 9 months after diagnosis
9 Deng et al	M	83 Left adrenal gland	13×8.7×11 cm3	>24200	Surgery+sorafenib	HepPar1©, glypican-3 ©, AFP D, arginase-1 ©, Ki-67 50%	Death at 9 months after diagnosis

*Published in Chinese. AFP, alpha-fetoprotein; CEA, carcinoembryonic antigen; CK, cytokeratin; EMA, epithelial membrane antigen; 5FU, 5-fluorouracil; N/A, not available; NSE, neuron specific enolase.

TREATMENT

Surgery is the mainstay of treatment for localised disease. Addi- tionally, HAC is chemotherapy and radiation resistant. Therefore, no survival benefit is derived from adjuvant chemotherapy. For systemic treatment among patients with advanced-stage cancer, some case reports showed marginal benefits from chemotherapy such as an oxaliplatin-based regimen (mFOLFOX, or capecit- abine+oxaliplatin),2-4 gemcitabine+oxaliplatin,5 or gemcitabine monotherapy.3 In addition, vascular endothelial growth factor- targeting tyrosine kinase inhibitors (apatinib, sorafenib) were reported for treatment.2 6

OUTCOME AND FOLLOW-UP

The estimated overall survival is 7-9 months.3 However, AFP- producing HAC has a worse prognosis than non-AFP-producing HAC. Our patient did not receive chemotherapy due to his clinical deterioration. The deceased patient developed severe upper GI bleeding from the progression of the primary tumour, invading the stomach before death.

DISCUSSION

The incidence of HAC is about 1.3%-1.5% worldwide.1 Only eight cases have been reported for adrenal HAC since 1994. The first case was reported by Yoshioka et al.6 The clinical charac- teristics were more common among men; age ranging from 47 to 83 years and involving the left adrenal gland. Elevated serum AFP level was common and related to a poor prognosis. The median level of serum AFP was 2235 ng/ml (2.75-30 500 ng/ mL).

Multifocal HCC with adrenal gland metastasis is more common than primary adrenal HA, and distinguishing between them would be difficult. Multifocal HCC could have multi- centric origination or intrahepatic metastases. Some studies have proposed the pathophysiology of multifocal HCC.7 8 Alterna- tively, multifocal HCC is predominantly used to describe only intrahepatic lesions. Thus, HAC may mimic and be indistin- guishable from HCC, especially when liver metastasis occurs. IHC study may not be useful in this circumstance.9 10 Hence, a related study showed that comprehensive gene profiling might be helpful in selected cases.3 However, clinical presentation and imaging may be of major help to determine the primary site of cancer.

In this case, the primary tumour was located in the epicentre of the left adrenal gland with multiple liver metastases, and the clinical presentation mainly occurred from compressive symp- toms from a primary tumour. The functional adrenal tumours, including pheochromocytoma, paraganglioma and hormone- producing adrenal carcinoma, should be excluded before diag- nosing ACC or adrenal HAC.

From related reports, surgical resection was the primary treatment. Several systemic therapies were reported, for example, 5-fluorouracil-based regimen,3 11 gemcitabine-based regimen,11 12 targeted therapy (sorafenib or apatinib)3 4 and tran- sarterial embolisation.3 The median overall survival ranged from 7 to 30 months.

Twitter Tawasapon Thambamroong @ttawasapon

Acknowledgements We acknowledge our patient and his family, the Phramongkutklao Hospital (PMK) Tumor Board, Asst Prof Kasan Seetalarom; Senior Medical Oncologist of Medical Oncology Division, Dr Nattapol Sathavarodom; Endocrinologist of Endocrinology Division, and Clinical Nutrition Division, Department of Internal Medicine, Dr Chatwadee Limpaiboon; Department of

Case report

Learning points

Adrenal hepatoid adenocarcinoma is an extremely rare cancer not easily diagnosed for which multifocal hepatocellular carcinoma, paraganglioma and pheochromocytoma should be excluded.

Surgical resection is preferred for resectable conditions.

There is no standard treatment established for systemic therapy.

Radiology, and Department of Pathology for collaborating to diagnose and treat this patient.

Contributors Manuscript writing, review, diagnosis and treatment-TT. Manuscript writing, diagnosis and treatment-NP and SS. Manuscript writing and dagnosis-KS. Final approval-TT, NP and SS.

Funding The authors have not declared a specific grant for this research from any funding agency in the public, commercial or not-for-profit sectors.

Competing interests None declared.

Patient consent for publication Next of kin consent obtained. Provenance and peer review Not commissioned; externally peer reviewed.

ORCID İD Tawasapon Thambamroong http://orcid.org/0000-0001-6066-4253

REFERENCES

1 Su J-S, Chen Y-T, Wang R-C, et al. Clinicopathological characteristics in the differential diagnosis of hepatoid adenocarcinoma: a literature review. World J Gastroenterol 2013;19:321-7.

2 Liu S, Man Q, Ding K. A rare case of hepatoid adenocarcinoma of the adrenal gland. Int J Clin Exp Pathol 2016;9:4247-50.

3 Lin J, Cao Y, Yu L, et al. Non-o-fetoprotein-producing adrenal hepatoid adenocarcinoma: a case report and literature review. Medicine 2018;97:e12336.

4 Deng X, Jin Y, Yang W, et al. An adrenal Hepatoid adenocarcinoma with left renal vein thrombosis extending into the inferior vena cava. Urol J 2019;16:511-4.

5 Marrero JA, Kulik LM, Sirlin CB, et al. Diagnosis, staging, and management of hepatocellular carcinoma: 2018 practice guidance by the American association for the study of liver diseases. Hepatology 2018;68:723-50.

6 Yoshioka M, Ihara H, Shima H, et al. [Adrenal hepatoid carcinoma producing alpha- fetoprotein: a case report]. Hinyokika Kiyo 1994;40:411-4.

7 Nomoto S, Kinoshita T, Kato K, et al. Hypermethylation of multiple genes as clonal markers in multicentric hepatocellular carcinoma. Br J Cancer 2007;97:1260-5.

8 Wang B, Xia C-Y, Lau W-Y, et al. Determination of clonal origin of recurrent hepatocellular carcinoma for personalized therapy and outcomes evaluation: a new strategy for hepatic surgery. J Am Coll Surg 2013;217:1054-62.

9 Terracciano LM, Glatz K, Mhawech P, et al. Hepatoid adenocarcinoma with liver metastasis mimicking hepatocellular carcinoma: an immunohistochemical and molecular study of eight cases. Am J Surg Pathol 2003;27:1302-12.

10 Kashani A, Ellis JC, Kahn M, et al. Liver metastasis from hepatoid adenocarcinoma of the esophagus mimicking hepatocellular carcinoma. Gastroenterol Rep 2017;5:67-71.

11 Malya FU, Bozkurt S, Hasbahceci M, et al. A rare tumor in a patient with hepatic hydatic cyst: adrenal hepatoid adenocarcinoma. Case Rep Med 2014;2014:1-4.

12 Zhang R, Hua J. One case of left adrenal hepatoid adenocarcinoma. Chin J Endocrinol 2016;6:527-8.

13 Yi L, Jiangyang L, Xiaohong W. Clinicopathological observation of adrenal hepatoid adenocarcinoma. Diagn Pathol J 2009.

14 Jing L, Rui Z, Ping Z. Clinical and pathological observation of adrenal Hepatoid adenocarcinoma practical cancer journal. , 2015: 02, 194-7.

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