Infiltrative hepatocellular carcinoma with multiple lung metastasis completely cured using nivolumab: a case report

Article information

J Liver Cancer. 2021;21(2):169-176
Publication date (electronic) : 2021 September 30
doi : https://doi.org/10.17998/jlc.2021.08.26
Department of Gastroenterology, Ajou University School of Medicine, Suwon, Korea
Corresponding author: Hyo Jung Cho, Department of Gastroenterology, Ajou University School of Medicine, 164 Worldcup-ro, Yeongtong-gu, Suwon 16499, Korea, Tel. +82-31-219-6939, Fax. +82-31-219-7820, E-mail: pilgrim8107@hanmail.net
Received 2021 June 5; Revised 2021 August 5; Accepted 2021 August 26.

Abstract

The current Food and Drug Administration-approved systemic treatments for advanced hepatocellular carcinoma (HCC) include multikinase inhibitors (tyrosine kinase inhibitor [TKI]) and immune checkpoint inhibitors (ICIs). Among ICIs, nivolumab is used as second-line therapy for advanced HCC after sorafenib failure or patient intolerance. In this case, a patient with infiltrative HCC and portal vein tumor thrombosis was treated with hepatic arterial infusion chemotherapy (HAIC) and radiation therapy. New lung metastasis developed after HAICs; thus, lenvatinib treatment was initiated. However, the disease progressed. Thereafter, sorafenib treatment was initiated but he developed intolerance, with grade 3 sorafenib-related diarrhea. Subsequently, nivolumab was administered as rescue therapy. He demonstrated a partial response to nivolumab after the third treatment and viable HCCs in the lungs and liver completely disappeared after the 24th treatment. These findings suggest that nivolumab could be used as an effective rescue therapy for advanced HCC progression after TKI treatment.

INTRODUCTION

Hepatocellular carcinoma (HCC) is the fourth most common cause of cancer-related mortalities worldwide. HCC originates from various etiologies, such as hepatitis B virus (HBV), hepatitis C virus, and alcoholic and non-alcoholic fatty liver, and usually develops from advanced chronic liver disease or cirrhosis. HCC is often accompanied by the deterioration of hepatic function or portal vein tumor thrombosis (PVTT).13 Moreover, HCC undergoes multi-step genetic modification as it progresses.4 Subsequently, it exhibits intratumor heterogeneity, does not respond to specific molecular targeted therapy, and often exhibits poor prognosis, especially when accompanied by PVTT or extrahepatic metastases.

Various HCC guidelines recommend sorafenib and lenvatinib as Food and Drug Administration (FDA)-approved multi-tyrosine kinase inhibitors (TKIs) for the first-line treatment of advanced HCC. Recently, immune checkpoint inhibitors (ICIs), which target programmed cell death 1 protein or programmed death-ligand 1 (PD-L1), have also been used as a systemic treatment for advanced HCC following the demonstration of their high efficacy and safety through various clinical trials.

Based on the results of the CheckMate-040 trial, nivolumab, a monoclonal antibody against PD-1, was approved by the FDA in 2017 as a second-line therapy for patients with advanced HCC that progressed even after sorafenib treatment or sorafenib intolerance.5 CheckMate-040 was an open-label multicenter clinical trial involving 154 patients with advanced HCC that progressed even after sorafenib treatment or due to sorafenib intolerance. In this trial, nivolumab treatment after sorafenib failure exhibited durable response, prolonged overall survival, and manageable safety profile.

Here, we report a case of advanced HCC with PVTT and multiple lung metastases, which demonstrated a complete response (CR) to nivolumab administered after the failure of hepatic artery infusion chemotherapy (HAIC), and lenvatinib, and sorafenib treatments. This case report is described according to the CARE guidelines (https://www.care-statement.org/).

CASE REPORT

A 56-year-old male patient was referred from a local clinic to our hospital for suspected infiltrative HCC with PVTT occupying the entire sixth segment of his liver, as observed on computed tomography (CT) and magnetic resonance imaging (MRI). He was also diagnosed with chronic hepatitis B and liver cirrhosis for the first time.

Liver MRI showed that approximately 10 cm of the heterogeneous mass was partially enhanced, with most of the mass exhibiting high signal intensity in the delayed arterial phase. The mass started to exhibit a low signal intensity in the transitional phase, with a low signal in the hepatobiliary phase and a high signal in diffusion-weighted images. Additionally, a right portal vein thrombus, which was partially expansile to the main portal vein, was observed in the delayed arterial phase (Fig. 1). The patient was staged as Modified Union for International Cancer Control stage III, T3N0M0, and Barcelona Clinic Liver Cancer (BCLC) stage BCLC C.

Figure 1

Hepatocellular carcinoma at initial diagnosis in order of abdomen, chest computed tomography (CT) and liver magnetic resonance imaging (MRI). Abdominal CT showing a single mass (arrows) on segment 6 with enhancement in the arterial phase (A) and wash-out on the delayed phase (B). Chest CT (C) showing no lung metastasis on initial diagnosis. Liver MRI showing a single mass (arrow) with an expansile tumor thrombus partially extending from the right portal vein to the main portal vein in the delayed arterial phase (D) of T1-weighted images. Transitional phase (E). T2-weighted image (F). Hepatobiliary phase (G). Diffusion-weighted image (b=800) (H).

In the initial lab tests, HBV DNA was not detected, the α-fetoprotein (AFP) level was above 60,500 ng/mL, and the protein level induced by vitamin K absence-II (PIVKA-II) level was 58,341 mAU/mL. The prothrombin time was 13.2 seconds, the albumin level was 4.1 g/dL, the total bilirubin level was 0.9 mg/dL, the alanine aminotransferase level was 63 IU/L, and the aspartate aminotransferase level was 86 IU/L. The patient did not have a history of hepatic encephalopathy or ascites. Therefore, his liver function was considered good, with a Child-Pugh score of 5, Class A. His performance status was also good, with an Eastern Cooperative Oncology Group status score of 0.

Based on the results of clinical studies reporting that hepatic artery injection chemotherapy combined with RT was not inferior to sorafenib in patients with advanced HCC with PVTT,5,6 HAIC combined with RT was performed as the first-line therapy. For HAIC, 5-FU 500 mg/m2 for 3 days and cisplatin 60 mg/m2 for 1 day were used as a fixed dose and administered twice at 4-week intervals. Radiation therapy was performed for the tumors in segment 6 and the PVTT. The total dose of 3,900 cGy was administered 13 times at 300 cGy each.

After 2 cycles of HAIC combined with RT, the portion of viable tumor exhibiting enhancement and the size of the PVTT had decreased on liver dynamic CT. However, as multiple lung metastases and new primary HCC were identified in segment 8, the patient was considered to have progressive disease based on the modified Response Evaluation Criteria in Solid Tumors (modified RECIST) for HCC (Fig. 2).

Figure 2

A change in the portal vein tumor thrombus, newly developed hepatocellular carcinoma (HCC), and lung metastasis in liver dynamic computed tomography after HAIC with radiation therapy (RT). (A, B) Shrinkage of viable tumor and portal vein tumor thrombus (red arrow) after hepatic artery infusion chemotherapy (HAIC) with RT. (C, D) Multiple lung metastases (yellow arrow) after HAIC with RT. (E) New primary HCC (yellow arrow) in segment 8 after HAIC with RT.

Lenvatinib (Lenvima®, 12 mg per day; Eisai Co., Ltd., Tokyo, Japan) was administered for 3 months as the first-line systemic therapy. However, the follow-up liver dynamic CT showed increased arterial enhancement in a portion of the existing primary HCC, which was considered to be the viable portion of the tumor, in addition to PVTT progression. Additionally, multiple lung metastases had progressed and new HCCs were observed in several segments, which corresponded to disease progression according to modified RECIST (Fig. 3).

Figure 3

Progression of hepatocellular carcinoma (HCC), portal vein tumor thrombus (PVTT), and lung metastases in liver dynamic computed tomography (CT) after lenvatinib therapy. Follow-up liver dynamic CT showing increase in the arterial enhancing portion of the existing primary HCC (red arrow) and PVTT (B) compared to before lenvatinib therapy (A). Additionally, new HCCs (yellow arrows) are visible in several hepatic segments (C–E) and multiple lung metastases show progression (yellow arrows) (F, G).

Therefore, sorafenib (Nexavar®, 400 mg twice daily; Bayer, Leverkusen, Germany) was administered as the second-line systemic therapy. However, the patients developed grade 3 sorafenib-induced diarrhea after treatment initiation, which persisted even dose reduction. Therefore, the sorafenib treatment was terminated.

Nivolumab (Opdivo®, 3 mg/kg after every 2 weeks; Ono pharmaceutical, Osaka, Japan) treatment was then initiated as the third-line systemic therapy. The serum AFP and PIVKA-II levels decreased continuously from the first administration (Fig. 4A). After the third administration, the size and number of multiple lung metastases had decreased in follow-up CT, which corresponded to partial regression according to modified RECIST. The AFP and PIVKA-II levels decreased to 9,780 ng/mL and 87 mIU/mL, respectively. Follow-up CT performed after the 18th administration of nivolumab showed that multiple pulmonary nodules had disappeared, along with the arterial enhancing HCC (Fig. 5).

Figure 4

Changes in α-fetoprotein (AFP) and protein induced by vitamin K absence-II (PIVKA-II) levels as well as liver function during nivolumab therapy. Serum AFP and PIVKA-II levels decreased continuously from the first administration of nivolumab. (A–D) Preserved liver function during nivolumab therapy.

Figure 5

Complete disappearance of multiple lung metastases (arrows) on chest computed tomography after the 18th nivolumab treatment. Multiple pulmonary nodules disappeared after the 18th administration of nivolumab (B, D) compared to before nivolumab therapy (A, C).

Twenty-four doses of nivolumab were administered without any side effects, including impaired liver function (Fig. 4B–D). The last liver MRI showed no evidence of viable tumors exhibiting arterial enhancement in the liver. The expansile PVTT had also contracted and all multiple pulmonary nodules had disappeared (Fig. 6). The serum AFP and PIVKA-II levels were also maintained at normal levels.

Figure 6

Liver magnetic resonance imaging after the 24th nivolumab treatment, showing no evidence of viable tumors exhibiting arterial enhancement in the liver and contracted expansile portal vein tumor thrombus. (A) T1-weighted image, hepatic arterial phase. (B) Portal venous phase. (C) Delayed phase. (D) T2-weighted image. (E) Hepatobiliary phase. (F) Diffusion-weighted image (b=800).

Ethics statement

The Institutional Review Board of Ajou University waived the requirement for ethics approval and informed consent (IRB number: AJIRB-MED-EXP-21-379).

DISCUSSION

HCC with PVTT occurs in 44.0–62.2% of cases7 and often causes distant metastasis.8 The lung is the most common organ for HCC metastasis, accounting for 51% of all extrahepatic metastases.9 Patients with PVTT or extrahepatic metastases are classified as BCLC stage C and are considered potential candidates for systemic therapy.10

Based on the underlying feature of the cirrhotic liver; namely, an immunosuppressive environment that protects cancer cells from being recognized by the immune system, the immunotherapies like ICIs provide a strong rationale for HCC treatment. Immune checkpoints normally prevent the activation of uncontrolled autologous immunity by suppressing T cell activation. The overexpression of immune checkpoint molecules by cancer cells is a critical mechanism through which tumor cells evade immune surveillance.11 PD-1 is an immunosuppressive receptor expressed on activated T cells, B cells, NK cells, regulatory T cells (Tregs), myeloid-derived suppressor cells, and dendritic cells. ICIs block the inhibitory immune checkpoints and ultimately trigger an immune response targeting tumor tissue.11,12

Multiple ongoing phase I–III clinical trials are evaluating ICI monotherapy for the treatment of advanced HCC.13,14 Several clinical studies are evaluating nivolumab as monotherapy and combination therapy for advanced HCC.15 CheckMate-459, a randomized, multi-center phase III controlled trial, evaluated nivolumab as the first-line treatment for advanced HCC. However, nivolumab did not reach statistical significance for overall survival compared to sorafenib, despite exhibiting the clinical benefits of improved objective response rate, long-time disease control, fewer adverse events, and survival benefit.16 Only a subset of patients with advanced HCC experience clinical benefits through TKIs or ICIs therapy. However, several cases of CR from advanced HCC following the administration of nivolumab have been reported.1719 As nivolumab was approved as second-line therapy after sorafenib failure in advanced HCC patients, nivolumab was administered in two cases with advanced HCC with preserved liver function after sorafenib failure. Another case in a patient with decompensated cirrhosis achieved CR after nivolumab as the first-line treatment.19 Since the reported CR cases are diverse in terms of underlying liver disease, prior treatment, and underlying liver function, it is difficult to infer commonalities from the fragmentary clinical or laboratory characteristics. Nevertheless, there may be a common specific immunological feature among patients who achieve a CR with nivolumab. Elucidating this immunological feature may lead to the development of a potential predictive biomarker and therapeutic target to overcome ICI resistance.

The patient in the present case was treated with HAIC and TKI before nivolumab. Previous studies reported that radiotherapy and chemotherapy can exert tumor immune response. 20 These therapies damage cancer cells, leading to ROS or endoplasmic reticulum stress medicated cellular stress and subsequent immunogenic cell death. This can contribute to the transformation of immunologically “cold” tumors to “hot” tumors and improve their response to ICI treatment.20 In the present case, the prior HAIC, RT, and TKI treatment may have affected the CR with nivolumab; however, this is only a case report limited to our study. Further studies are needed to identify a possible role of prior or concomitant HAIC, TKIs, and/or RT in the antitumor effects of ICI treatment in patients with advanced HCC.

Here, we report a case of CR after nivolumab therapy, which had progressed during HAIC and TKI treatment. The findings of the present case suggest that nivolumab could be used as an effective rescue therapy for patients with HCC who demonstrate disease progression after TKI treatment.

Notes

Conflicts of Interest

The authors have no conflicts of interest to disclose.

Ethics Statement

The Institutional Review Board of Ajou University waived the requirement for ethics approval and informed consent (IRB number: AJIRB-MED-EXP-21-379).

Funding Statement

No funding to declare.

Data Availability

Data sharing not applicable to this article as no datasets were generated or analyzed for this case report.

Author Contribution

Conceptualization: JEH, HJC

Data curation: HJC, SSK, JYC

Methodology: HJC, SSK, JYC

Project administration: HJC, SSK, JYC

Writing original draft: JEH

Writing review & editing: HJC

Approval of final manuscript: all authors.

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Article information Continued

Figure 1

Hepatocellular carcinoma at initial diagnosis in order of abdomen, chest computed tomography (CT) and liver magnetic resonance imaging (MRI). Abdominal CT showing a single mass (arrows) on segment 6 with enhancement in the arterial phase (A) and wash-out on the delayed phase (B). Chest CT (C) showing no lung metastasis on initial diagnosis. Liver MRI showing a single mass (arrow) with an expansile tumor thrombus partially extending from the right portal vein to the main portal vein in the delayed arterial phase (D) of T1-weighted images. Transitional phase (E). T2-weighted image (F). Hepatobiliary phase (G). Diffusion-weighted image (b=800) (H).

Figure 2

A change in the portal vein tumor thrombus, newly developed hepatocellular carcinoma (HCC), and lung metastasis in liver dynamic computed tomography after HAIC with radiation therapy (RT). (A, B) Shrinkage of viable tumor and portal vein tumor thrombus (red arrow) after hepatic artery infusion chemotherapy (HAIC) with RT. (C, D) Multiple lung metastases (yellow arrow) after HAIC with RT. (E) New primary HCC (yellow arrow) in segment 8 after HAIC with RT.

Figure 3

Progression of hepatocellular carcinoma (HCC), portal vein tumor thrombus (PVTT), and lung metastases in liver dynamic computed tomography (CT) after lenvatinib therapy. Follow-up liver dynamic CT showing increase in the arterial enhancing portion of the existing primary HCC (red arrow) and PVTT (B) compared to before lenvatinib therapy (A). Additionally, new HCCs (yellow arrows) are visible in several hepatic segments (C–E) and multiple lung metastases show progression (yellow arrows) (F, G).

Figure 4

Changes in α-fetoprotein (AFP) and protein induced by vitamin K absence-II (PIVKA-II) levels as well as liver function during nivolumab therapy. Serum AFP and PIVKA-II levels decreased continuously from the first administration of nivolumab. (A–D) Preserved liver function during nivolumab therapy.

Figure 5

Complete disappearance of multiple lung metastases (arrows) on chest computed tomography after the 18th nivolumab treatment. Multiple pulmonary nodules disappeared after the 18th administration of nivolumab (B, D) compared to before nivolumab therapy (A, C).

Figure 6

Liver magnetic resonance imaging after the 24th nivolumab treatment, showing no evidence of viable tumors exhibiting arterial enhancement in the liver and contracted expansile portal vein tumor thrombus. (A) T1-weighted image, hepatic arterial phase. (B) Portal venous phase. (C) Delayed phase. (D) T2-weighted image. (E) Hepatobiliary phase. (F) Diffusion-weighted image (b=800).