Relapse with isolated peritoneal metastasis in lung adenocarcinoma: case report and review of the literature

Introduction

Lung cancer, which is among the most common tumors in adults, accounts for 12.4% of all new cancer cases worldwide, exhibiting one of the highest rates of mortality [1]. Of the patients with lung cancer, approximately 40% have metastases, presenting the main cause of mortality. The most common regions of metastasis are the pleura, lung parenchyma, skeletal system, liver, brain, and adrenal glands [1]. Metastasis to the peritoneum is rarely encountered during the clinical course of lung cancer, and there are limited treatment alternatives for such cases [1, 2].

Compared with pleural metastasis, peritoneal involvement is rarely encountered in lung carcinoma. In fact, peritoneal involvement may be asymptomatic and may only be determined through imaging techniques, although it may have a severe clinical course with high incidence of morbidity and mortality. Definite diagnosis of peritoneal involvement is confirmed by the presence of malignant cells in the peritoneal fluid [1, 2].

Metastatic involvement of other areas is common and expected in cancer patients in whom peritoneal metastases develop [1, 2]. To the best of our knowledge, there are no studies in the literature describing a lung cancer patient with a relapse in the peritoneal region but without metastases to distant and anticipated sites. Herein, we aimed to present a rare case of non-small cell lung carcinoma involving the peritoneum and to discuss, in light of the current limited literature, our patient who had an unusual course presenting with metastasis to the peritoneal surface without involvement of other regions.

Case report

A 59-year-old man presented to the chest diseases clinic of another hospital with fatigue, dyspnea, and hemoptysis, which began a few months earlier. Chest x-ray at that time showed increased density in the inferior right lung. Thoracic computed tomography (CT) confirmed that finding, based on observation of a 4 × 3-cm soft tissue mass that was obstructing the postero-basal segment and apical bronchus segment below the carina, an atelectatic area with pleural fluid, as well as multiple para-aortic and paratracheal lymphadenopathies (LAP) proximal to the carina, the largest of which was 1 × 1 cm. Bronchoscopic analysis showed blunting at the carina, mucosal tram-lines in both bronchi, and external compression of the right lung, particularly the lateral and posterior segments, but endobronchial lesions were not observed. Histopathological examination of transbronchial biopsy material showed adenocarcinoma, and then the patient was referred to our department.

The patient, a chemical engineer, did not have a history of any comorbidity other than diabetes mellitus for the past 5 years, which was managed with oral antidiabetics. As an ex-smoker for the last 10 years, the patient previously smoked 25 packs/year and did not use alcohol. He had no family history of cancer, and exposure to asbestosis was negative. His performance status was Eastern Cooperative Oncology Group (ECOG) 1, blood pressure was 130/85 mm Hg, and heart rate was 92 bpm and rhythmic. Physical examination did not show any pathological findings, except a coarse respiratory sound in the right hemithorax (posterior and lateral regions) and sporadic inspiratory rales. Serum lactate dehydrogenase level was 324 U/l (normal range: 125–243 U/l), and other routine laboratory parameters were normal. Distal organ metastases were not noted with whole-body bone scintigraphy and abdominal and cranial CT. He was staged as T2N2M0 (Stage IIIA).

The patient was administered neoadjuvant chemotherapy (28-day cycle) – cisplatin 80 mg/m² (day 1) and gemcitabine 1000 mg/m² (days 1, 8, and 15). According to the follow-up thoracic CT, the patient achieved a partial response following 2 cycles of the therapy, and then an additional cycle was administered. He was admitted to another hospital due to progressive shortness of breath, as well as heart palpitations present for the last five days. Physical examination revealed congested jugular, shortness of breath, orthopneic posture, and 1+ pitting edema in the bilateral pretibial areas. His arterial pressure was low (90/60 mm Hg) and the heart beat rate was high (142/min). Prominent low voltage QRS complexes in all derivations were obtained on electrocardiogram. The patient underwent echocardiographic examination and pericardial effusion was observed. One hundred and fifty milliliters of bloody fluid were removed by echocardiography guided needle aspiration. Adenocarcinoma cells were noted based on cytological evaluation of the pericardial fluid (Fig. 1).

Positron emission tomography (PET)-CT for assessment showed a 36-mm hypermetabolic (SUVmax = 4.8) lymph node in the subcarinal region that extended through the right intermediate bronchus posterior wall, a 51.6-mm mass density increase that resulted in the collapse of all peripheral basal segments and increased glycolytic activity (SUVmax = 5.9) in the internal structure of the suprahilar region peripheral to the basal segment bronchi, as well as the presence of minimal pericardial fluid. Clinically staged T4 (with malignant pericardial tamponade) N2M0, surgery was deemed inappropriate for the patient and he received 30-Gy palliative radiotherapy for the primary tumor and mediastinum. Response assessment after radiation treatment showed that there was a reduction in the mass formation around the right lung’s inferior lobe apical segment and posterobasal segment bronchus. Lymph nodes noted in the carina during the previous analysis were not present; however, diffuse peritoneal fluid was a new finding. As such, cytological analysis of the paracentesis fluid was performed and poorly differentiated carcinoma cells forming sporadic adenoid-like structures were noted (Fig. 2). The serum acid-albumin fraction was 0.8. The patient did not have hepatic metastases, portal hypertension, or peripheral edema. Echocardiography did not demonstrate pericardial fluid or left ventricular systolic dysfunction. The patient was thought to have peritoneal carcinomatosis. The case relapsed with involvement of the peritoneum only, without metastases at other sites that are often involved in lung cancer, and a second opinion for diagnosis of malignant mesothelioma was requested from the pathology department. The patient’s transbronchial biopsy specimen tumor cells immunohistochemically stained positive with cytokeratin 7 and thyroid transcription factor-1, but did not stain with cytokeratin 5/6. Tumor cells in pericardial and peritoneal fluid had similar morphology as the adenocarcinoma cells obtained via transbronchial biopsy. Malignant mesothelioma was ruled out based on these findings and the final diagnosis of primary lung adenocarcinoma was made. Then, second-line treatment (21-day cycle) with docetaxel (75 mg/m² on day 1) was started. The patient could only receive 1 cycle of this chemotherapy regime and died.

Discussion

Although ascites can be seen at relapse in lung cancer, the incidence of isolated peritoneal carcinomatosis without metastases in other parts of the body is very low [1, 2]. A search of the literature showed that only 1 case report and 2 individual case analyses regarding peritoneal involvement have been published [1, 3, 4]. There are no published reports of lung cancer cases with involvement of only the peritoneum without metastases to other more common regions [2, 5, 6].

Although the frequency of peritoneal metastases in au­to­psy series is 2.7–16%, in clinical studies it is 1–2% [1]. Satoh et al. evaluated 1041 patients with lung cancer and reported that 1.2% (n = 12) of the patients had clinically verified peritoneal carcinomatosis [4]. Peritoneal carcinomatosis has been reported in cases of non-small cell lung cancer. Peritoneal carcinomatosis was also reported relatively more frequently in association with adenocarcinoma subtypes [1]. Although small cell lung cancer is known to be the most aggressive subtype with the highest incidence of metastases, it is reported less frequently in peritoneal metastases series, probably due to characteristic occurrence of diffuse metastases at an early stage and short clinical duration. In their analysis of 30 patients with lung cancer and peritoneal metastases, Su et al. reported that 26 of the patients (86.6%) had adenocarcinoma type, of which 20 were stage IV and 6 were stage IIIB. In that series only 3 patients had small cell subtype lung carcinoma, 1 had combined small cell/squamous cell lung carcinoma, and 1 had a pancreatic metastasis together with peritoneal carcinomatosis [1]. Based on explorative laparotomy, Sakar et al. described a patient with pancreatic metastasis and another with small cell lung carcinoma in the peritoneum that were studied for icterus [7].

Lung cancer can either spread locally and involve nearby tissues, such as the cavity outside the lungs (pleural space), or layers around the heart, or may travel to distant sites by vascular, lymphatic and transcoelomic routes/along serous membranes [1].

In patients with lung cancer signs and symptoms including abdominal distress, distension, and pain together with respiratory distress, as well as ileus, peripheral edema, nausea, and vomiting, were reported to be associated with peritoneal involvement. Su et al. reported that among their patients with peritoneal carcinomatosis 93.3% had abdominal distension, 23.3% had pretibial edema, 20% had constipation and ileus, 20% had abdominal pain and distress, and 6.7% had nausea/vomiting; however, metastases were diagnosed with CT performed to assess treatment response before clinical signs and symptoms were observed [1]. In the present case there was only abdominal discomfort at the time peritoneal carcinomatosis was diagnosed. No pronounced symptoms were noted with imaging techniques that were used to determine staging and response in the peritoneal region.

Ascites development is often described during late stages of the disease, following diagnosis in patients with serosal involvement other than pleural metastases. Su et al. noted ascites at baseline in only 4 of 30 patients, whereas they observed the development of peritoneal carcinomatosis after 253 days (range: 0–1156 days) following diagnosis in other patients [1]. This period was 214 days in the present case, which is close to the previously reported mean.

It was reported that malign pleural fluid developed before the diagnosis of peritoneal carcinomatosis or malign pericardial effusion in 80% of patients with lung cancer and that distal organ involvement was also common [1, 2, 6]. In the present case, however, there were no findings of metastases in the bone, liver, brain, or other regions at the time peritoneal carcinomatosis was diagnosed. Given that peritoneal cytological examinations were positive during the clinical course, it would be reasonable to assume that the minimal pleural fluid shown by the baseline CT, which disappeared after chemotherapy, was most probably malignant.

Malignant mesothelioma is often associated with asbestos exposure. It is a tumor that originates from serosal surfaces such as the pleura, pericardium, peritoneum, and tunica vaginalis, and is frequently fatal [8]. In particular, differentiation between epithelioid malignant mesothelioma and primary lung adenocarcinoma that infiltrates the pleura or metastatic adenocarcinoma must be done. Due to the pre-determined isolated serosal infiltration in the present case, malignant mesothelioma was included in the differential diagnosis. Unfortunately, recognizing epithelioid mesothelioma is difficult because it shares similar microscopic properties with adenocarcinoma. As such, immunohistochemical staining patterns were important in the differential diagnosis. An immunohistochemical technique that facilitates the diagnosis of epithelioid malignant mesothelioma by itself has not been reported [8, 9]. Despite this, the most commonly accepted immunohistochemical markers for the diagnosis of mesothelioma are reported to be calretinin and cytokeratin 5/6 [9]. Ordonez reported cytokeratin 5/6-positive staining in all of their 60 malignant mesothelioma patients, but nonetheless only 1 of the 50 patients with adenocarcinoma stained positive with cytokeratin 5/6 [10]. King et al. reported that none of their 240 patients with malignant mesothelioma stained with TTF-1, while 281 of 366 (77%) patients with lung adenocarcinoma stained positive with TTF-1 [11]. Nearly 25% of primary lung adenocarcinoma cases do not stain with TTF-1. Nonetheless, the existence of this immunohistochemical staining feature alone is regarded as sufficient to make a diagnosis of primary adenocarcinoma [9]. The present case did not have a history of asbestos exposure. Re-evaluation of the transbronchial biopsy specimen used for the initial diagnosis showed that there was positive staining for cytokeratin and TTF-1, whereas the tumor cells did not stain with cytokeratin 5/6, which rules out a diagnosis of mesothelioma.

Median survival was reported as 2 months following peritoneal carcinomatosis in lung cancer patients [1, 2, 5]. Su et al. reported that median survival was 14.7 days in patients followed up with conservative therapy and 127.3 days in those who received aggressive treatment [1]. These data indicate a significant difference in survival between patients administered conservative and aggressive treatments. As other regions of metastases are also often involved in patients with peritoneal carcinomatosis, aggressive systemic treatment seems unfeasible, as performance scores are low in such patients. Four patients with adenocarcinoma and good performance scores were followed up with 4-week gefitinib treatment, and clinically good responses were achieved [1]. The second line option in the present case was docetaxel, as the patient used to be a smoker, gefitinib had not obtained approval for this type of use in our country, and other active chemotherapy options were still available.

In conclusion, peritoneal carcinomatosis in patients with lung cancer occurs quite infrequently and is usually accompanied by other systemic metastases. The case presented here is unusual, as the patient developed isolated peritoneal involvement while receiving treatment for peritoneal metastases. This case suggests that pleural metastases may respond better to systemic treatment than other serosal regions in lung adenocarcinoma.



The authors declare no conflict of interest.

References

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Address for correspondence



Ozgur Tanriverdi

Department of Medical Oncology

Mugla Sitki Kocman University Education and

Research Hospital

Mugla, Turkey

tel. +90 256 444 12 56 (1091)

fax +90 256 213 17 05

e-mail: ozgurtanriverdi@hotmail.com



Submitted: 23.05.2011

Accepted: 2.04.2012