Abstract
Malignant pleural mesothelioma (MPM) is a tumour which, despite progress in diagnostic procedures and biomolecular research, has poor prognosis. Symptoms reflect extension of disease and include shortness of breath and chest pain. Unexplained pleural effusion and pleural pain in patients exposed to asbestos should raise the suspicion of MPM. MPM diagnosis requires imaging procedures X-ray and computed tomography (CT) scans; magnetic resonance imaging (MRI) better defines the extension of the tumor while PET scanning provides additional information on metabolic activity, metastases, and response to treatment. Thoracoscopic biopsy remains the most appropriate procedure for definitive diagnosis of mesothelioma. Multimodality treatment including surgery, chemotherapy and radiotherapy has been associated with a better survival in selected patients. Clinical translational research including new approaches targeting immune-checkpoints is opening new horizons which may lead to personalised treatments.
Keywords: Pleural mesothelioma, malignant pleural mesothelioma (MPM), clinical diagnosis
Introduction
Malignant pleural mesothelioma (MPM) is a solid tumor originating from pleural mesothelial cells. It is associated with previous asbestos exposure; delayed onset of MPM following fibre exposure (up to 40 years) makes screening for the disease challenging (1). A slight increase in incidence has been observed over the last 10 years. An estimate based on 2008 data suggested an average of 14,200 cases worldwide each year. Total incidence is highest in the United States and United Kingdom although, per capita, Australia and Italy also rank highly (1,2). Most patients present at diagnosis with advanced disease; prognosis is poor with a median survival ranging from 7 to 12 months with supportive care or chemotherapy, respectively (3).
Epithelioid, sarcomatoid, and mixed or biphasic are the three major histological subtypes of MPM with sarcomatoid type exhibiting the worse prognosis (4).
In the present paper, we describe the pathogenesis, clinical features and diagnostic procedures of MPM, including imaging and invasive exams to achieve disease diagnosis.
Pathogenesis
Asbestos is the major carcinogen associated with MPM. Cancer occurs initially on the parietal surface and several pathogenetic mechanisms have been proposed (5): (I) asbestos fibres are able to irritate the pleura inducing scarring or progression to malignancy (6); (II) asbestos fibres are able to penetrate mesothelial cells, interfere with mitosis and generate mutations in DNA, altering chromosome structure (7); (III) asbestos triggers the production of oxygen free radicals responsible for intra-cellular DNA damage and disruption of repair mechanisms (8); (IV) asbestos is able to interfere with early-response proto-oncogenes which in turn promote abnormal cellular proliferation through mitogen-activated protein (MAP) kinases and extracellular signal–regulated kinases (ERK) 1 and 2 pathways (9).
Additional environmental risk factors have been implicated in MPM development such as prior radiation exposure, other mineral fibers, such as Erionite, synthetic materials (ceramics, nanoparticles), etc. (5,10).
Furthermore, familial forms with autosomal dominant inheritance have been reported (5).
In addition, simian virus 40 (SV40) has also been reported as a potential cofactor in the pathogenesis of MPM, although its role remains controversial (11).
Clinical presentation
MPM symptoms are non-specific and may mimic other respiratory disease (12,13). The majority of patients with MPM present with breathlessness, chest pain, weight loss and fatigue (14,15).
Symptoms may be due to Ipsilateral Pleural Involvement (Parietal/Visceral), Intrathoracic Spread, Trans-Diaphragmatic Extension, Distant Spread, and Paraneoplastic Syndromes.
Shortness of breath is often initially due to pleural effusion; encasement caused by growing intrathoracic tumor is the major cause of breathlessness as disease progresses (16).
Thoracic pain is common and multifactorial in MPM. Tumour invasion of chest wall may cause bone pain and neuropathic pain when tumour invades neural intercostal, paravertebral or brachial plexus structures.
Symptoms associated with advanced stage of disease include weight loss, fatigue, cachexia, fevers and night sweats; at this stage thrombocytosis, hypoalbuminemia, elevated erythrocyte sedimentation rate, and anaemia (3,5) are often detected.
MPM occurs initially unilaterally and local invasion of neighbouring structures including lymph node involvement may result in superior vena cava syndrome, pericardial effusion and subsequent cardiac tamponade, spinal cord compression as well as a subcutaneous involvement. The affected site becomes fixed and cannot expand. Further MPM progression may involve invasion of contralateral pleural cavity and peritoneum. Compared with lung cancer, distant metastases are usually rare since patients die before metastases occur (1,2).
Only a small number of patients are asymptomatic at diagnosis, having an incidental detection of abnormality on imaging undertaken for a different reason. They appear to have longer survival than symptomatic patients, probably because they are diagnosed earlier in the disease process (1). For this reason, it is important to carefully assess patients with a background of previous asbestos exposure who present with an unexplained pleural effusion. A proportion of these patients will develop MPM over time, and active follow-up increases the chance of early diagnosis and prompt treatment.
Diagnostic procedures
Standard diagnostic work-up in patients with MPM includes Chest X-ray, computed tomography (CT) scan of chest and upper abdomen, PET, MRI to define the extension of the disease. Invasive procedures are required to obtain specimens for a definitive histological and bio-molecular diagnosis. Additional investigations include blood markers and pulmonary function tests (17-19).
Chest X-ray
Chest radiography (CXR) is usually the first investigation performed. Typical findings include pleural effusion with loss of hemithoracic volume and occasionally nodular pleural thickening, irregular fissural thickening or a localised mass lesion (1-4). However, it has a low sensitivity and further imaging is usually required. Figure 1 reports a case of MPM followed-up through poster anterior chest XR images from diagnosis to disease.
Figure 1.
Poster anterior CXR follow-up images of progressive malignant pleural mesothelioma (MPM) in a 61-year-old female. (A) Baseline unilateral (left side) pleural effusion; (B) after 3 months, more diffuse pleural thickening and pleural masses; (C) after 5 months, further ipsilateral volume loss of the left hemithorax with elevation of the ipsilateral hemidiaphragm, ipsilateral mediastinal shift, and narrowing of the intercostal spaces; (D) after 8 months, contralateral spread of disease. CXR, chest radiography.
Thoracic ultrasound (US)
Thoracic US allows both evaluation of pleural fluid volume and detection of lesions on the pleura or diaphragm. Pleural-based mass lesions, pleural thickening >1 cm, nodular pleural thickening and diaphragmatic nodularity have a specificity of >95% with regard to malignancy but, as with chest X-ray the sensitivity is low at 40% and further investigations are needed if MPM is suspected (1,20).
CT scan
CT scanning at diagnosis often shows pleural effusion at disease site, pleural thickening and involvement of the interlobar fissure and invasion of the chest wall. A recent review of diagnostic performance of CT reported a sensitivity and specificity of 68% and 78%, respectively, for pleural malignancy (21). CT cannot differentiate MPM from metastatic pleural malignancy, although circumferential pleural thickening and mediastinal pleural involvement are more frequent in MPM.
Magnetic resonance imaging (MRI)
MRI has superior soft tissue contrast over CT (20). Gadolinium contrast agent may improve delineation of T3 disease and visualize potential neoplastic foci in the diaphragm, pericardium or chest wall (22); it is particularly indicated when surgical resection is part of treatment plan.
Of the available MRI techniques, diffusion-weighted MRI (DWI), is the most promising strategy for evaluating tumor extension and response to treatment. This technique relies on tissue variability of water motility which is quantified using the apparent diffusion coefficient (ADC). Necrosis and apoptosis related to treatment decrease the tumour cell density resulting in higher water mobility and therefore an increase in ADC values; accordingly, there is a significant increase in ADC values in patients who exhibit response to treatment with chemotherapy, radiotherapy, and novel agents (23).
PET-CT scan
PET-CT scan combines high-resolution CT scanning with an injection of 18-fluoro-deoxy-glucose (FDG), which accumulates at areas of metabolic activity. FDG uptake is assessed at regions of interest and reported as standardised uptake values (SUV). Maximum SUV is higher in MPM than benign disease, and a threshold value of 2 can reliably differentiate between benign and malignant disease. Therefore PET-CT scan is employed for MPM diagnosis and staging (1) as well as to guide surgical biopsy.
PET scan has several limitations. It cannot differentiate between MPM and metastatic pleural malignancy and there is no correlation between SUV value and histological sub-type. In addition, MPM in early stage or MPM with a low proliferation rate could have a low FDG uptake (false negative results) while inflammatory disorders such as rheumatoid pleuritic, tuberculous pleurisy and prior pleurodesis could be FDG-avid (false positive results) (1,24-27). To overcome these limits, three-dimensional measurements incorporating total tumor volume and metabolic activity may potentially be more sensitive than the SUVmax not only for diagnosis but also for evaluating the response to treatment (28).
Figure 2 reports cases of intrathoracic MPM: (I) a MPM case of unilateral intrathoracic spread; (II) a case of MPM with direct tumor invasion to the contralateral pleura. Figure 3 reports a MPM case of direct tumor invasion to the peritoneum with carcinomatosis.
Figure 2.
Whole-body 18F-FDG PET/CT. Coronal and Sagittal fusion imaging at middle and right side. Transverse reconstruction axis, at left side, has been reported as CT alone, at left top, and as fusion PET/CT imaging below: (A) MPM left unilateral side involvement; (B) severe 18F-FDG uptake of MPM pertinence at left side, with clear contralateral MPM involvement. MPM, malignant pleural mesothelioma.
Figure 3.
Trans-diaphragmatic extension in a 62-year-old man with MPM and peritoneal carcinomatosis. (A) Axial contrast enhanced well-collimated multidetector CT (MDCT); (B) sagittal multiplanar MDCT reconstruction images at level of left hemithorax showing nodular pleural thickening in the left hemidiaphragm (arrows) and a left pleural effusion (*). There is complete encasement of left hemidiaphragm with loss of fat plane between diaphragm and spleen (arrowheads) suggestive of transdiaphragmatic extension; (C) MDCT image shows a thick omental thickening in the left anterior abdomen (arrowheads) and ascites (*) due to intraperitoneal neoplastic seeding; (D) axial fused PET/CT image at the level of superior abdomen shows FDG-avid nodular thickening in the left sub diaphragmatic region (arrows).
Biomarkers
Molecular profiling technologies to assess DNA, RNA, protein and metabolites have led to better understanding of the molecular basis of cancer, with identification of new disease markers (28-36).
Recent interest has been focused on BAP-1 protein loss (37).
Circulating serum biomarkers including mesothelin, osteopontin and vimentin have been evaluated in MPM (38).
Serum mesothelin-related protein (SMRP) has been found to be high in 84% of patient. Other serum markers such as CA-125, CA 15-3 and Hyaluronic acid are elevated while (1,39), conversely, carcinoembryonic antigen (CEA) is not increased in MPM.
Invasive procedures
Prompt and accurate diagnosis of MPM is important for therapeutic and medico-legal reasons. Cytological samples obtained by thoracentesis or by fine-needle aspiration biopsy may be inconclusive for a definitive diagnosis. Large biopsies and appropriate immunohistochemistry are generally mandatory for differentiating mesothelioma from other tumors (i.e., adenocarcinoma) and for defining the histological sub-type. Biopsies can be obtained percutaneously under radiological guidance, or during thoracoscopy. In addition, VATS provides useful information on staging since it explores the entire pleural cavity, defines the extension of the tumor and detects the invasion of neighbouring structures (1-4). When imaging is equivocal, additional invasive procedures should be performed to investigate mediastinal involvement (mediastinoscopy, anterior mediastinotomy, EBUS-TBNA) and/or of contralateral pleural or peritoneum invasion (bilateral thoracoscopy and laparoscopy).
Staging and response assessment
Both staging and response assessment in MPM are difficult to be performed due to pattern of growth and disease progression. The absence of bi-dimensional measurable consolidations limits tumour size and nodal involvement assessment by conventional size-based imaging techniques. Several staging classifications have been proposed over the years, all of which have limitations for use in routine clinical practice regarding tumour (T-) and node (N-) extension. Mainly used TNM staging system was proposed by the International Mesothelioma Interest Group (IMIG) with the approval of Union for International Cancer Control (Figure 4) (40,41).
Figure 4.
Functional or molecular imaging techniques that reflect specific features of tumour pathophysiology, like PET, MRI -DWI and dynamic contrast-enhanced MRI (DCE-MRI) are attracting growing interest. However, despite accuracy limits, size measurement based response criteria remains widely used in MPM management (42,43).
New strategies
Multimodality therapy including surgery, radiotherapy and chemotherapy remains the approach for MPM treatment (1-4). Inter-individual differences in terms of response to multimodality treatment and impaired functional status make treatment decisions challenging in MPM.
Personalised treatment based on individual patient characteristics and tumour genetics are under investigation (44).
Targeted therapies to epidermal growth factor receptor (EGFR) antagonists and platelet-derived growth factor receptor inhibitors have shown promising results. Immune checkpoint inhibitors (ICI) are attracting much interest as first-, second- or third-line treatments demonstrating prolonged disease stability. The combination of chemotherapy with ICI, or multiple ICI, has shown to be synergistic in other tumours and warrants further exploration in MPM.
Conclusions
MPM is an aggressive tumor, usually diagnosed in advanced stage and associated with a poor prognosis (ranging from 7 to 12 months). Unexplained pleural effusion and pleural pain in patients with asbestos exposure should raise the suspicion of MPM. In addition to conventional imaging, functional imaging techniques have the potential to improve disease management.
Thoracoscopic biopsy remains the most appropriate procedure for definitive diagnosis.
Multimodality approach with surgery, radiotherapy and chemotherapy is currently the standard while new personalised treatments, including ICI have shown promising results.
Acknowledgements
None.
Footnotes
Conflicts of Interest: The authors have no conflicts of interest to declare.
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