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Clinical utility of diagnostic biomarkers in malignant pleural mesothelioma: a systematic review and meta-analysis

Eline Schillebeeckx, Jan P. van Meerbeeck, Kevin Lamote
European Respiratory Review 2021 30: 210057; DOI: 10.1183/16000617.0057-2021
Eline Schillebeeckx
1Laboratory of Experimental Medicine and Pediatrics, University of Antwerp, Wilrijk, Belgium
2Infla-Med Centre of Excellence, University of Antwerp, Wilrijk, Belgium
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  • For correspondence: eline.schillebeeckx@uantwerpen.be
Jan P. van Meerbeeck
1Laboratory of Experimental Medicine and Pediatrics, University of Antwerp, Wilrijk, Belgium
2Infla-Med Centre of Excellence, University of Antwerp, Wilrijk, Belgium
3Dept of Internal Medicine, Ghent University, Ghent, Belgium
4Pulmonology and Thoracic Oncology, Antwerp University Hospital, Edegem, Belgium
5European Reference Network for rare respiratory diseases (ERN-LUNG), Frankfurt Am Main, Germany
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Kevin Lamote
1Laboratory of Experimental Medicine and Pediatrics, University of Antwerp, Wilrijk, Belgium
2Infla-Med Centre of Excellence, University of Antwerp, Wilrijk, Belgium
3Dept of Internal Medicine, Ghent University, Ghent, Belgium
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Abstract

Malignant pleural mesothelioma (MPM) is characterised by late-stage diagnosis and poor prognosis. Currently, no screening tool is advocated and diagnosis is based on invasive techniques, which are not well tolerated. Non-invasive diagnostic biomarkers have shown potential and could have a huge clinical benefit. However, despite extensive research, there is no consensus yet on their clinical use, with many articles reporting contradicting results, limiting their clinical implementation. The aim of this systematic review is therefore to explore the different semi- and non-invasive diagnostic markers in several human matrices and identify those that might clinically be relevant. A total of 100 articles were selected through Web of Science and PubMed, with 56 articles included in the quantitative analysis. Although many studies have reported on the diagnostic accuracy of MPM biomarkers such as serum mesothelin and high-mobility group box protein 1 and plasma fibulin-3, none have resulted in a validated test for early detection. Future research should focus on external validation, combinations into biomarker panels, the inclusion of early stage MPM patients and a combination of different biomarker matrices, as well as new markers.

Abstract

Diagnostic biomarkers for malignant pleural mesothelioma seem promising; however, further research is necessary to prove their clinical value. This review provides a thorough overview of the different markers and compares them in several matrices. https://bit.ly/35ni6UO

Introduction

Malignant pleural mesothelioma (MPM) is a cancer caused by historical exposure to asbestos fibres [1]. MPM has a poor prognosis, with a median survival of 9–12 months after diagnosis and <5% 5-year survival rate [2]. There are three histological subtypes of MPM, which are prognostic of patient outcome: epithelioid (best outcome), sarcomatoid (worst outcome) and biphasic. MPM carcinogenesis is a multistep process caused by the deep penetration of asbestos fibres into the lung epithelium and the pleural space where they cause mutations by a repeated cycle of pleural irritation, damage and repair, leading to frustrated phagocytosis and the release of pro-oncogenic proteins and growth factors [3, 4]. This multistep process takes time, which is reflected by a long latency period of 30 to 50 years between first asbestos exposure and MPM diagnosis [5]. The clinical symptoms of MPM are usually insidious and nonspecific, and enclose dyspnoea, cough and/or chest pain [1, 3]. Hence, a late diagnosis is characteristic for MPM, leading to a dismal prognosis. The gold standard for diagnosing MPM remains histological assessment of thoracoscopically obtained biopsies [1]. However, due to its invasiveness, it is not suitable for each and every patient. Furthermore, treatment of MPM is mostly palliative and consists of a backbone of chemotherapy, with recent promising advancement in immunotherapy (nivolumab and ipilimumab) [1, 3, 6]. Hence, research into less invasive biomarkers that could play a role in earlier diagnosis are thriving.

Liquid biomarkers have sparked a lot of interest due to their advantages over a single tissue biopsy. Liquid biomarkers are found in different body fluids, such as serum, plasma, pleural effusions (PEs), exhaled breath condensate, saliva and urine and contain a lot of information about the tumour, also at distinct metastatic sites, are less invasive and are easy to obtain [7, 8]. Especially when tissue sampling is hampered by the location of the tumour, liquid biomarkers can be beneficial. Furthermore, they hold the promise of diagnosing diseases at an early stage, even before detection by clinical imaging techniques [7]. The aim of this systematic review is to review the state of the art regarding diagnostic biomarkers for the detection of MPM in different body matrices.

Methods

Search strategy

This systematic review was conducted in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidelines [9]. Both PubMed and Web of Science were used as online databases. All articles published before 31 December 2019 were up for review. Keywords were determined based upon the population, exposure, comparison, outcome strategy (supplementary table S1), and their combination was used to detect relevant literature in the aforementioned databases (supplementary table S2).

Only articles published in English assessing the diagnostic accuracy of a biomarker in a human liquid matrix for the diagnosis of MPM were included. Editorial material, letters, reviews, case reports and meta-analyses were excluded. No limitation on the year of publication was imposed and all duplicates were removed. Firstly, the article titles and abstracts were screened by two independent reviewers, after which the full text of the remaining articles was evaluated. Study details (title, author, date), research question, matrix, method, patient population and control group, biomarker, potential confounders, reference test, patient selection, cut-off value, sensitivity, specificity and area under the receiver operating characteristics curve (AUCROC) were collected. The data was grouped according to the matrix and type of biomarker.

Study quality scoring

The quality of the articles was assessed using the Quality Assessment of Diagnostic Accuracy Studies 2 scoring system based on the scoring of four key domains: patient selection, index test, reference standard and flow and timing [10]. The risk of bias was determined based on all four domains, while for the risk of applicability only the first three were taken into account. For each domain, predefined questions were answered by yes or no, with “yes' indicating a low risk and “no” a high risk. Questions could also be answered with unclear, when the article did not include the applicable information.

Meta-analysis

All markers studied by at least two research groups were included in the meta-analysis. Studies dividing the population into subpopulations and not reporting the AUCROC or its (correct) confidence interval, were excluded. When one study reported the diagnostic accuracy of MPM compared to different control groups, the comparison per control group was included. Forest plots were created using the metafor package in R [11].

Results

A total of 2385 articles matched our search terms in Web of Science and PubMed (Supplementary figure S1). After duplicate removal, 2141 articles remained, which was further reduced to 469 after selection on title and abstract. 100 articles were included in the qualitative analysis after full-text assessment and their characteristics are summarised in supplementary table S3. The majority of the articles reported on serum biomarkers and only mesothelin was studied in all matrices (Supplementary figure S2). 56 studies were included in the quantitative analysis. Interesting markers for which a meta-analysis was not possible are described in the online data supplement.

Quality assessment

Supplementary figure S3 shows the quality of the 100 included articles. Overall, there are few concerns regarding applicability. All studies included MPM patients; however, there is a high variability in the type of control subjects, ranging from healthy controls with (AE) and without (HC) proven asbestos exposure or those with asbestos-related benign diseases to patients with non-asbestos-related malignancies and benign diseases. Furthermore, some studies only included epithelioid-type MPM patients, which can lead to bias as they tend to lead to a better outcome [12–17]. The most commonly used reference standard was histological or cytological assessment of pleural biopsies, often confirmed by experienced pathologists. However, some articles failed to mention exactly how MPM was diagnosed. The risk of bias does call for some concern. Firstly, some studies excluded patients based on suspicion of infection [18–23], previous therapy for other malignancies [24], other benign or malignant diseases [12, 13, 16, 25–33], mixed and sarcomatoid mesothelioma [13], or unclear diagnosis [34–37], which can lead to a more positive evaluation of the diagnostic capacities of the biomarker. Most studies only included untreated patients. However, this was not seen as an inappropriate exclusion and did not lead to the selection of solely early stage MPM. All studies used a cross-sectional, case–control design. Secondly, the cut-off value was often calculated and not pre-specified, introducing a potential bias through the index test. Furthermore, only a few studies mentioned the blinding of the reference test results, while interpreting the index test. Thirdly, some studies failed to mention the used reference standard or reported a combination of different methods, introducing a potential bias. Lastly, as almost all studies only included treatment-naïve patients, there was minimal concern for long intervals between the reference and index test.

Serum biomarkers

65% of all studies report on biomarkers in serum, making it the most investigated matrix.

Proteins

Mesothelin is a 40 kDA cell surface glycoprotein with low expression in normal mesothelial cells [31]. Together with megakaryocyte potentiating factor (MPF), mesothelin is derived from a 70 kDa precursor [38]. Although mesothelin is normally cell bound, different isoforms can be released into the bloodstream as a result of abnormal splicing or enzymatic cleavage. In the literature, both (soluble) mesothelin and soluble mesothelin-related peptides are often used interchangeably. Enzyme-linked immunosorbent assay (ELISA) was the preferred analytical method, with most studies having used the MesoMark assay. 27 studies were included in the meta-analysis of serum mesothelin (figure 1a) [13, 20, 21, 29, 35, 39–61]. All studies reported an overexpression in MPM patients compared to different control groups, with cut-off values ranging between 0.55 nM and 2.4 nM. When looking at the different AUCROC values, it is important to not lose track of the control group that was used. The highest AUCROC was obtained when comparing to a limited and less representative control population consisting of only benign PEs (AUCROC=0.93; AUCROC=0.94) [35, 57]. When only stage I MPM patients were compared to AE controls, an AUCROC of 0.74 was reported, indicating a potential for early diagnosis [47]. However, it was significantly lower than the AUCROC when all stages of MPM were included (AUCROC=0.81), in line with the intuitive idea that early stage diagnosis is more challenging. The specificity of serum mesothelin is questionable as a lower AUC was obtained when compared to other cancer types and metastases. A higher serum mesothelin concentration in the epithelioid subtype compared to other subtypes was explicitly described by most studies [20, 39–41, 47, 59]. The articles that could not find a significant difference between the two subtypes, did find a trend towards higher levels in the epithelioid subtype with the lack of significance most likely due to the limited amount of included sarcomatoid patients [42, 47, 61].

FIGURE 1
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FIGURE 1

Forest plot for the area under the curve (AUC) of serum markers in distinguishing malignant pleural mesothelioma (MPM) from different controls. AE: asbestos exposed; ARD: asbestos-related disease; BAP: benign asbestos pleurisy, BARD: benign asbestos-related disease; BPD: benign pleural disease; BPE: benign pleural effusion; BRD: benign respiratory disease; HC: healthy control; HMGB1: high mobility group box protein 1; ILK: integrin-linked protein kinase; LC: lung cancer; Met: metastasis; miR: microRNA; MPF: megakaryocyte potentiating factor; MPD: malignant pleural disease; MPE: malignant pleural effusion; NSCLC: non-small cell lung cancer; OPN: osteopontin; TRX: thioredoxin-1. References in panel a): Ak et al. 2017 [51]; Beyer et al. 2007 [42]; Cristaudo et al. 2007 [40]; Creaney et al. 2008 [50]; Creaney et al. 2010 [52]; Creaney et al. 2007 [54]; Creaney et al. 2011 [55]; Creaney et al. 2013 [56]; Creaney et al. 2007 [61]; Corradi et al. 2013 [58]; Demir et al. 2016 [29]; Dipalma et al. [39]; Ferro et al. 2013 [44]; Fujimoto et al. 2014 [60]; Franceschini et al. 2014 [43]; Grigoriu et al. 2007 [21]; Hollevoet et al. 2010 [59]; Hooper et al. 2013 [35]; Johnen et al. 2007 [53]; Napolitano et al. 2016 [49]; Pass et al. 2008 [47]; Portal et al. 2008 [45]; Rai et al. 2010 [46]; Santarelli et al. 2015 [48]; Scherpereel et al. 2006 [20]; Sriram et al. 2012 [57]. Panel b): Arslan et al. 2017 [34]; Creaney et al. 2008 [50]; Creaney et al. 2013 [56]; Hollevoet et al. 2010 [59]. Panel c): Arslan et al. 2017 [34]; Bayram et al. 2014 [31]; Pass et al. 2005 [62]; Creaney et al. 2008 [50]; Grigoriu et al. 2007 [21]; Napolitano et al. 2016 [49]. Panel d): Watzka et al. 2011 [63]; Watzka et al. 2013 [64]. Panel e): Demir et al. 2016 [29]; Maeda et al. 2011 [65]. Panel f): Napolitano et al. 2016 [49]; Ying et al. 2017 [66]. Panel g): Santarelli et al. 2015 [48]; Tomasetti et al. 2012 [19].

Only four studies investigated MPF, which all reported an elevation in MPM patients [34, 50, 56, 59]. In a large population (85 MPM patients and 275 controls), a high correlation between MPF and mesothelin was reported [59]. However, due to a lack in sensitivity (67.4% when compared to benign pleural disease) and specificity (60.8% when compared to metastases), in general, mesothelin seems to be more performant than MPF in serum (AUCROC=0.81 and 0.78, respectively) (figure 1b) [34, 50, 56, 59]. A significant link between higher MPF levels and the epithelioid subtype as well as the association with advanced stage was found [34, 59].

Osteopontin (OPN) is an integrin-binding protein involved in cell-matrix interactions [38]. The reported cut-off values vary tremendously, ranging from 16.06 ng·mL−1 to 139.1 ng·mL−1. Studies focussing on differential diagnosis with benign PEs performed very poorly, with AUCROC values no better than random (figure 1c) [34, 49]. Studies including AE and HC individuals as controls performed remarkably better (AUCROC=0.89 and 0.86, respectively) [31, 62]. All studies reported a higher level of OPN in MPM patients compared to controls. However, two studies reported no difference in OPN levels when compared to other diseases [34, 50]. These results stress that serum OPN is not optimal for differential diagnosis as it lacks specificity.

Integrin-linked kinase (ILK) is an intracellular kinase linking β-integrins to the cytoskeleton. It plays a role in chronic inflammatory processes and its overexpression can induce an epithelial–mesenchymal transition and thus a tumorigenic phenotype in epithelial cells [63]. Two different diagnostic outcomes were reported, with a AUCROC values of 0.69 and 0.89 (figure 1d) [63, 64]. The lower diagnostic accuracy was obtained when comparing to AE controls, while a better outcome was reported with malignant and benign chest diseases. Whether this difference can be explained by the use of different methods (western blot or ELISA) or a lower performance against asbestos exposure/related diseases is currently unclear. However, both studies were conducted by the same research group without explicitly describing their reference test, urging further research.

Thioredoxin-1 (TRX) is a protein with antioxidant properties as it can mobilise the antioxidant defence mechanism decreasing reactive oxygen species [29]. In MPM patients, TRX levels are increased due to the heightened antioxidant capacity (figure 1e) [29, 65]. The median TRX concentrations varied, with the higher concentrations linked to early stage MPM patients (stage I and II). Nevertheless, this did not result in an overall higher discriminatory capacity. At a cut-off of 156.67 ng·mL−1, a sensitivity of 92.9% (at 77.6% specificity) was obtained, which might render it interesting for screening purposes. As no comparisons were made with other cancer types, TRX's capacities as a discriminatory marker remain unknown.

High-mobility group box protein 1 (HMGB1) is a damage-associated molecular pattern protein that is released in the extracellular space during necrosis [49]. When HMGB1 resides in the nucleus, it is mainly non-acetylated, while the cytoplasmic hyperacetylated HMGB1 is secreted into the extracellular space where it attracts macrophages leading to a chronic inflammatory state. Therefore, it is hypothesised that the non-hyperacetylated form is present is AE individuals, while the hyperacetylated form is actively released during carcinogenesis. Overall, HMGB1 is a very promising biomarker, with the hyperacetylated form performing slightly better (figure 1f) [49]. However, the superiority of hyperacetylated HMGB1 should be further investigated. When MPM patients were compared to asbestosis patients, no differences were found. Furthermore, HMGB1 was reported to be an excellent marker for distinguishing asbestosis patients from HC and AE [66]. Unfortunately, as no comparisons with other malignancies are available yet, the inability to discriminate between MPM and asbestosis might indicate a lack in overall specificity. These results should be interpreted with caution, as only two studies with limited sample sizes were included in the meta-analysis, urging the need for future validation.

miRNA

MicroRNA (miRNA, miR) stands for non-coding RNA that has an important role in regulating gene expression. Studies focussing on miRNA all reported an increased expression of miR-197-3p, miR-1281, miR548-3p, miR-20a, miR-625-3p, has-1,3 miR-2053 and miR-34b/c. Only miR-126 was downregulated, which might be explained by its potential tumour suppressor function [18, 19]. With a combined AUCROC of 0.80, miR-126 is one of the best performing serum markers (figure 1g). However, the best result stems from the comparison with solely HC, possibly resulting in an overoptimistic summary AUCROC. Furthermore, the lack in specificity (54%) when compared to HC and AE reveals a suboptimal discriminatory capacity when asbestos exposure is included in the control group.

Biomarker panels

When serum OPN and mesothelin were measured in the same individual, a positive correlation with disease outcome was found comparing MPM patients to patients with pleural plaques, AE or HC [21, 31]. However, this was contradicted when combining both markers did not lead to an improvement in diagnostic accuracy [21, 46]. Furthermore, neither the addition of OPN nor of MPF had any added value over mesothelin on its own [50, 59]. As mesothelin and MPF both stem from the same precursor, it is not surprising that no significant difference in diagnostic accuracy between the two was found. Lastly, CA125 is a transmembrane mucin and known tumour marker [61]. In over 50% of cases, CA125 and mesothelin levels were not linked, which might lead to an additive effect when combined in a panel. Unfortunately, CA125 did not improve the sensitivity of mesothelin in detecting MPM. In contrast, carcinoembryonic antigen (CEA), chitinase-like protein (YKL-40) and cytokeratin 19 fragment (CYFRA-21) did improve the diagnostic performance of mesothelin [25, 30, 58].

Plasma biomarkers

Of the 19 studies looking into plasma biomarkers, 11 investigated mesothelin, two calretinin, one thrombomodulin, six OPN, three fibulin-3, five miRNA and one other (8-hydroxy-2′-deoxyguanosine, platelet-derived growth factor-h, hepatocyte growth factor, basic fibroblast growth factor and vascular endothelial growth factor-h, matrix metalloproteinase (MMP) 2, MMP9, tissue inhibitor of metalloproteinase (TIMP) 1 and TIMP2). ELISA was the preferred analytical method for plasma proteins.

Proteins

OPN is the most investigated plasma protein, with five studies included in the meta-analysis (figure 2a) [13, 21, 22, 46, 55]. However, with AUCROC values ranging from 0.568 to 0.795 and a summary AUCROC of 0.69, it seems to be outperformed by other plasma biomarkers independent of the control group.

FIGURE 2
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FIGURE 2

Forest plot for the area under the curve (AUC) of plasma markers in distinguishing malignant pleural mesothelioma (MPM) from different controls. AE: asbestos exposed; BARD: benign asbestos related disease; BRD: benign respiratory disease; HC: healthy control; Met: metastasis; PE: pleural effusion; PP: pleural plaques; OPN: osteopontin. References in panel a): Paleari et al. 2009 [22]; Cristaudo et al. 2011 [13]; Grigoriu et al. 2007 [21]; Creaney et al. 2011 [55]; Rai et al. 2010 [46]. Panel b): Jiang et al. 2017 [16]; Pass et al. 2012 [68]; Creaney et al. 2014 [67]. Panel c): Amatiet al. 2008 [23]; Johnen et al. 2018 [69]; Creaney et al. 2011 [55]; Creaney et al. 2014 [67]; Rai et al. 2010 [46].

Fibulin-3 is a secreted glycoprotein which has shown to promote tumour growth and invasion via phosphorylation of the epidermal growth factor receptor and downstream activation of the AKT (protein kinase B) signalling pathway [67]. The Pass and Jiang groups both reported a high diagnostic potential with AUCROC values ranging from 0.81 when compared to asbestosis patients to 0.92 when compared to HC [16, 68]. However, a lower accuracy was achieved when discriminating MPM from a control group including patients with benign asbestos-related disease, malignant and non-malignant effusions (AUC=0.671) [67]. The Pass's group also performed a validation analysis for the comparison with AE, where a very low sensitivity of 33% (AUCROC=0.87) was obtained. This is significantly different from the reported sensitivity of 71.32% during the discovery phase, further emphasizing the importance of biomarker validation. Overall, the three studies resulted in a summary AUCROC of 0.91, which is the highest for plasma (figure 2b).

All studies confirmed a higher value of plasma mesothelin in MPM compared to controls [23, 46, 55, 67, 69]. The reported cut-off values ranged from 1.963 nM to 2.5 nM. When plasma mesothelin levels of MPM patients were compared to those of patients with benign respiratory diseases, malignant and non-malignant effusions, an AUCROC of 0.816 was obtained, with 56% sensitivity and 96% specificity [67]. When AE was used as a control group, contradictory results were found, with an AUCROC values of 0.66 and 0.93, respectively [23, 69]. The quantitative analysis resulted in an overall AUCROC of 0.86 (figure 2c).

Biomarker panels

As there is limited effect of the matrix on mesothelin measurements, plasma is preferred over serum for biomarker discovery due to its better stability. When mesothelin, calretinin and MPF were combined into a diagnostic biomarker panel, an increase of the AUC to 0.944 was obtained in a male population and 0.937 in a female population. The corresponding sensitivities are 82% and 87% at a pre-set specificity of 95% [70]. The added value of combining mesothelin and calretinin was further confirmed by Johnen et al. [69]. Combining mesothelin and miR-103a-3p resulted in higher sensitivity (86%) and specificity (85%) [71]. Lastly, although miR132-3p (AUCROC=0.76) seems less effective in diagnosing MPM compared to mesothelin (AUCROC=0.81), the combination of both is superior to their individual diagnostic capacities, resulting in an AUCROC of 0.90 [71, 72]. A similar positive effect was seen for the combination of miR-132-3p and miR-126 [72].

PE biomarkers

In total, 36% of the included studies investigated biomarkers in PEs (Supplementary table S3). Proteins are the most investigated biomarkers (89%) followed by DNA (5.5%) and miRNA (5.5%).

Proteins

The diagnostic effectiveness of PE mesothelin is shown in figure 3a [20, 21, 35, 43, 44, 47, 56, 57, 67, 73–82]. All 19 studies reported relatively similar AUCROC values ranging from 0.70 to 0.93, leading to a summary total of 0.83. The largest study included 128 MPM patients and 1147 controls and obtained a sensitivity and specificity of 67% and 95% at a cut-off of 20 nM [74]. The AUCROC reported in this study is comparable to the overall calculated AUCROC, which might be caused by the higher weight due to its small confidence interval. Similar to the other matrices, all studies reported an elevated level of mesothelin in MPM patients compared to controls. A large heterogeneity was found in reported cut-off values, ranging from 6 nM to 50 nM. Both the highest and lowest cut-off values were reported by Aleman et al. [76], who compared a group of 18 MPM patients to 51 controls (including lung cancer patients, patients with other cancers, patients with pneumonia, TB and idiopathic pulmonary disease). Sensitivity and specificity of 72% and 46% and 44% and 100% were obtained for the lowest and highest cut-off value, respectively. The most commonly used cut-off value in PE lies around 20nM, with sensitivities and specificities ranging from 44% to 100% and 46% to 100%.

FIGURE 3
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FIGURE 3

Forest plot for the area under the curve (AUC) of pleural effusion markers in distinguishing malignant pleural mesothelioma (MPM) from different controls. BARD: benign asbestos related disease; BAP: benign asbestos pleurisy; BPE: benign pleural effusion; CEA: carcinoembryonic antigen; LC: lung cancer; Mets: metastasis; MPE: malignant pleural effusion; PE: pleural effusion. References in panel a): Sriram et al. 2012 [57]; Canessa et al. 2013 [75]; Ferro et al. 2013 [44]; Pass et al. 2008 [47]; Battolla et al. 2017 [78]; Otoshi et al. 2017 [81]; Blanquart et al. 2012 [79]; Grigoriu et al. 2007 [21]; Scherpereel et al. 2006 [20]; Fujimoto et al. 2010 [77]; Hegmans et al. 2009 [82]; Filiberti et al. 2013 [80]; Davies et al. 2009 [73]; Creaney et al. 2014 [67]; Hooper et al. 2013 [35]; Aleman et al. 2009 [76]; Franceschini et al. 2014 [43]. Panel b): Battolla et al. 2017 [78]; Pass et al. 2012 [68]; Creaney et al. 2014. Panel c): Hegmans et al. 2009 [82]; Filiberti et al. 2013 [80]; Fuhrman et al. 2000 [83]; Wang et al. 2014 [36]. Panel d): Filiberti et al. 2013 [80]; Fuhrman et al. 2000 [83]; Wang et al. 2014 [36]. Panel e): Mundt et al. 2014 [33]; Fuhrman et al. 2000 [83]; Mundt et al. 2013 [37].

Contradictory results were found for fibulin-3. Pass et al. [68] reported higher fibulin-3 concentrations in PE of MPM patients compared to patients with PE (both benign and malignant, related to AE or not), with AUCROC values of 0.91 and 0.95 in two independent cohorts. However, this could not be reproduced, with other AUCROC values ranging from 0.42 to 0.59 [67, 78]. With a summary AUCROC of 0.68, PE fibulin-3 is not a good standalone diagnostic biomarker (figure 3b). Further research is advised due to the heterogenous results, the limited number of studies and the lack of asbestos-related control groups.

A very promising but less investigated marker for MPM, is CYFRA-21-1, which is the soluble fragment of cytokeratin 19. In malignant tissues, CYFRA-21-1 is released into circulation after apoptosis or caspase-3 cleavage. As carcinogenesis can cause apoptosis, it is not surprising that all studies reported an elevated level of CYFRA-21-1 in MPM patients compared to controls [80, 82, 83]. The diagnostic accuracy is not outstanding, with AUCROC values ranging from 0.65 to 0.76 and an overall AUCROC of 0.73 (figure 3c). No major differences in accuracy between the different control groups could be detected; however, no benign or asbestos-related conditions were included.

CEA is a glycoprotein involved in cell adhesion. In healthy individuals, very low levels of CEA are detectable in the bloodstream. An increase in several cancer types and non-cancerous conditions has been reported. Hence, MPM patients are also expected to have an elevated CEA level. Although two studies indicated this expected increase, one study reported a decrease when compared to other types of cancer [36, 80, 83]. This indicates that CEA is elevated in different cancer types and therefore not specific for MPM. Due to these inconclusive results and an overall AUCROC of 0.55, no conclusion can be drawn regarding the diagnostic accuracy of PE CEA (figure 3d). Due to its lack of specificity, the use of CEA as a differential diagnostic marker is not advised. Further research including asbestos-exposed individuals should clarify whether CEA might be interesting as a screening marker.

Hyaluronan (HA) or hyaluronic acid is a major compound of the extracellular matrix, regulating cell adhesion and motility, as well as mediating cell proliferation and differentiation [84]. Three studies investigated PE HA, but only two validated their findings in an independent cohort [33, 37]. Only patients with other cancers, benign diseases and metastases were included as controls, so no conclusion can be drawn about HA as an MPM screening biomarker. In PE, HA on its own does not have the best diagnostic accuracy, with an AUCROC of 0.78 (figure 3e).

Biomarker panels

A similar diagnostic accuracy of PE HA and MPF was found [37]. Their combination resulted in a slightly better AUCROC (0.81 versus 0.83). A protein biomarker panel that does exceed its individual performance, consists of C-C motif chemokine ligand 2, galectine-3, mesothelin, and secretory leukocyte protease inhibitor [79]. With a sensitivity and specificity of 93.8% and 64.9%, respectively, the combination of mesothelin and the CYFRA-21-1/CEA ratio is also a strong contender as an MPM biomarker panel [81]. As this combination helped to rule out MPM among the high-risk population, it is a valuable option for screening purposes. The combination of CYFRA-21-1 and CA-15-3 resulted in an elevated sensitivity (100%) and specificity (83%) [27]. Furthermore, a combination of CA-15-3, CYFRA-21-1 and CA19-9 resulted in a higher sensitivity, but decreased the specificity [27]. Lastly, the panel of three miRNAs (miR-200c, miR-210 and miR-143) resulted in a summary AUCROC of 0.92 when comparing MPM patients to both patients with benign diseases and patients with adenocarcinoma [85].

Urine biomarkers

Proteins

As urine volume and renal function have effects on protein concentration, urinary mesothelin concentrations were standardised against urinary creatinine concentrations [52]. Again, the level of mesothelin was found to be significantly higher in MPM patients compared to controls. When discriminating MPM patients from those with benign disease, an AUCROC of 0.87 was obtained. A correlation was found with serum mesothelin, but only in the MPM group.

Reported confounding factors

When looking at diagnostic tests, the risk of confounding factors should always be considered. The main confounding factor seemed to be the histological subtype, with epithelioid tumours being associated with higher diagnostic accuracy of the biomarkers assessed. However, this was contradicted by several studies for serum mesothelin, miRNA, a protein panel, midkine, ILK and the DNA integrity index [28, 41, 47, 51, 57, 64, 86]. Weber's group also did not find a difference between different subtypes studying miR-103 in plasma [87]. Secondly, it is not surprising that for most biomarkers the most pronounced differences were found when comparing controls to advanced stages of MPM. In contrast, the influence of body mass index (BMI), smoking, gender and age seemed to have limited effect [16, 23, 29, 35, 63, 68]. However, both Bayram et al. [31] and Paleari et al. [22] reported a significant influence of gender on the serum and plasma OPN levels. Furthermore, a positive relationship was found between smoking status and serum OPN levels [31]. Hollevoet et al. [88] studied the effect of clinical covariates on the diagnostic accuracy of both mesothelin and MPF in serum and reported an increase in accuracy when age decreased or the glomerular filtration rate or BMI increased [88].

Discussion

Liquid biomarkers can be found in different body fluids, such as serum, plasma, PEs, exhaled breath condensate, saliva, sweat and urine. With their advantage of being minimally invasive, they have a huge benefit over the current golden standard of biopsy-driven diagnosis. Furthermore, a large population of asbestos-exposed individuals do not have access to a readily accessible screening device, which leads to a psychological burden. Being able to relieve people from this stress will have a positive effect on their overall well-being. A rapid and accurate early stage diagnosis can also have a positive effect on the dismal prognosis of MPM, as a potential radical therapy can be initiated earlier. As research for newer and curative therapies is booming, diagnostic tools cannot stay behind. Unfortunately, there is still a lot of variability in the reported outcomes of diagnostic biomarker studies. This can mainly be attributed to the control groups included, ranging from only those patients with PEs to patients with benign or malignant conditions and asbestos-related diseases. Due to this heterogeneity, it is difficult to directly compare the results of different individual studies. However, this heterogeneity can be useful to assess the full diagnostic capacity of a certain marker. The inclusion of HC and AE as controls is more representative for a screening test, while different types of malignancy and benign asbestos-related diseases can verify whether a differential diagnosis is possible. Furthermore, many studies show that epithelioid mesothelioma is easier to differentiate from controls compared to other MPM histological subtypes. As a result, studies only including the epithelioid subtype can have biased positive results. Both a representative cohort of patients and controls are therefore crucial in future studies. Another point of concern is the cut-off value. As the majority of studies do not have a predefined cut-off value, it leads to a variety of cut-off values, each perfect for the specific cohort used in that study. Unfortunately, many studies disagree on the perfect value, rendering it clinically useless. Therefore, studies including both a verification and a validation cohort or follow-up studies, validating the results in an independent cohort, are necessary.

Many biomarkers have been studied in different matrices. For mesothelin, the highest diagnostic accuracy was detected in plasma, closely followed by PE and serum (figures 2–4). Its levels in PE were significantly higher compared to those in serum, which might be explained by the fact that mesothelin is derived from a cell-bound protein produced locally and released directly into the pleural cavity [44]. Although this was confirmed by most studies, Scherpereel et al. [20] found a significant correlation between serum and PE mesothelin levels, with no significant favour. For OPN, the preferred matrix is plasma, as measurements have proven to be more stable and reliable. However, OPN was neither in plasma nor in serum the best-performing diagnostic marker [12]. This might be explained by its link to some other malignant conditions, as well as to non-malignant diseases such as tuberculosis [12]. In contrast, fibulin-3 has a clear superior diagnostic accuracy in plasma compared to PE. However, as the results of the included studies vary greatly, additional research is advised. Lastly, serum HA seems less than optimal due to the fast clearance from systemic circulation by stabilin-2 [3]. In pleural fluid, HA is present in the form of a large fibroblast-formed polysaccharide, making it more stable. Due to a lack in overlap between the miRNAs studied in the different matrices, no comparison of their performance between the matrices was possible. It is clear that it is impossible to just focus on one matrix, as different matrices are preferable for different markers (table 1; figure 4).

FIGURE 4
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FIGURE 4

Liquid biomarkers for the diagnosis of malignant pleural mesothelioma (MPM). The font size of the different biomarkers is directly proportional to the area under the receiver operating characteristics curve (AUCROC) obtained through the meta-analysis for that matrix. When detected in multiple matrices, the biomarker in that matrix resulting in the highest AUCROC was put in bold. A few interesting combinations of biomarkers (biomarker panels), as discussed by articles included in this review, are shown in the figure under the column panel. Furthermore, this panel represents the possibility of combining different markers and matrices as a focus for future research. CEA: carcinoembryonic antigen; CLEIA: chemiluminescence immunoassay; CYFRA-21-1: cytokeratin 19 fragment; ECLEIA: electro-chemiluminescence immunoassay; ELISA: enzyme-linked immunosorbent assay; HA: hyaluronan; HMGB1: high mobility group box protein 1; ILK: integrin-linked protein kinase; IRMA: immunoradiometric assay; LC-MS: liquid chromatography–mass spectrometry; MIA: magnetic immunoassay; miR: microRNA; MPF: megakaryocyte potentiating factor; OPN: osteopontin; PCR: polymerase chain reaction; SELDI-TOF MS: surface-enhanced laser desorption/ionisation time of flight mass spectrometry; SLPI: secretory leukocyte protease inhibitor; TRX: thioredoxin; YKL: chitinase-like protein.

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TABLE 1

An overview of the values of the area under the receiver operating characteristics curve (AUCROC) per matrix and marker as reported by the meta-analyses

Mesothelin is by far the most investigated diagnostic biomarker for MPM. Despite repeated validation studies, there is no consensus yet about its actual clinical utility. A meta-analysis combining the diagnostic value of serum mesothelin in over 4000 patients resulted in 47% sensitivity at 95% specificity [1, 89]. In this review, we obtained a summary AUCROC of 0.81 for serum mesothelin when 27 studies were combined. Although promising, mesothelin clearly lacks the sensitivity to be used as standalone diagnostic marker. Therefore, focussing on a combination of different markers, either in one panel or using a decision tree, seems to be the best way forward. The combination of mesothelin, TRX and fibulin-3 in serum resulted in an optimised sensitivity and negative predictive value of 100% [29]. Although their specificities were disappointing, this 100% negative predictive value is ideal for a screening test, as all patients would be detected and referred for further (invasive) testing. The addition of biomarkers to the currently existing diagnostic techniques should also be further investigated. Adding PE mesothelin to cytological assessment reached a diagnostic sensitivity of 78.9%, which is higher than the sensitivities of either individually [43]. Furthermore, we should be clear about what to expect from a diagnostic biomarker for malignant mesothelioma. Ideally, one strives for a perfect test, possessing a 100% sensitivity and 100% specificity. This holy grail test would lead to a flawless detection of MPM where we can perfectly distinguish MPM from all other diseases and no patients would be missed. However, a more realistic approach would be to either focus on a differential diagnosis with a high specificity or to focus on developing a test with a high sensitivity and negative predictive value, leading to a minimal of false negatives (supplementary figure S4). This test could then be implemented as a pre-diagnostic step for the AE population in the diagnosis of MPM. Due to its non-invasive nature, repeated testing is possible. Unfortunately, most current studies only included already diagnosed patients, with mostly advanced disease, which lack true clinical utility for the early stage markers and screening purposes. Future studies should therefore prospectively try and validate markers. This could prove to be difficult as several studies have indicated disease stage as a confounding factor, with earlier stages being more difficult to discriminate. Pass et al. [47] demonstrated this by separating stage I MPM from more advanced stages of MPM when compared to AE as control group. With an AUCROC of 0.74, stage I MPM was more difficult to discriminate from AE compared to advanced MPM (AUCROC=0.81).

Although no such studies were included in this review, a more recent and promising matrix is exhaled breath, more specifically the liquid phase enclosing exhaled breath condensate and aerosols. Both can be sampled using completely non-invasive techniques and contain a plethora of non-volatile or semi-volatile compounds, including, ammonia, isoprostanes, hydrogen peroxide, chemokines, cytokines, nitrogen oxides, peptides, DNA and RNA [90, 91]. By using a cooling device, exhaled breath is condensed into a liquid during tidal breathing. A rise in oxidative stress biomarkers in exhaled breath condensate has already been established in subjects with asbestosis compared to healthy controls [92]. Furthermore, promising results have been described regarding chronic airway diseases, such as cystic fibrosis, asthma and chronic obstructive pulmonary disease [93, 94]. Although the previously mentioned compounds are very diluted as breath also contains a lot of water, the matrix will still be less complex compared to serum or plasma. A more direct, but less explored approach is to entrap exhaled droplets, containing small non-volatile molecules, directly by the use of a filter or facemask. The origin of these aerosols can be linked to both the lower respiratory tract caused by surface film disruption and to the upper airways due to turbulence [91, 93, 95]. They are released during exhalation and in larger amounts during coughing and sneezing. However, caution is warranted not to mistake exogenous exposures for biomarker candidates. As every matrix has its own strengths and weaknesses, introducing a panel of optimal biomarkers beyond the borders of one matrix could have an added value.

Conclusions and future perspectives

We reviewed diagnostic liquid biomarkers for MPM. The majority focussed on identifying biomarkers in limited discovery cohorts, while implementation in clinical practice calls for larger validation studies. Furthermore, the heterogeneity of the used protocols and control groups was high, and efforts should therefore be made regarding standardisation to optimise results while making them comparable and reproducible. Focus should lie on the external validation of already discovered biomarkers, as well as exploring new biomarkers and biomarker panels. The most popular MPM biomarker is mesothelin and should be included in different panels, irrespective of matrix, as the combination with TRX and fibulin-3 has already shown promising results for screening purposes. Serum HMGB1 is also a strong contender, although further research is necessary to validate the positive results obtained by the two studies included in this review. The inclusion of patients with asbestosis or malignant diseases is encouraged as currently no difference in HMGB1 levels was found between asbestosis and MPM. Based on this review, plasma fibulin-3 (AUCROC=0.91) is the most promising single biomarker and should therefore be put in the limelight when further research is concerned. Furthermore, the use of new and innovative technologies for panel discovery should be encouraged. As MPM is mostly diagnosed at an advanced stage, the discovery and validation of early stage biomarkers is lacking. The set-up of an overarching biobank of early stage samples for scientific use could lead to a boost in this specific type of research. Furthermore, as different liquid matrices provide matrix-specific biomarkers, the combination of biomarkers from different matrices should be further investigated, as they each have their different strengths and downfalls. Lastly, recent discoveries in exhaled breath condensate and aerosols should be explored.

Supplementary material

Supplementary Material

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Supplementary material ERR-0057-2021_Supplementary_material

Footnotes

  • Provenance: Submitted article, peer reviewed.

  • This article has supplementary material available from err.ersjournals.com

  • Author contributions: E. Schillebeeckx: data curation, investigation, methodology, visualisation, writing (original draft, review and editing). J.P. van Meerbeeck: supervision, writing (review and editing). K. Lamote: conceptualisation, methodology, funding acquisition, supervision, visualisation, writing (review and editing).

  • Conflict of interest: E. Schillebeeckx has nothing to disclose.

  • Conflict of interest: J.P. van Meerbeeck has nothing to disclose.

  • Conflict of interest: K. Lamote has nothing to disclose.

  • Support statement: This study was funded by a grant from the Foundation Against Cancer (grant STK 2018-137) and by a grant from Kom op tegen Kanker (Stand up to Cancer), the Flemish cancer society by the grant “Emmanuel van der Schueren”. Funding information for this article has been deposited with the Crossref Funder Registry.

  • Received March 3, 2021.
  • Accepted June 8, 2021.
  • Copyright ©The authors 2021
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Clinical utility of diagnostic biomarkers in malignant pleural mesothelioma: a systematic review and meta-analysis
Eline Schillebeeckx, Jan P. van Meerbeeck, Kevin Lamote
European Respiratory Review Dec 2021, 30 (162) 210057; DOI: 10.1183/16000617.0057-2021

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Clinical utility of diagnostic biomarkers in malignant pleural mesothelioma: a systematic review and meta-analysis
Eline Schillebeeckx, Jan P. van Meerbeeck, Kevin Lamote
European Respiratory Review Dec 2021, 30 (162) 210057; DOI: 10.1183/16000617.0057-2021
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