Kevin Lamote

Biomarkers for early diagnosis of malignant mesothelioma: Do we need another moonshot?

Early diagnosis of malignant pleural mesothelioma (MPM) is a challenge for clinicians. The disease is usually detected in an advanced stage which precludes curative treatment. We assume that only new and non-invasive biomarkers allowing earlier detection will result in better patient management and outcome. Many efforts have already been made to find suitable biomarkers in blood and pleural effusions, but have not yet resulted in a valid and reproducible diagnostic one. In this review, we will highlight the strengths and shortcomings of blood and fluid based biomarkers and highlight the potential of breath analysis as a non-invasive screening tool for MPM. This method seems very promising in the early detection of diverse malignancies, because exhaled breath contains valuable information on cell and tissue metabolism. Research that focuses on breath biomarkers in MPM is in its early days, but the few studies that have been performed show promising results. We believe a breathomics-based biomarker approach should be further explored to improve the follow-up and management of asbestos exposed individuals.Early diagnosis of malignant pleural mesothelioma (MPM) is a challenge for clinicians. The disease is usually detected in an advanced stage which precludes curative treatment. We assume that only new and non-invasive biomarkers allowing earlier detection will result in better patient management and outcome. Many efforts have already been made to find suitable biomarkers in blood and pleural effusions, but have not yet resulted in a valid and reproducible diagnostic one. In this review, we will highlight the strengths and shortcomings of blood and fluid based biomarkers and highlight the potential of breath analysis as a non-invasive screening tool for MPM. This method seems very promising in the early detection of diverse malignancies, because exhaled breath contains valuable information on cell and tissue metabolism. Research that focuses on breath biomarkers in MPM is in its early days, but the few studies that have been performed show promising results. We believe a breathomics-based biomarker approach should be further explored to improve the follow-up and management of asbestos exposed individuals.

Volatile organic compounds as an early diagnostic tool for malignant pleural mesothelioma

To the Editor: The same patient outcome data from clinical trial results, when presented as absolute or relative changes, may appear different in magnitude. Recommendations are to report both absolute and relative, or at least baseline, data from which to calculate absolute values [1, 2]. A systematic review of efficacy trials demonstrated that only relative values were reported in most study abstracts (88%) and the main text (75%) [3]. To inform clinical practice, outcome improvements, whether relative or absolute, must be statistically significant and clinically meaningful. A minimal clinically important difference (MCID) should inform sample size calculations for clinical trials. Two main methods identify an MCID (distribution and anchor-based methods); ideally used together to interpret one in the context of the other [4]. The distribution method is a statistical calculation based on the baseline variability of the measure in the population studied. This gives an effect size (change after intervention divided by standard deviation of baseline scores), the magnitude of which relates to a small, moderate or large clinical effect [5]. Thus the distribution method can only be used to calculate an absolute MCID as there is no standard deviation of baseline score for a relative measure. The anchor-based method relates the change in score

Detection of malignant pleural mesothelioma in exhaled breath by multicapillary column/ion mobility spectrometry (MCC/IMS).

Malignant pleural mesothelioma (MPM) is predominantly caused by previous asbestos exposure. Diagnosis often happens in advanced stages restricting any therapeutic perspectives. Early stage detection via breath analysis was explored using multicapillary column/ion mobility spectrometry (MCC/IMS) to detect volatile organic compounds (VOCs) in the exhaled breath of MPM patients in comparison to former occupational asbestos-exposed and non-exposed controls. Breath and background samples of 23 MPM patients, 22 asymptomatic former asbestos (AEx) workers and 21 healthy non-asbestos exposed persons were taken for analysis. After background correction, we performed a logistic least absolute shrinkage and selection operator (lasso) regression to select the most important VOCs, followed by receiver operating characteristic (ROC) analysis. MPM patients were discriminated from both controls with 87% sensitivity, 70% specificity and respective positive and negative predictive values of 61% and 91%. The overall accuracy was 76% and the area under the ROC-curve was 0.81. AEx individuals could be discriminated from MPM patients with 87% sensitivity, 86% specificity and respective positive and negative predictive values of 87% and 86%. The overall accuracy was 87% with an area under the ROC-curve of 0.86. Breath analysis by MCC/IMS allows MPM patients to be discriminated from controls and holds promise for further investigation as a screening tool for former asbestos-exposed persons at risk of developing MPM.

Calcium phosphate cements modified with pore expanded SBA-15 materials

The effects of adding a mesoporous ordered silica to a calcium phosphate cement (CPC) based on α-tricalcium phosphate (α-TCP) are described in this study. The influence of this mesoporous seed material and of the phosphate concentrations in the cement liquid on the physico-chemical, mechanical and microstructural properties of the CPC was investigated. SBA-15 and ultra-large pore (ULP) SBA-15 were used as seed materials. For the latter, a novel reproducible synthesis procedure was developed. When using a 4 wt% Na2HPO4 solution, the α-TCP based cement exhibited setting times convenient for clinical applications, but the material was very weak and no conversion to a calcium-deficient hydroxyapatite (CDHAp) occurred. Adding either SBA-15 or ULP SBA-15 to the CPC stimulated the nucleation and growth of apatite crystals and influenced the microstructure of the set cement. The ratio between the concentration of silica in the cement powder and the phosphate concentration in the cement liquid was crucial for tailoring the properties of the CPC. Cements with 5 wt% ULP SBA-15 as seed material could be used in a clinical setting for load-bearing applications.

Exhaled breath to screen for malignant pleural mesothelioma: a validation study

Malignant pleural mesothelioma (MPM) is predominantly caused by asbestos exposure and has a poor prognosis. Breath contains volatile organic compounds (VOCs) and can be explored as an early detection tool. Previously, we used multicapillary column/ion mobility spectrometry (MCC/IMS) to discriminate between patients with MPM and asymptomatic high-risk persons with a high rate of accuracy. Here, we aim to validate these findings in different control groups. Breath and background samples were obtained from 52 patients with MPM, 52 healthy controls without asbestos exposure (HC), 59 asymptomatic former asbestos workers (AEx), 41 patients with benign asbestos-related diseases (ARD), 70 patients with benign non-asbestos-related lung diseases (BLD) and 56 patients with lung cancer (LC). After background correction, logistic lasso regression and receiver operating characteristic (ROC) analysis, the MPM group was discriminated from the HC, AEx, ARD, BLD and LC groups with 65%, 88%, 82%, 80% and 72% accuracy, respectively. Combining AEx and ARD patients resulted in 94% sensitivity and 96% negative predictive value (NPV). The most important VOCs selected were P1, P3, P7, P9, P21 and P26. We discriminated MPM patients from at-risk subjects with great accuracy. The high sensitivity and NPV allow breath analysis to be used as a screening tool for ruling out MPM. Breath analysis can be used to screen for malignant pleural mesothelioma in high-risk asbestos-exposed persons http://ow.ly/GppL30gCOaD

Breath analysis by gas chromatography-mass spectrometry and electronic nose to screen for pleural mesothelioma: a cross-sectional case-control study

Rationale Malignant pleural mesothelioma (MPM) is mainly caused by previous exposure to asbestos fibers and has a poor prognosis. Due to a long latency period between exposure and diagnosis, MPM incidence is expected to peak between 2020-2025. Screening of asbestos-exposed individuals is believed to improve early detection and hence, MPM management. Recent developments focus on breath analysis for screening since breath contains volatile organic compounds (VOCs) which reflect the cell’s metabolism. Objectives The goal of this cross-sectional, case-control study is to identify VOCs in exhaled breath of MPM patients with gas chromatography-mass spectrometry (GC-MS) and to assess breath analysis to screen for MPM using an electronic nose (eNose). Methods Breath and background samples were taken from 64 subjects: 16 healthy controls (HC), 19 asymptomatic former asbestos-exposed (AEx) individuals, 15 patients with benign asbestos-related diseases (ARD) and 14 MPM patients. Samples were analyzed with both GC-MS and eNose. Results Using GC-MS, AEx individuals were discriminated from MPM patients with 97% accuracy, with diethyl ether, limonene, nonanal, methylcyclopentane and cyclohexane as important VOCs. This was validated by eNose analysis. MPM patients were discriminated from AEx+ARD participants by GC-MS and eNose with 94% and 74% accuracy, respectively. The sensitivity, specificity, positive and negative predictive values were 100%, 91%, 82%, 100% for GC-MS and 82%, 55%, 82%, 55% for eNose, respectively. Conclusion This study shows accurate discrimination of patients with MPM from asymptomatic asbestos-exposed persons at risk by GC-MS and eNose analysis of exhaled VOCs and provides proof-of-principle of breath analysis for MPM screening.

Abstract 5584: Exhaled breath as diagnostic tool for malignant pleural mesothelioma

Background: Malignant Pleural Mesothelioma (MPM) is an asbestos-related disease with a dismal prognosis due to its late detection at an advanced stage. Hence, a diagnostic test is requisite that allows to screen asbestos-exposed persons for earlier MPM detection. As blood biomarkers have not shown to be clinically useful biomarkers for early non-invasive diagnosis, breath is currently explored. Breath is easy to retrieve by physicians in a clinical environment and contains volatile organic compounds (VOCs) that arise from (patho)physiological processes. Since asbestos causes oxidative stress and cancers are known to up regulate their metabolism, we hypothesize that VOCs and, hence, the exhaled breath of MPM patients will differ from healthy controls. Methods: We compared the breath of 23 MPM patients, 10 asbestos-exposed and 12 non-exposed healthy individuals using a multicapillary column/ion mobility spectrometer (MCC/IMS, BS 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 5584. doi:10.1158/1538-7445.AM2015-5584

MC13-0046 Volatile organic compounds as an early diagnostic tool for malignant pleural mesothelioma

Background: Early diagnosis of malignant pleural mesothelioma (MPM) can improve patients’ outcome but is hampered by non-specific symptoms and investigations, which delay diagnosis and result in advanced stage disease [van Meerbeeck JP, 2011]. An accurate non-invasive test allowing early stage diagnosis in asbestos-exposed persons is lacking. Purpose/Objective: Breathomics aims at a non-invasive analysis of volatile organic compounds (VOCs) reflecting the cells’ metabolism. The breathogram obtained by the electronic nose does however, not allow identification of MPM-related VOCs [Chapman EA 2009, Dragonieri S 2011]. Ion mobility spectrometry (IMS) combines the advantages of online direct sampling with the possibility of VOC identification and linking to MPM pathogenesis [Baumbach JI 2009]. We investigated which VOCs could play a role in MPM pathogenesis in order to build a possible diagnostic MPM tool. Materials and Methods: 10 MPM patients and 10 healthy professionally asbestos-exposed individuals were included after refraining from eating, drinking and smoking for at least 2 hours before sampling. They breathed tidally for 3 minutes through a mouthpiece connected to a bacteria filter. Ten ml alveolar air was sampled via a CO2-controlled ultrasonic sensor and analyzed using the BioScout Multicapillary Column/Ion Mobility Spectrometer (MCC/IMS, B&S Analytik, Dortmund, Germany) [Westhoff M 2009], by using N2 as a carrier gas. Per subject a background sample was taken. Peaks of interest were visually selected and their intensity (V) was analyzed and compared between background and breath samples via on-board VisualNow 3.2 software and SPSS v21 (IBM) using Mann-Whitney-U tests. Results:Out of 41 peaks of interest, three show a significantly higher intensity in the exhaled breath of MPM patients than healthy controls [Table]. The high AUCROC of resp. P12 (0.877) and P24 (0.863) suggests a possible role of these associated VOCs in MPM pathogenesis and as a diagnostic marker in discriminating MPM patients from asbestos-exposed healthy controls.