Advances in the investigation and treatment of pleural effusions

CD163+CD14+ macrophages, a potential immune biomarker for malignant pleural effusion

BACKGROUND

Malignant pleural effusion (MPE) is a common complication caused by malignant diseases. However, subjectivity, poor sensitivity, and substantial false-negative rates of cytology assay hamper accurate MPE diagnosis. The aim of this study was to assess whether CD163+CD14+ tumor-associated macrophages (TAMs) could be used as a biomarker for enabling sensitive and specific MPE diagnosis.

METHODS

Pleural effusion samples and peripheral blood samples were collected from 50 MPE patients and 50 non-malignant pleural effusion (NMPE) patients, respectively. Flow cytometry was performed to analyze cell phenotypes, and RT-qPCR was used to detect cytokine expression in these monocytes and macrophages. A blinded validation study (n = 40) was subsequently performed to confirm the significance of CD163+CD14+ TAMs in MPE diagnosis. Student's t test, rank sum test, and receiver operating characteristic curve analysis were used for statistical analysis.

RESULTS

Notably, CD163+CD14+ cell frequency in MPE was remarkably higher than that in NMPE (P < 0.001). In a blinded validation study, a sensitivity of 78.9 % and a specificity of 100 % were obtained with CD163+CD14+ TAMs as a MPE biomarker. In total (n = 140), by using a cutoff level of 3.65 %, CD163+CD14+ cells had a sensitivity of 81.2 % and a specificity of 100 % for MPE diagnosis. Notably, MPE diagnosis by estimating CD163+CD14+ cells in pleural effusion could be obtained one week earlier than that obtained by cytological examination.

CONCLUSIONS

CD163+CD14+ macrophages could be potentially used as an immune diagnostic marker for MPE and has better assay sensitivity than that of cytological analysis.

Soluble CD40 in plasma and malignant pleural effusion with non-small cell lung cancer: A potential marker of prognosis

OBJECTIVE

Soluble CD40 (sCD40) is a potential modulator for both antitumor responses and CD40-based immunotherapy; however the levels and significance of sCD40 in non-small cell lung cancer (NSCLC) patients with malignant pleural effusion are unknown.

METHODS

Forty-eight patients with lung cancer were treated in our institutions from January 2008 to January 2010. Peripheral blood and pleural effusion samples were collected from each subject. sCD40 levels in plasma and malignant pleural effusions supernatant were measured. The CD40L expression on CD3t T-cells was confirmed by flow cytometric direct immunofluorescence analysis. All patients were followed up after the study ended on January 1, 2010.

RESULTS

Patients with malignant pleural effusion of NSCLC had elevated circulating and pleural effusion levels of sCD40, and these elevated sCD40 levels were associated with advanced diseases and a poor prognosis.

CONCLUSIONS

These findings indicate that elevated sCD40 may have a role in modulating antitumor responses and may also be a useful prognostic marker.

Pre-clinical mouse models of primary and metastatic pleural cancers of the lung and breast and the use of bioluminescent imaging to monitor pleural tumor burden

Malignant pleural disease (MPD) results in an estimated 150,000 cases of malignant pleural effusions (MPE) annually. The most common malignancies associated with MPD are primary malignant pleural mesothelioma (MPM) and metastatic lung cancer, breast cancer, and lymphoma. MPM is a rare, regionally aggressive malignancy whose incidence is increasing secondarily to the latency of disease progression. MPD is characteristic of advanced-stage pleural disease and portends a grave clinical prognosis with a median survival between 3 and 12 months. Preclinical investigations conducted in flank and intraperitoneal tumor models do not fully recapitulate the pleural tumor microenvironment, and the results are not directly translatable to the clinical setting. The protocol described herein provides a mouse model of MPM and MPD from nonhematogenous tumors, resulting in reproducible tumor location, tumor progression, animal survival, and histopathology. Pleural tumor growth in this model resembles the regionally aggressive clinical course and tumor microenvironment of human pleural cancers and provides an optimal animal model to investigate MPD biology and therapies.