The use of computer-aided decision systems in health sciences has developed considerably in recent years.1314 Studies on this topic have especially focused on the field of radiological image analysis.15 Big data analysis using Artificial Intelligence (AI) and Machine Learning (ML) based classification algorithms in medical science provides an infrastructure for computer-aided diagnosis and clinical decision support systems.16 AI has a growing impact on diagnosis systems with the use of deep neural networks to diagnose different diseases, such as lesion/nodules detection, image classification, and image segmentation by pattern recognition.17 AI plays a crucial role in the identification of cancer patients by the diagnosis of heterogeneous diseases with an accurate prediction rate. Especially to differentiate between malignant pleural effusion and benign pleural effusion the Deep Learning (DL) technique can be used.6 DL is a part of the ML tools that provide high performance in medical imaging, especially for the detection, identification, and segmentation of complex lesions that emerged in image processing and recognition.18 Additionally, DL provides highly accurate intelligent diagnosis through medical image analysis.19 Whereas computer-aided detection algorithms provide diagnosis systems to assist radiologists by interpreting medical images, DL can learn by extracting effective features from the medical images to differentiate between diseases. As a subfield of ML, DL-based diagnosis models have an increased performance compared to computer-aided detection systems due to improved representations of the lesion features. It helps to improve the additional diagnosis criteria in the diagnosis process by obtaining effective unobservable data from the extracted features from the medical images quantitatively.20 DL consists of multiple layers in the optimization process for learning the detected and/or extracted features of lesions/nodules on the related images.21 Specifically, DL-based algorithms are trained with CT image data for obtaining the characteristics and diagnostic criteria of related diseases through the extracted/detected features from CT images.22

While investigating the etiology of pleural effusion, medical treatment is primarily planned in patients with heart failure and minimal pleural effusion, thoracentesis is performed at the initial stage in the other group of patients. Biochemical and cytopathological analysis of the fluid sample by thoracentesis is the major laboratory test to be performed. The separation of exudate/transudate and differentiation of malignant/benign through cytological examination can be made by analyzing the fluid obtained from the pleural space using diagnostic thoracentesis. Light criteria are used to differentiate transudates from exudates.23 MPEs constitute 42%–72% of exudative fluids.124 In cases where thoracentesis is not sufficient for the diagnosis, advanced invasive procedures, such as pleural biopsy/video-assisted thoracoscopic biopsy are used in the pathological diagnosis of malignant diseases.

Posterior-anterior chest radiography is the common technique used in patients with fluid detection followed by ultrasonography, which provides guidance for thoracentesis. Thoracic ultrasonography helps in characterizing pleural fluid and determining localization while sampling. However, Computed Tomography (CT) is the most preferred method because it gives more information about the nature of the effusion (tumor, if any) and the spread of the disease. In addition to showing the amount and location of the effusion, CT can also detect the presence of diseases such as pneumonia and malignancy underlying the etiology. Moreover, it is very easy to detect and characterize the lesions in CT when contrast material is used. However, imaging findings are not always successful in definitively distinguishing MPEs, mesothelioma, and other diseases. Findings of CT examination have moderate sensitivity and high specificity in distinguishing malign/benign pleural effusion/lesions.2526

Image processing has a crucial role in many medical applications fields.27 Deep learning can be used in image processing, image analysis, image classification, image segmentation, feature/object detection, and image retrieval.28–30 Recently it has provided great success in the detection of nodule regions on medical images and classification of the lymph nodes. Major advances have been provided in the analysis of the sonographic features of nodules on digital medical images for the identification of malignancy by using deep learning.31 The core aim of deep learning is to teach computers how to recognize an ideal pattern when giving these approaches a set of data.32

Pleural disease is becoming more frequent and complex requiring specialist management. Diagnosing and managing the pleural disease can be complex and challenging.6 Artificial Intelligence (AI) has been widely used in the field of modern medicine and can help pathologists make more accurate diagnoses.2 Additionally, AI in the medical field has become a research hotpot and holds the promise to automatically diagnose heterogeneous diseases with high accuracy.4 In recent years, many diagnostic deep-learning approaches such as image classification, disease detection and lesion location have been developed by using chest radiographic images.33

One of the main issues in the differential diagnosis of pleural effusion is distinguishing exudates from transudates. Determining the nature of pleural effusion (exudate or transudate) allows for reducing the list of potential pleural causes and indicates the direction for further diagnosis. Another important clinical issue is the etiology of effusion – malignant or benign – is crucial for PE management and prognosis. Combining clinical data using deep learning can enable the development of a novel model for distinguishing the etiology of pleural effusion.34

Therefore, developing a useful method that can identify MPE as early as possible with precision is highly important.35 Accurate identification of patients with a high probability of MPE is critical to deploy optimal interventions and thus improving patients' clinical outcomes. Hence, a convenient method with a minimum invasion that can accurately identify malignancy from BPE as early as possible is highly desirable. Therefore, it is aimed to explore the applicability of deep learning techniques to distinguish MPE from BPE.4

This study aimed to identify malignant and benign samples from CT images. The general framework of the proposed method is in Figure 1. The texture patches of the PE images were cropped manually by MATLAB (version 9.3.0.713579 [R2017b]). The evaluation process of all cropped PE images was performed by Microsoft Azure Machine Learning Studio-Deep Learning Tool (version 1.6.4.0, release status 3/31/2021) with a license from Recep Tayyip Erdogan University.

Fig. 1.

Full size Chest CT image with pleural effusion (1a), region of interest for pleural effusion (1b), extracted feature of pleural effusion (1c).

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The authors conducted this diagnostic study following STARD guidelines.36

The present study is a retrospective, single-center study using file and image records. Between September 2021 and May 2022, 64 adult patients (> 18 years) patients who were followed up in the clinic with the diagnosis of pleural effusion were included. CT images of the patients were examined, and 408 images of various sections from each patient were recorded in JPEG format. In the next process, the region of interest for pleural effusion is determined and features extracted from chest CT images (Fig. 1). Patient characteristics such as age, sex, weight, height, etiology, and effusion side were collected for further analysis.

The cytology results of the thoracentesis fluid samples of the patients were obtained from the file records and were recorded for malignant or benign characteristics. The images obtained were classified by deep learning method within the scope of AI. It used 378 images for the training of the system and different 15 malignant and 15 benign CT images were randomly selected that were used as a test data set. It obtained the prediction output for diagnosis as malign or benign of the tested images (Fig. 2 ‒ Adapted from37).

Fig. 2.

Framework of the deep learning based diagnostic system for pleural effusion (adapted from 37).

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These values obtained by analyzing the diagnostic prediction results of the tested images were compared with the pathology results and the obtained data were evaluated statistically. Diagnostic accuracy, positive predictive value, and negative predictive values were calculated for the computer-aided program to predict the malignant or benign characteristics of the fluid samples.

Patients over 18 years of age who underwent CT with a diagnosis of pleural effusion in the last 5 years were included. Patients with pleural effusion but without thoracentesis indication or who could not undergo thoracentesis due to a contraindication and patients who underwent thoracentesis but did not have cytology examination of thoracentesis fluid were not included in the study. The pathology results of three consecutive thoracenteses were recorded. Especially in cytology results with benign results, three consecutive thoracenteses was determined as an inclusion criterion.

SPSS 17.0 (IBM, Armonk, NY, United States) was used for statistical analysis. Normally distributed data were reported as the mean (±SD), and non-normally distributed data were expressed as the median (interquartile range). The prediction percentages (malignant or benign) of a diagnostic algorithm created with a computer-aided decision system were determined in the tested pleural effusion tomography images. The rates of malignant and non-malignant and benign and non-benign lesions in the malignant and benign effusion tomography images were compared using the Chi-Square test. The receiver operating characteristic curve was constructed to evaluate the diagnostic performance of the computer-aided decision system. Sensitivity, specificity, positive predictive value, negative predictive value, positive likelihood ratio, negative likelihood ratio, and the corresponding 95% Confidence Intervals (95% CIs) were estimated with these cut-off values. A p-value < 0.05 was considered statistically significant.

The ethics committee approval was obtained from Recep Tayyip Erdogan University Clinical Research Ethics Committee (Ethics Committee Approval no: 2021/90).

The mean age of 64 patients (40M, 24F) included in the study was 68 years. The p-values between the training and test sets for age and sex were 0.1307 and 0.3837, respectively, which are greater than 0.05 and indicate a balanced distribution between the two sets (Table 1).

The authors used 378 of the 408 CT images obtained from these patients for training the system, and another 30 CT images for testing the computer system. These 30 images contain 15 malign and 15 benign images for testing the computer system. The training and test sets achieved a balance in most of the characteristics.

Training Dataset images: 13 patients with lung adenocarcinoma, 5 patients with ovarian cancer metastasis, 3 patients with squamous cell lung cancer, 3 patients with prostate cancer metastasis, 2 patients with breast cancer metastasis, 2 patients with small cell lung cancer, 1 patient with renal cell cancer metastasis, 14 patients with parapneumonic effusion, 7 patients had heart failure, 2 patients had pleural effusion secondary to peritoneal fluid, and 1 patient secondary to tuberculosis.

Test Dataset images: The diagnoses of 15 malignant patients from the patients in the data set used for the test; 7 patients had lung adenocarcinoma, 1 patient had small cell lung cancer, 1 patient had large cell neuroendocrine tumor, and 1 patient had squamous cell carcinoma. And 5 patients had metastatic pleural effusion. Patients with metastases had ovarian cancer metastasis in 2 patients, breast cancer metastasis in 2 patients, and renal cell carcinoma metastasis in 1 patient. The diagnoses of 15 benign patients from the patients in the data set used for the test: parapneumonic effusion in 5 patients, heart failure in 4 patients, hypoalbuminemia in 2 patients, renal failure in 2 patients, liver failure in 1 patient, pleural effusion due to tuberculosis in 1 patient.

The diagnosis was correctly predicted in 14 of 15 malignant patients and 13 of 15 benign patients among 30 test images evaluated by the system that is represented as Receiver Operating Characteristics diagnostic yields (PPV: 93.3%, NPV: 86.67%, Sensitivity: 87.5%, Specificity: 92.86%) and statistical significances values (Table 2; Figs. 3 and 4). The diagnostic accuracy calculated by deep learning is 90%.

Fig. 3.

Testing of tomography images of malignant effusions and comparison of predicted diagnosis of malignancy and benign based on the analysis.

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Fig. 4.

Testing of tomography images of benign effusions and comparison of predicted diagnosis of malignancy and benign based on the analysis.

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The model had an Area Under the receiver operating Characteristic Curve (AUC) of 0.791 with a 95% Confidence Interval (95% CI) of 0.623–0.959; p-value = 0.007 (Fig. 5).

Fig. 5.

ROC plot with pointwise 95% confidence bounds with the malign and benign pleural effusion CT images train and test with computer-aided decision system. AUC: 0.791; p-value = 0.007.

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The most significant limitation of the present study is that it is a single-center and retrospective study. In prospective studies with larger case series, higher diagnostic power, and accuracy can be obtained with better-trained systems by using more test data.

(I) Conception and design: NO; (II) Administrative support: AG; (III) Provision of study materials or patients: NO, NMGZ, IS; (IV) Collection and assembly of data: NO, NMGZ, IS; (V) Data analysis and interpretation: AEO, AG; (VI) Manuscript writing: All authors; (VII) Final approval of manuscript: All authors.