Automatic detection of multisize pulmonary nodules in CT images: Large-scale validation of the false-positive reduction step

Anindya Gupta; Tonis Saar; Olev Martens; Yannick Le Moullec

doi:10.1002/mp.12746

Automatic detection of multisize pulmonary nodules in CT images: Large-scale validation of the false-positive reduction step

Med Phys. 2018 Mar;45(3):1135-1149. doi: 10.1002/mp.12746. Epub 2018 Jan 23.

Authors

Anindya Gupta¹, Tonis Saar², Olev Martens¹, Yannick Le Moullec¹

Affiliations

¹ Thomas Johann Seebeck Department of Electronics, Tallinn University of Technology, Tallinn, 19086, Estonia.
² Eliko Tehnoloogia Arenduskeskus OÜ, Tallinn 12618 and OÜ, Tallinn, 10143, Estonia.

PMID: 29359462
DOI: 10.1002/mp.12746

Abstract

Purpose: Currently reported computer-aided detection (CAD) approaches face difficulties in identifying the diverse pulmonary nodules in thoracic computed tomography (CT) images, especially in heterogeneous datasets. We present a novel CAD system specifically designed to identify multisize nodule candidates in multiple heterogeneous datasets.

Methods: The proposed CAD scheme is divided into two phases: primary phase and final phase. The primary phase started with the lung segmentation algorithm and the segmented lungs were further refined using morphological closing process to include the pleural nodules. Next, we empirically formulated three subalgorithms modules to detect different sizes of nodule candidates (≥3 and <6 mm; ≥6 and <10 mm; and ≥10 mm). Each subalgorithm module included a multistage flow of rule-based thresholding and morphological processes. In the final phase, the nodule candidates were augmented to boost the performance of the classifier. The CAD system was trained using a total number of nodule candidates = 201,654 (after augmentation) and nonnodule candidates = 731,486. A rich set of 515 features based on cluster, texture, and voxel-based intensity features were utilized to train a neural network classifier. The proposed method was trained on 899 scans from the Lung Image Database Consortium/Image Database Resource Initiative (LIDC-IDRI). The CAD system was also independently tested on 153 CT scans taken from the AAPM-SPIE-LungX Dataset and two subsets from the Early Lung Cancer Action Project (ELCAP and PCF).

Results: For the LIDC-IDRI training set, the proposed CAD scheme yielded an overall sensitivity of 85.6% (1189/1390) and 83.5% (1161/1390) at 8 FP/scan and 1 FP/scan, respectively. For the three independent test sets, the CAD system achieved an average sensitivity of 68.4% at 8 FP/scan.

Conclusion: The authors conclude that the proposed CAD system can identify dissimilar nodule candidates in the multiple heterogeneous datasets. It could be considered as a useful tool to support radiologists during screening trials.

Keywords: AAPM-SPIE-LungX challenge; LIDC−IDRI, pulmonary nodules; computed tomography (CT); computer-aided detection (CAD).

Publication types

Validation Study

MeSH terms

Automation
Diagnosis, Computer-Assisted / methods*
False Positive Reactions
Image Processing, Computer-Assisted
Lung Neoplasms / diagnostic imaging*
Tomography, X-Ray Computed*