Usefulness of longitudinal nodule-matching algorithm in computer-aided diagnosis of new pulmonary metastases on cancer surveillance CT scans

Sung Hyun Yoon; Dong Yul Oh; Hyo Jin Kim; Sowon Jang; Minseon Kim; Jihang Kim; Kyung Won Lee; Kyong Joon Lee; Junghoon Kim

doi:10.21037/qims-23-1174

Usefulness of longitudinal nodule-matching algorithm in computer-aided diagnosis of new pulmonary metastases on cancer surveillance CT scans

Quant Imaging Med Surg. 2024 Feb 1;14(2):1493-1506. doi: 10.21037/qims-23-1174. Epub 2024 Jan 2.

Authors

Sung Hyun Yoon^#¹, Dong Yul Oh^#², Hyo Jin Kim¹, Sowon Jang¹, Minseon Kim¹, Jihang Kim¹, Kyung Won Lee¹, Kyong Joon Lee^{1

2}, Junghoon Kim¹

Affiliations

¹ Department of Radiology, Seoul National University Bundang Hospital, Seongnam, Republic of Korea.
² Monitor Corporation, Seoul, Republic of Korea.

^# Contributed equally.

Abstract

Background: Detecting new pulmonary metastases by comparing serial computed tomography (CT) scans is crucial, but a repetitive and time-consuming task that burdens the radiologists' workload. This study aimed to evaluate the usefulness of a nodule-matching algorithm with deep learning-based computer-aided detection (DL-CAD) in diagnosing new pulmonary metastases on cancer surveillance CT scans.

Methods: Among patients who underwent pulmonary metastasectomy between 2014 and 2018, 65 new pulmonary metastases missed by interpreting radiologists on cancer surveillance CT (Time 2) were identified after a retrospective comparison with the previous CT (Time 1). First, DL-CAD detected nodules in Time 1 and Time 2 CT images. All nodules detected at Time 2 were initially considered metastasis candidates. Second, the nodule-matching algorithm was used to assess the correlation between the nodules from the two CT scans and to classify the nodules at Time 2 as "new" or "pre-existing". Pre-existing nodules were excluded from metastasis candidates. We evaluated the performance of DL-CAD with the nodule-matching algorithm, based on its sensitivity, false-metastasis candidates per scan, and positive predictive value (PPV).

Results: A total of 475 lesions were detected by DL-CAD at Time 2. Following a radiologist review, the lesions were categorized as metastases (n=54), benign nodules (n=392), and non-nodules (n=29). Upon comparison of nodules at Time 1 and 2 using the nodule-matching algorithm, all metastases were classified as new nodules without any matching errors. Out of 421 benign lesions, 202 (48.0%) were identified as pre-existing and subsequently excluded from the pool of metastasis candidates through the nodule-matching algorithm. As a result, false-metastasis candidates per CT scan decreased by 47.9% (from 7.1 to 3.7, P<0.001) and the PPV increased from 11.4% to 19.8% (P<0.001), while maintaining sensitivity.

Conclusions: The nodule-matching algorithm improves the diagnostic performance of DL-CAD for new pulmonary metastases, by lowering the number of false-metastasis candidates without compromising sensitivity.

Keywords: Deep learning (DL); computed tomography (CT); computer-aided detection (CAD); pulmonary metastasis; pulmonary nodule.