Abstract

(1) Background: To evaluate the effects of an AI-based denoising post-processing software solution in low-dose whole-body computer tomography (WBCT) stagings; (2) Methods: From 1 January 2019 to 1 January 2021, we retrospectively included biometrically matching melanoma patients with clinically indicated WBCT staging from two scanners. The scans were reconstructed using weighted filtered back-projection (wFBP) and Advanced Modeled Iterative Reconstruction strength 2 (ADMIRE 2) at 100% and simulated 50%, 40%, and 30% radiation doses. Each dataset was post-processed using a novel denoising software solution. Five blinded radiologists independently scored subjective image quality twice with 6 weeks between readings. Inter-rater agreement and intra-rater reliability were determined with an intraclass correlation coefficient (ICC). An adequately corrected mixed-effects analysis was used to compare objective and subjective image quality. Multiple linear regression measured the contribution of “Radiation Dose”, “Scanner”, “Mode”, “Rater”, and “Timepoint” to image quality. Consistent regions of interest (ROI) measured noise for objective image quality; (3) Results: With good–excellent inter-rater agreement and intra-rater reliability (Timepoint 1: ICC ≥ 0.82, 95% CI 0.74–0.88; Timepoint 2: ICC ≥ 0.86, 95% CI 0.80–0.91; Timepoint 1 vs. 2: ICC ≥ 0.84, 95% CI 0.78–0.90; all p ≤ 0.001), subjective image quality deteriorated significantly below 100% for wFBP and ADMIRE 2 but remained good–excellent for the post-processed images, regardless of input (p ≤ 0.002). In regression analysis, significant increases in subjective image quality were only observed for higher radiation doses (≥0.78, 95%CI 0.63–0.93; p < 0.001), as well as for the post-processed images (≥2.88, 95%CI 2.72–3.03, p < 0.001). All post-processed images had significantly lower image noise than their standard counterparts (p < 0.001), with no differences between the post-processed images themselves. (4) Conclusions: The investigated AI post-processing software solution produces diagnostic images as low as 30% of the initial radiation dose (3.13 ± 0.75 mSv), regardless of scanner type or reconstruction method. Therefore, it might help limit patient radiation exposure, especially in the setting of repeated whole-body staging examinations.

Highlights

  • This article is an open access articleDue to repeated follow-up examinations to monitor therapy, the most common indication for whole-body computed tomography (WBCT) is malignant diseases [1]

  • This study aimed to evaluate the effects of an AI denoising algorithm on image quality in whole-body computer tomography (WBCT) stagings of melanoma patients

  • We hypothesize that the software may produce diagnostic images at low radiation doses beyond the limits of conventional reconstruction methods and help limit radiation exposure

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Summary

Introduction

This article is an open access articleDue to repeated follow-up examinations to monitor therapy, the most common indication for whole-body computed tomography (WBCT) is malignant diseases [1]. The substantial contribution of WBCT to the patients’ overall radiation exposure led to a growing concern in recent years regarding difficultly predictable long-term harms [2,3,4]. This concern is especially elevated in cancer patients, where studies show a significant distributed under the terms and conditions of the Creative Commons. The limits of conventional reconstruction methods for image quality enhancements in low-dose computed tomography have previously been explored [11]. Facilitating low-dose WBCT for patients with metastatic melanoma is no easy task, as rising image noise can severely complicate proper visual assessment [19]. We hypothesize that the software may produce diagnostic images at low radiation doses beyond the limits of conventional reconstruction methods and help limit radiation exposure

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