IMAGINE UR UM 103, Montpellier University, Department of Medical Imaging, Nîmes University Hospital, 30029 Nîmes, France; Department of Medical Physics, Nîmes University Hospital, 30029 Nîmes Cedex 9, France.
IMAGINE UR UM 103, Montpellier University, Department of Medical Imaging, Nîmes University Hospital, 30029 Nîmes, France.
Diagn Interv Imaging. 2023 Feb;104(2):76-83. doi: 10.1016/j.diii.2022.08.004. Epub 2022 Sep 11.
PURPOSE: The purpose of this study was to assess the impact of the new artificial intelligence deep-learning reconstruction (AI-DLR) algorithm on image quality and radiation dose compared with iterative reconstruction algorithm in lumbar spine computed tomography (CT) examination. MATERIALS AND METHODS: Acquisitions on phantoms were performed using a tube current modulation system for four DoseRight Indexes (DRI) (i.e., 26/23/20/15). Raw data were reconstructed using the Level 4 of iDose (i4) and three levels of AI-DLR (Smoother/Smooth/Standard) with a bone reconstruction kernel. The Noise power spectrum (NPS), task-based transfer function (TTF) and detectability index (d') were computed (d' modeled detection of a lytic and a sclerotic bone lesions). Image quality was subjectively assessed on an anthropomorphic phantom by two radiologists. RESULTS: The Noise magnitude was lower with AI-DLR than i4 and decreased from Standard to Smooth (-31 ± 0.1 [SD]%) and Smooth to Smoother (-48 ± 0.1 [SD]%). The average NPS spatial frequency was similar with i4 (0.43 ± 0.01 [SD] mm) and Standard (0.42 ± 0.01 [SD] mm) but decreased from Standard to Smoother (0.36 ± 0.01 [SD] mm). TTF values at 50% decreased as the dose decreased but were similar with i4 and all AI-DLR levels. For both simulated lesions, d' values increased from Standard to Smoother levels. Higher detectabilities were found with a DRI at 15 and Smooth and Smoother levels than with a DRI at 26 and i4. The images obtained with these dose and AI-DLR levels were rated satisfactory for clinical use by the radiologists. CONCLUSION: Using Smooth and Smoother levels with CT allows a significant dose reduction (up to 72%) with a high detectability of lytic and sclerotic bone lesions and a clinical overall image quality.
目的:本研究旨在评估新型人工智能深度学习重建(AI-DLR)算法与迭代重建算法相比,在腰椎 CT 检查中对图像质量和辐射剂量的影响。
材料与方法:使用管电流调制系统对四个 DoseRight 指数(DRI)(即 26/23/20/15)进行体模采集。使用 iDose 第 4 级(i4)和三级 AI-DLR(Smoother/Smooth/Standard)以及骨重建内核对原始数据进行重建。计算噪声功率谱(NPS)、基于任务的传递函数(TTF)和可检测性指数(d')(d' 模拟检测溶骨性和硬化性骨病变)。两名放射科医生对人体模型进行主观评估。
结果:与 i4 相比,AI-DLR 的噪声幅度更低,且从 Standard 降低至 Smooth(-31 ± 0.1 [SD]%)和 Smooth 降低至 Smoother(-48 ± 0.1 [SD]%)。平均 NPS 空间频率与 i4(0.43 ± 0.01 [SD]mm)和 Standard(0.42 ± 0.01 [SD]mm)相似,但从 Standard 降低至 Smoother(0.36 ± 0.01 [SD]mm)。在 50%处的 TTF 值随着剂量的降低而降低,但与 i4 和所有 AI-DLR 水平相似。对于两种模拟病变,d'值从 Standard 升高至 Smoother 水平。与 DRI 为 26 和 i4 相比,在 DRI 为 15 和 Smooth 和 Smoother 水平下检测到的骨病变的可检测性更高。放射科医生认为,使用这些剂量和 AI-DLR 水平获得的图像在临床应用中具有令人满意的总体图像质量。
结论:使用 CT 的 Smooth 和 Smoother 水平可以显著降低剂量(高达 72%),同时保持对溶骨性和硬化性骨病变的高检测能力,并保持整体临床图像质量。
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