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人工智能深度学习重建算法对 CT 图像质量和潜在剂量降低的影响:一项体模研究。

Impact of an artificial intelligence deep-learning reconstruction algorithm for CT on image quality and potential dose reduction: A phantom study.

机构信息

IMAGINE, UR UM 103, Montpellier University, Department of Medical Imaging, Nîmes University Hospital, Nîmes, France.

University of Lyon, INSA-Lyon, University Claude Bernard Lyon 1, UJM-Saint Etienne, CNRS, Inserm, CREATIS UMR 5220, U1206, Villeurbanne, France.

出版信息

Med Phys. 2022 Aug;49(8):5052-5063. doi: 10.1002/mp.15807. Epub 2022 Jun 24.

DOI:10.1002/mp.15807
PMID:35696272
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9544990/
Abstract

BACKGROUND

Recently, computed tomography (CT) manufacturers have developed deep-learning-based reconstruction algorithms to compensate for the limitations of iterative reconstruction (IR) algorithms, such as image smoothing and the spatial resolution's dependence on contrast and dose levels.

PURPOSE

To assess the impact of an artificial intelligence deep-learning reconstruction (AI-DLR) algorithm on image quality and dose reduction compared with a hybrid IR algorithm in chest CT for different clinical indications.

METHODS

Acquisitions on the CT American College of Radiology (ACR) 464 and CT Torso CTU-41 phantoms were performed at five dose levels (CTDI : 9.5/7.5/6/2.5/0.4 mGy) used for chest CT conditions. Raw data were reconstructed using filtered backprojection, two levels of IR (iDose levels 4 (i4) and 7 (i7)), and five levels of AI-DLR (Precise Image; Smoother, Smooth, Standard, Sharp, Sharper). Noise power spectrum (NPS), task-based transfer function, and detectability index (d') were computed: d'-modeled detection of a soft tissue mediastinal nodule (low-contrast soft tissue chest nodule within the mediastinum [LCN]), ground-glass opacity (GGO), or high-contrast pulmonary (HCP) lesion. The subjective image quality of chest anthropomorphic phantom images was independently evaluated by two radiologists. They assessed image noise, image smoothing, contrast between vessels and fat in the mediastinum for mediastinal images, visual border detection between bronchus and lung parenchyma for parenchymal images, and overall image quality using a commonly used four- or five-point scale.

RESULTS

From Standard to Smoother levels, on average, the noise magnitude decreased (for all dose levels: -66.3% ± 0.5% for mediastinal images and -63.1% ± 0.1% for parenchymal images), the average NPS spatial frequency decreased (for all dose levels: -35.3% ± 2.2% for mediastinal images and -13.3% ± 2.2% for parenchymal images), and the detectability (d') of the three lesions increased. The opposite pattern was found from Standard to Sharper levels. From Smoother to Sharper levels, the spatial resolution increased for the low-contrast polyethylene insert and the opposite for the high-contrast air insert. Compared to the i4 used in clinical practice, d' values were higher using Smoother (mean for all dose levels: 338.7% ± 29.4%), Smooth (103.4% ± 11.2%), and Standard (34.1% ± 6.6%) levels for the LCN on mediastinal images and Smoother (169.5% ± 53.2% for GGO and 136.9% ± 1.6% for HCP) and Smooth (36.4% ± 22.1% and 24.1% ± 0.9%, respectively) levels for parenchymal images. Radiologists considered the images satisfactory for clinical use at these levels, but adaptation to the dose level of the protocol is required.

CONCLUSION

With AI-DLR, the smoothest levels reduced the noise and improved the detectability of chest lesions but increased the image smoothing. The opposite was found with the sharpest levels. The choice of level depends on the dose level and type of image: mediastinal or parenchymal.

摘要

背景

最近,计算机断层扫描(CT)制造商开发了基于深度学习的重建算法,以弥补迭代重建(IR)算法的局限性,例如图像平滑和空间分辨率对对比和剂量水平的依赖。

目的

在不同的临床适应证下,评估人工智能深度学习重建(AI-DLR)算法与混合 IR 算法相比,在胸部 CT 中对图像质量和剂量降低的影响。

方法

在五个剂量水平(CTDI:9.5/7.5/6/2.5/0.4 mGy)下,使用胸部 CT 条件对 CT 美国放射学院(ACR)464 和 CT 胸部 CTU-41 体模进行采集。使用滤波反投影、两级 IR(iDose 水平 4(i4)和 7(i7))和五级 AI-DLR(精确图像;平滑、平滑、标准、锐利、更锐利)重建原始数据。计算噪声功率谱(NPS)、基于任务的传递函数和可检测性指数(d'):d'-模拟软组织纵隔结节(纵隔内低对比度软组织结节[LCN])、磨玻璃影(GGO)或高对比度肺(HCP)病变的检测。两名放射科医生独立评估胸部拟人化体模图像的主观图像质量。他们使用常用的四或五分制评估图像噪声、血管与纵隔脂肪的图像平滑度、肺实质图像支气管与肺实质的视觉边界检测以及整体图像质量。

结果

从标准到平滑水平,平均而言,噪声幅度降低(所有剂量水平:纵隔图像为-66.3%±0.5%,肺实质图像为-63.1%±0.1%),平均 NPS 空间频率降低(所有剂量水平:纵隔图像为-35.3%±2.2%,肺实质图像为-13.3%±2.2%),三种病变的检测(d')增加。从标准到锐利水平则相反。从平滑到锐利水平,低对比度聚乙烯插件的空间分辨率增加,而高对比度空气插件的空间分辨率降低。与临床实践中使用的 i4 相比,LCN 在纵隔图像上的 Smoother(所有剂量水平的平均值:338.7%±29.4%)、Smooth(103.4%±11.2%)和 Standard(34.1%±6.6%)水平以及 GGO 的 Smoother(169.5%±53.2%)和 HCP 的 Smoother(136.9%±1.6%)和 Smooth(36.4%±22.1%和 24.1%±0.9%)水平的 d'值更高。放射科医生认为这些水平的图像可满足临床使用要求,但需要适应协议的剂量水平。

结论

使用 AI-DLR,最平滑的水平降低了噪声并提高了胸部病变的检测能力,但增加了图像平滑度。最锐利的水平则相反。水平的选择取决于剂量水平和图像类型:纵隔或肺实质。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/84ad/9544990/b7e525a2d196/MP-49-5052-g001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/84ad/9544990/f3550c4fa6c8/MP-49-5052-g004.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/84ad/9544990/5e001c145bac/MP-49-5052-g003.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/84ad/9544990/f3550c4fa6c8/MP-49-5052-g004.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/84ad/9544990/b7e525a2d196/MP-49-5052-g001.jpg

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