Impact of deep learning image reconstruction on volumetric accuracy and image quality of pulmonary nodules with different morphologies in low-dose CT.

IF 3.5 2区 医学 Q2 ONCOLOGY
L D'hondt, C Franck, P-J Kellens, F Zanca, D Buytaert, A Van Hoyweghen, H El Addouli, K Carpentier, M Niekel, M Spinhoven, K Bacher, A Snoeckx
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引用次数: 0

Abstract

Background: This study systematically compares the impact of innovative deep learning image reconstruction (DLIR, TrueFidelity) to conventionally used iterative reconstruction (IR) on nodule volumetry and subjective image quality (IQ) at highly reduced radiation doses. This is essential in the context of low-dose CT lung cancer screening where accurate volumetry and characterization of pulmonary nodules in repeated CT scanning are indispensable.

Materials and methods: A standardized CT dataset was established using an anthropomorphic chest phantom (Lungman, Kyoto Kaguku Inc., Kyoto, Japan) containing a set of 3D-printed lung nodules including six diameters (4 to 9 mm) and three morphology classes (lobular, spiculated, smooth), with an established ground truth. Images were acquired at varying radiation doses (6.04, 3.03, 1.54, 0.77, 0.41 and 0.20 mGy) and reconstructed with combinations of reconstruction kernels (soft and hard kernel) and reconstruction algorithms (ASIR-V and DLIR at low, medium and high strength). Semi-automatic volumetry measurements and subjective image quality scores recorded by five radiologists were analyzed with multiple linear regression and mixed-effect ordinal logistic regression models.

Results: Volumetric errors of nodules imaged with DLIR are up to 50% lower compared to ASIR-V, especially at radiation doses below 1 mGy and when reconstructed with a hard kernel. Also, across all nodule diameters and morphologies, volumetric errors are commonly lower with DLIR. Furthermore, DLIR renders higher subjective IQ, especially at the sub-mGy doses. Radiologists were up to nine times more likely to score the highest IQ-score to these images compared to those reconstructed with ASIR-V. Lung nodules with irregular margins and small diameters also had an increased likelihood (up to five times more likely) to be ascribed the best IQ scores when reconstructed with DLIR.

Conclusion: We observed that DLIR performs as good as or even outperforms conventionally used reconstruction algorithms in terms of volumetric accuracy and subjective IQ of nodules in an anthropomorphic chest phantom. As such, DLIR potentially allows to lower the radiation dose to participants of lung cancer screening without compromising accurate measurement and characterization of lung nodules.

深度学习图像重建对低剂量 CT 中不同形态肺结节容积精度和图像质量的影响
背景:这项研究系统地比较了创新的深度学习图像重建(DLIR,TrueFidelity)与传统使用的迭代重建(IR)对结节容积测量和主观图像质量(IQ)的影响,同时高度降低辐射剂量。这在低剂量 CT 肺癌筛查中至关重要,因为在重复 CT 扫描中准确测量肺结节的体积和特征是不可或缺的:使用一个拟人化胸部模型(Lungman,Kyoto Kaguku Inc.,日本京都)建立了一个标准化的 CT 数据集,该模型包含一组 3D 打印的肺结节,包括六种直径(4 至 9 毫米)和三种形态类别(小叶状、棘状、光滑),并建立了基本真相。在不同辐射剂量(6.04、3.03、1.54、0.77、0.41 和 0.20 mGy)下采集图像,并使用重建核(软核和硬核)和重建算法(低、中、高强度的 ASIR-V 和 DLIR)组合进行重建。通过多元线性回归和混合效应序数逻辑回归模型,对五位放射科医生记录的半自动体积测量结果和主观图像质量评分进行了分析:与 ASIR-V 相比,使用 DLIR 成像的结节体积误差最多可降低 50%,尤其是在辐射剂量低于 1 mGy 和使用硬核重建时。此外,在所有结节直径和形态中,DLIR 的体积误差普遍较低。此外,DLIR 的主观智商更高,尤其是在亚毫戈瑞剂量下。与使用 ASIR-V 重建的图像相比,放射科医生给这些图像打出最高 IQ 分数的可能性要高出九倍。边缘不规则、直径较小的肺结节在使用 DLIR 重建时获得最佳 IQ 分数的可能性也有所增加(高达五倍):我们观察到,在拟人化胸部模型中,DLIR 在结节的体积准确性和主观智商方面的表现不亚于甚至优于传统的重建算法。因此,DLIR 有可能在不影响肺结节精确测量和特征描述的情况下,降低肺癌筛查参与者的辐射剂量。
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来源期刊
Cancer Imaging
Cancer Imaging ONCOLOGY-RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
CiteScore
7.00
自引率
0.00%
发文量
66
审稿时长
>12 weeks
期刊介绍: Cancer Imaging is an open access, peer-reviewed journal publishing original articles, reviews and editorials written by expert international radiologists working in oncology. The journal encompasses CT, MR, PET, ultrasound, radionuclide and multimodal imaging in all kinds of malignant tumours, plus new developments, techniques and innovations. Topics of interest include: Breast Imaging Chest Complications of treatment Ear, Nose & Throat Gastrointestinal Hepatobiliary & Pancreatic Imaging biomarkers Interventional Lymphoma Measurement of tumour response Molecular functional imaging Musculoskeletal Neuro oncology Nuclear Medicine Paediatric.
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