Deep learning-based volume of interest imaging in helical CT for image quality improvement and radiation dose reduction.

IF 3.4 4区医学 Q3 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

British Journal of Radiology Pub Date : 2025-09-13 DOI:10.1093/bjr/tqaf128

Zhongxing Zhou, Akitoshi Inoue, Christian W Cox, Cynthia H McCollough, Lifeng Yu

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引用次数: 0

Abstract

Objectives: To develop a volume of interest (VOI) imaging technique in multi-detector-row helical CT to reduce radiation dose or improve image quality within the VOI.

Methods: A deep-learning method based on a residual U-Net architecture, named VOI-Net, was developed to correct truncation artifacts in VOI helical CT. Three patient cases, a chest CT of interstitial lung disease and 2 abdominopelvic CT of liver tumour, were used for evaluation through simulation.

Results: VOI-Net effectively corrected truncation artifacts (root mean square error [RMSE] of 5.97 ± 2.98 Hounsfield Units [HU] for chest, 3.12 ± 1.93 HU, and 3.71 ± 1.87 HU for liver). Radiation dose was reduced by 71% without sacrificing image quality within a 10-cm diameter VOI, compared to a full scan field of view (FOV) of 50 cm. With the same total energy deposited as in a full FOV scan, image quality within the VOI matched that at 350% higher radiation dose. A radiologist confirmed improved lesion conspicuity and visibility of small linear reticulations associated with ground-glass opacity and liver tumour.

Conclusions: Focusing radiation on the VOI and using VOI-Net in a helical scan, total radiation can be reduced or higher image quality equivalent to those at higher doses in standard full FOV scan can be achieved within the VOI.

Advances in knowledge: A targeted helical VOI imaging technique enabled by a deep-learning-based artifact correction method improves image quality within the VOI without increasing radiation dose.

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基于深度学习的螺旋CT感兴趣体积成像提高图像质量和降低辐射剂量。

目的：发展多排螺旋CT感兴趣体积成像技术，以降低感兴趣体积内的辐射剂量或提高图像质量。方法：提出了一种基于残差U-Net结构的深度学习方法VOI- net，用于纠正VOI螺旋CT中的截断伪影。采用3例肺间质性疾病胸部CT和2例肝肿瘤腹腔CT进行模拟评价。结果：VOI-Net有效地纠正了截断伪像（胸部的均方根误差[RMSE]为5.97±2.98 Hounsfield单位[HU]，肝脏的均方根误差为3.12±1.93 HU, 3.71±1.87 HU）。与50厘米的全扫描视场（FOV）相比，在直径10厘米的VOI内，辐射剂量减少了71%，而不牺牲图像质量。在与全视场扫描相同的总能量沉积下，VOI内的图像质量与高350%辐射剂量下的图像质量相匹配。一位放射科医生证实，与毛玻璃混浊和肝脏肿瘤相关的小线状网状病变的显著性和可见性得到改善。结论：利用VOI- net对VOI进行螺旋扫描，可以减少VOI内的总辐射或获得相当于标准全视场扫描中较高剂量的图像质量。知识进步：基于深度学习的伪影校正方法实现了靶向螺旋VOI成像技术，在不增加辐射剂量的情况下提高了VOI内的图像质量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

British Journal of Radiology 医学-核医学

CiteScore

5.30

自引率

3.80%

发文量

330

审稿时长

2-4 weeks

期刊介绍： BJR is the international research journal of the British Institute of Radiology and is the oldest scientific journal in the field of radiology and related sciences. Dating back to 1896, BJR’s history is radiology’s history, and the journal has featured some landmark papers such as the first description of Computed Tomography "Computerized transverse axial tomography" by Godfrey Hounsfield in 1973. A valuable historical resource, the complete BJR archive has been digitized from 1896. Quick Facts: - 2015 Impact Factor – 1.840 - Receipt to first decision – average of 6 weeks - Acceptance to online publication – average of 3 weeks - ISSN: 0007-1285 - eISSN: 1748-880X Open Access option