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使用模块化、多用途体模评估锥形束 CT 剂量和成像性能。

Cone-beam CT dose and imaging performance evaluation with a modular, multipurpose phantom.

机构信息

Department of Biomedical Engineering, Johns Hopkins University, Baltimore, MD, 21205, USA.

Department of Radiology, University of California - Davis, Sacramento, CA, 95817, USA.

出版信息

Med Phys. 2020 Feb;47(2):467-479. doi: 10.1002/mp.13952. Epub 2019 Dec 25.

DOI:10.1002/mp.13952
PMID:31808950
Abstract

PURPOSE

A modular phantom for dosimetry and imaging performance evaluation in cone-beam computed tomography (CBCT) is reported, providing a tool for quantitative technical assessment that can be adapted to a broad variety of CBCT imaging configurations and clinical applications.

METHODS

The phantom presents a set of modules that can be ordered in various configurations suitable to a particular CBCT system. Modules include slabs containing a uniform medium, low-contrast inserts, line-spread features, and disk features suitable to measurement of image uniformity, noise, noise-power spectrum (NPS), contrast, contrast-to-noise ratio (CNR), Hounsfield (HU) accuracy, linearity, spatial resolution modulation transfer function (MTF), and magnitude of cone-beam artifact. Automated software recognizes the phantom configuration in DICOM images and provides structured reporting of such test measures. In any modular configuration, the phantom permits measurement of air kerma in central and peripheral locations with an air ionization chamber (e.g., Farmer chamber). The utility and adaptability of the phantom were demonstrated across a spectrum of CBCT systems, including scanners for orthopaedic imaging (Carestream OnSight 3D, Rochester NY), breast imaging (Doheny prototype, UC Davis), image-guided surgery (IGS, Medtronic O-arm, Littleton MA), angiography (Siemens Artis Zeego, Forcheim Germany), and image-guided radiation therapy (IGRT, Elekta Synergy XVI, Stockholm Sweden).

RESULTS

The phantom provided a consistent platform for quantitative assessment of dose and imaging performance compatible with a broad spectrum of CBCT systems. The purpose of the survey was not to obtain head-to-head performance comparison of systems designed for such distinct clinical applications. Rather, the survey demonstrated the suitability of the phantom to a broad spectrum of systems in a manner that provides characterization pertinent to disparate applications and imaging tasks. For example: the orthopaedic CBCT system (pertinent clinical tasks relating to high-resolution bone imaging) was shown to achieve MTF consistent with imaging of high-contrast trabecular bone structures (i.e., the MTF reduced to 10% at spatial frequency,  = 1.2 mm ); the breast system (even higher-resolution imaging of microcalcifications) exhibited  = 2.2 mm ; the IGS system (tasks including both bone and soft-tissue contrast resolution) provided  = 0.9 mm and soft-tissue  = 1.64; the angiography system (soft-tissue body interventions) demonstrated  = 1.2 in soft tissues approximating liver lesions; and the IGRT system (pertinent tasks emphasizing HU linearity and image uniformity) showed linear response with HU values (  = 1), with a cupping artifact (  = 5.8%) due to x-ray scatter.

CONCLUSIONS

The phantom provides an adaptable, quantitative basis for CBCT dosimetry and imaging performance evaluation suitable to a broad variety of CBCT systems. The dosimetry and image quality metrics are consistent with up-to-date methods for rigorous, quantitative, physics testing and should be suitable to emerging standards for CBCT quality assurance.

摘要

目的

本文报道了一种用于锥束 CT(CBCT)剂量学和成像性能评估的模块化体模,为定量技术评估提供了一种工具,可适应广泛的 CBCT 成像配置和临床应用。

方法

该体模提供了一组模块,可根据特定的 CBCT 系统以各种配置进行订购。模块包括含有均匀介质、低对比度插件、线扩散特征和磁盘特征的平板,可用于测量图像均匀性、噪声、噪声功率谱(NPS)、对比度、对比噪声比(CNR)、亨氏(HU)精度、线性度、空间分辨率调制传递函数(MTF)以及圆锥束伪影的幅度。自动化软件可识别 DICOM 图像中的体模配置,并提供此类测试结果的结构化报告。在任何模块化配置中,体模都允许使用空气电离室(例如,Farmer 室)在中央和外围位置测量空气比释动能。该体模在包括骨科成像(Carestream OnSight 3D,纽约罗彻斯特)、乳腺成像(Doheny 原型,加州大学戴维斯分校)、图像引导手术(IGS,美敦力 O 臂,利特尔顿,马萨诸塞州)、血管造影(西门子 Artis Zeego,德国福海姆)和图像引导放射治疗(IGRT,医科达 Synergy XVI,斯德哥尔摩,瑞典)在内的一系列 CBCT 系统中展示了其适用性和可适应性。

结果

该体模为与广泛的 CBCT 系统兼容的剂量和成像性能的定量评估提供了一致的平台。该调查的目的不是对头对头的系统性能进行比较,这些系统是为如此不同的临床应用而设计的。相反,该调查以与不同应用和成像任务相关的方式展示了体模对广泛系统的适用性,提供了与离散应用相关的特征。例如:骨科 CBCT 系统(与高分辨率骨成像相关的临床任务)实现的 MTF 与高对比度小梁骨结构的成像一致(即 MTF 在空间频率为 1.2mm 时降低到 10%);乳腺系统(甚至更高分辨率的微钙化成像)显示 2.2mm;IGS 系统(包括骨和软组织对比度分辨率的任务)提供 0.9mm 和软组织 1.64;血管造影系统(软组织体干预)显示软组织中 1.2 近似肝病变;而 IGRT 系统(强调 HU 线性度和图像均匀性的相关任务)显示 HU 值的线性响应( = 1),由于 X 射线散射而存在杯状伪影( = 5.8%)。

结论

该体模为广泛的 CBCT 系统提供了一种适应性强、定量的 CBCT 剂量学和成像性能评估基础。剂量学和图像质量指标与严格、定量、物理测试的最新方法一致,应适用于新兴的 CBCT 质量保证标准。

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