使用锥形束和微型计算机断层扫描仪对临床前计算机断层扫描放射组学进行比较分析

Kathryn H. Brown , Brianna N. Kerr , Mihaela Pettigrew , Kate Connor , Ian S. Miller , Liam Shiels , Colum Connolly , Conor K. McGarry , Annette T. Byrne , Karl T. Butterworth
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引用次数: 0

摘要

背景和目的放射组学分析从医学图像中提取定量数据(特征)。这些特征有可能反映生物特征,并作为精准医学中的成像生物标记物。然而,目前缺乏对放射组学输出结果的交叉比较和验证,而这对临床实施至关重要。在这项研究中,我们比较了两种基于计算机断层扫描(CT)的临床前扫描仪的放射组学输出结果。使用一个不同成像能量(40 & 60 kVp)和分割体积(44-238 mm3)的模型对每台扫描仪上放射组学特征的可重复性进行了评估。小鼠回顾性扫描用于比较不同组织密度(肺、心脏、骨骼)、扫描仪和体素大小协调后的特征可靠性。可靠特征的类内相关系数(ICC)为 0.8。结果在不同体积的两种扫描仪上,一阶特征和 GLCM 特征最为可靠。组织密度与特征可靠性之间存在反比关系,肺部的特征数量最多(CBCT=580,µCT=734),而骨骼的特征数量最少(CBCT=110,µCT=560)。统一体素尺寸后,肺部和心脏组织的可比特征增加了。我们确定了小鼠肺(133)、心脏(35)和骨骼(15)的组织特异性临床前放射组学特征。这项研究表明了标准化的重要性,并强调了多中心研究的必要性。
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A comparative analysis of preclinical computed tomography radiomics using cone-beam and micro-computed tomography scanners

Background and purpose

Radiomics analysis extracts quantitative data (features) from medical images. These features could potentially reflect biological characteristics and act as imaging biomarkers within precision medicine. However, there is a lack of cross-comparison and validation of radiomics outputs which is paramount for clinical implementation. In this study, we compared radiomics outputs across two computed tomography (CT)-based preclinical scanners.

Materials and methods

Cone beam CT (CBCT) and µCT scans were acquired using different preclinical CT imaging platforms. The reproducibility of radiomics features on each scanner was assessed using a phantom across imaging energies (40 & 60 kVp) and segmentation volumes (44–238 mm3). Retrospective mouse scans were used to compare feature reliability across varying tissue densities (lung, heart, bone), scanners and after voxel size harmonisation. Reliable features had an intraclass correlation coefficient (ICC) > 0.8.

Results

First order and GLCM features were the most reliable on both scanners across different volumes. There was an inverse relationship between tissue density and feature reliability, with the highest number of features in lung (CBCT=580, µCT=734) and lowest in bone (CBCT=110, µCT=560). Comparable features for lung and heart tissues increased when voxel sizes were harmonised. We have identified tissue-specific preclinical radiomics signatures in mice for the lung (133), heart (35), and bone (15).

Conclusions

Preclinical CBCT and µCT scans can be used for radiomics analysis to support the development of meaningful radiomics signatures. This study demonstrates the importance of standardisation and emphasises the need for multi-centre studies.

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来源期刊
Physics and Imaging in Radiation Oncology
Physics and Imaging in Radiation Oncology Physics and Astronomy-Radiation
CiteScore
5.30
自引率
18.90%
发文量
93
审稿时长
6 weeks
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