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Evaluating attenuation correction strategies in a dedicated, single-gantry breast PET-tomosynthesis scanner.评估专用单探头乳腺 PET-断层融合扫描仪中的衰减校正策略。
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4
Virtual clinical trials in medical imaging: a review.医学成像中的虚拟临床试验:综述
J Med Imaging (Bellingham). 2020 Jul;7(4):042805. doi: 10.1117/1.JMI.7.4.042805. Epub 2020 Apr 11.
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The compressed breast during mammography and breast tomosynthesis: in vivo shape characterization and modeling.乳腺钼靶摄影和乳腺断层合成中受压乳房的体内形状表征与建模
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Non-Gaussian statistical properties of breast images.乳腺图像的非高斯统计特性。
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Optimized generation of high resolution breast anthropomorphic software phantoms.优化生成高分辨率乳房拟人软件体模。
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基于Perlin噪声的新型体模,使用压缩乳房形状的3D模型和分形噪声。

Novel Perlin-based Phantoms Using 3D Models of Compressed Breast Shape and Fractal Noise.

作者信息

Teixeira João P V, Silva Filho Telmo M, do Rêgo Thaís G, Malheiros Yuri B, Dustler Magnus, Bakic Predrag R, Vent Trevor L, Acciavatti Raymond J, Krishnamoorthy Srilalan, Surti Suleman, Maidment Andrew D A, Barufaldi Bruno

机构信息

Department of Computer Science, Federal University of Paraiba, João Pessoa, Brazil.

Department of Translational Medicine, Lund University, Malmö, Sweden.

出版信息

Proc SPIE Int Soc Opt Eng. 2022 Feb-Mar;12031. doi: 10.1117/12.2612565. Epub 2022 Apr 4.

DOI:10.1117/12.2612565
PMID:39351016
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11441370/
Abstract

Virtual clinical trials (VCTs) have been used widely to evaluate digital breast tomosynthesis (DBT) systems. VCTs require realistic simulations of the breast anatomy (phantoms) to characterize lesions and to estimate risk of masking cancers. This study introduces the use of Perlin-based phantoms to optimize the acquisition geometry of a novel DBT prototype. These phantoms were developed using a GPU implementation of a novel library called Perlin-CuPy. The breast anatomy is simulated using 3D models under mammography cranio-caudal compression. In total, 240 phantoms were created using compressed breast thickness, chest-wall to nipple distance, and skin thickness that varied in a {[35, 75], [59, 130), [1.0, 2.0]} mm interval, respectively. DBT projections and reconstructions of the phantoms were simulated using two acquisition geometries of our DBT prototype. The performance of both acquisition geometries was compared using breast volume segmentations of the Perlin phantoms. Results show that breast volume estimates are improved with the introduction of posterior-anterior motion of the x-ray source in DBT acquisitions. The breast volume is overestimated in DBT, varying substantially with the acquisition geometry; segmentation errors are more evident for thicker and larger breasts. These results provide additional evidence and suggest that custom acquisition geometries can improve the performance and accuracy in DBT. Perlin phantoms help to identify limitations in acquisition geometries and to optimize the performance of the DBT prototypes.

摘要

虚拟临床试验(VCTs)已被广泛用于评估数字乳腺断层合成(DBT)系统。VCTs需要对乳房解剖结构进行逼真模拟(体模),以表征病变并估计掩盖癌症的风险。本研究介绍了使用基于柏林噪声的体模来优化新型DBT原型的采集几何结构。这些体模是使用一个名为Perlin-CuPy的新型库的GPU实现开发的。在乳腺头尾位压迫下,使用三维模型模拟乳房解剖结构。总共创建了240个体模,其压缩乳房厚度、胸壁到乳头距离和皮肤厚度分别在{[35, 75], [59, 130), [1.0, 2.0]}毫米区间内变化。使用我们DBT原型的两种采集几何结构模拟体模的DBT投影和重建。使用柏林噪声体模的乳房体积分割比较了两种采集几何结构的性能。结果表明,在DBT采集中引入X射线源的前后运动可改善乳房体积估计。在DBT中乳房体积被高估,随采集几何结构有很大变化;对于更厚更大的乳房,分割误差更明显。这些结果提供了更多证据,并表明定制采集几何结构可以提高DBT的性能和准确性。柏林噪声体模有助于识别采集几何结构的局限性,并优化DBT原型的性能。

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