双层光谱探测器 CT 降噪算法虚拟单色光谱图像在肥胖模拟体模中改善图像质量的价值。

Value of virtual monochromatic spectral image of dual-layer spectral detector CT with noise reduction algorithm for image quality improvement in obese simulated body phantom.

机构信息

Department of Radiology, Seoul National University Hospital, Seoul, 03080, South Korea.

Department of Radiology, Seoul National University College of Medicine, 101 Daehangno, Jongno-gu, Seoul, 03080, South Korea.

出版信息

BMC Med Imaging. 2019 Aug 28;19(1):76. doi: 10.1186/s12880-019-0367-8.

DOI:10.1186/s12880-019-0367-8

PMID:31462212

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6714289/

Abstract

BACKGROUND

Dual-layer spectral detector CT (SDCT) may provide several theoretical advantages over pre-existing DECT approaches in terms of adjustment-free sampling number and dose modulation, beam hardening correction, and production spectral images by post-processing. In addition, by adopting noise reduction algorithm, high contrast resolution was expected even in low keV level. We surmised that this improvement would be beneficial to obese people. Therefore, our aim of study is to compare image quality of virtual monochromatic spectral images (VMI) and polychromatic images reconstructed from SDCT with different body size and radiation dose using anthropomorphic liver phantom.

METHODS

One small and one large size of body phantoms, each containing eight (four high- and four low-contrast) simulated focal liver lesions (FLLs) were scanned by SDCT (at 120 kVp) using different Dose Right Indexes (DRIs). VMI were reconstructed from spectral base images from 40 keV to 200 keV. Hybrid iterative reconstruction (iDose) was used for polychromatic image reconstruction. Image noise and contrast to noise ratio (CNR) were compared. Five radiologists independently rated lesion conspicuity, diagnostic acceptability and subjective noise level in every image sets, and determined optimal keV level in VMI.

RESULTS

Compare with conventional polychromatic images, VMI showed superior CNR at low keV level regardless of phantom size at every examined DRIs (Ps < 0.05). As body size increased, VMI had more gradual CNR decrease and noise increase than conventional polychromatic images. For low contrast FLLs in large phantom, lesion conspicuities at low radiation dose levels (DRI 16 and 19) were significantly increased in VMI (Ps < 0.05). Subjective image noise and diagnostic acceptabilities were significantly improved at VMI in both phantom size.

CONCLUSIONS

VMI of dual-layer spectral detector CT with noise reduction algorithm provides improved CNR, noise reduction, and better subjective image quality in imaging of obese simulated liver phantom compared with polychromatic images. This may hold promise for improving detection of liver lesions and improved imaging of obese patients.

摘要

背景

与现有的双能量 CT（DECT）方法相比，双层光谱探测器 CT（SDCT）在无需调整采样数量和剂量调制、进行硬化校正以及通过后处理生成光谱图像方面具有理论优势。此外，通过采用降噪算法，即使在低 keV 水平也有望获得高对比分辨率。我们推测这种改进对肥胖人群有益。因此，我们的研究目的是使用人体肝脏模拟体模比较不同体型和辐射剂量下 SDCT 重建的虚拟单能量光谱图像（VMI）和多光谱图像的图像质量。

方法

使用 SDCT（120 kVp）对包含 8 个（4 个高对比和 4 个低对比模拟肝病灶）模拟肝病灶的小体型和大体型体模进行扫描，每个体模使用不同的剂量调整指数（DRI）。从 40 keV 到 200 keV 的光谱基础图像重建 VMI。采用混合迭代重建（iDose）进行多光谱图像重建。比较图像噪声和对比噪声比（CNR）。5 名放射科医生分别对每个图像组进行病灶显影、诊断可接受性和主观噪声水平的评分，并确定 VMI 的最佳 keV 水平。

结果

与常规多光谱图像相比，VMI 在每个检查的 DRI 下（P < 0.05），无论体型大小，在低 keV 水平均显示出更高的 CNR。随着体型的增加，VMI 的 CNR 下降和噪声增加比常规多光谱图像更渐进。对于大体型中的低对比 FLL，在低辐射剂量水平（DRI 16 和 19），VMI 中病灶的显影显著提高（P < 0.05）。在两种体型的图像中，主观图像噪声和诊断可接受性均显著改善。

结论

具有降噪算法的双层光谱探测器 CT 的 VMI 与多光谱图像相比，可提高肥胖模拟肝脏体模成像的 CNR、降低噪声和改善主观图像质量。这可能有助于提高肝脏病变的检测能力和肥胖患者的成像质量。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/84e2/6714289/314b0f08861a/12880_2019_367_Fig1_HTML.jpg

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双层光谱探测器 CT 降噪算法虚拟单色光谱图像在肥胖模拟体模中改善图像质量的价值。

Value of virtual monochromatic spectral image of dual-layer spectral detector CT with noise reduction algorithm for image quality improvement in obese simulated body phantom.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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