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基于深度学习的超高分辨率计算机断层扫描重建:能否改善由高清探测器和矩阵元素尺寸微型化引起的图像噪声?

Deep learning-based reconstruction in ultra-high-resolution computed tomography: Can image noise caused by high definition detector and the miniaturization of matrix element size be improved?

机构信息

Division of Diagnostic Radiology, Shizuoka Cancer Center 1007 Shimonagakubo, Nagaizumi, Sunto, Shizuoka 411-8777, Japan.

Vocational School Toyo Public Health Academy, 6-21-7 Honmachi, Shibuya-ku, Tokyo 151-0071, Japan.

出版信息

Phys Med. 2021 Jan;81:121-129. doi: 10.1016/j.ejmp.2020.12.006. Epub 2021 Jan 13.

DOI:10.1016/j.ejmp.2020.12.006
PMID:33453504
Abstract

PURPOSE

This study aimed to assess the noise characteristics of ultra-high-resolution computed tomography (UHRCT) with deep learning-based reconstruction (DLR).

METHODS

Two different diameters of water phantom were scanned with three different resolution acquisition modes. Images were reconstructed by filtered back projection (FBP), hybrid iterative reconstruction (hybrid-IR), and DLR. Image noise analysis was performed with noise magnitude, peak frequency (f) of the noise power spectrum (NPS), and the square root of the area under the curve (√AUC) for the NPS curve.

RESULTS

The noise magnitude was up to 3.30 times higher for the FBP acquired in SHR mode than that for the NR mode. The f values of the FBP were 0.20-0.21, 0.34-0.36, and 0.34-0.37 cycles/mm for normal resolution (NR), high resolution (HR), and super high resolution (SHR) mode, respectively. The f of hybrid-IR was 0.16-0.19, 0.21-0.26, and 0.23-0.26 cycles/mm for NR, HR, and SHR mode, respectively. The f of DLR was 0.21-0.32 and 0.22-0.33 cycles/mm for HR and SHR mode, respectively. √AUC showed that the highest value in FBP images of the SHR mode was up to 1.89 times that of the NR mode. DLR in the HR and SHR modes showed high noise reduction while suppressing f shift with respect to FBP.

CONCLUSIONS

The new DLR algorithm could be a solution to the noise increase due to the high-definition detector elements and the small reconstruction matrix element size.

摘要

目的

本研究旨在评估基于深度学习重建(DLR)的超高分辨率计算机断层扫描(UHRCT)的噪声特性。

方法

使用三种不同的分辨率采集模式对两个不同直径的水模体进行扫描。使用滤波反投影(FBP)、混合迭代重建(hybrid-IR)和 DLR 对图像进行重建。通过噪声幅度、噪声功率谱(NPS)的峰值频率(f)和 NPS 曲线下的面积平方根(√AUC)对图像噪声进行分析。

结果

SHR 模式采集的 FBP 的噪声幅度最高可达 NR 模式的 3.30 倍。FBP 的 f 值分别为 0.20-0.21、0.34-0.36 和 0.34-0.37 个周期/mm,用于正常分辨率(NR)、高分辨率(HR)和超高分辨率(SHR)模式。HR 和 SHR 模式下 hybrid-IR 的 f 值分别为 0.16-0.19、0.21-0.26 和 0.23-0.26 个周期/mm。HR 和 SHR 模式下 DLR 的 f 值分别为 0.21-0.32 和 0.22-0.33 个周期/mm。√AUC 表明,SHR 模式下 FBP 图像的最高值可达 NR 模式的 1.89 倍。HR 和 SHR 模式下的 DLR 可在抑制 f 移位的同时降低噪声,与 FBP 相比。

结论

新的 DLR 算法可以解决由于高清探测器元件和小重建矩阵元素尺寸导致的噪声增加问题。

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