超高分辨率光谱光子计数CT在肺部成像方面优于双层CT：体模研究结果

Ultra-high resolution spectral photon-counting CT outperforms dual layer CT for lung imaging: Results of a phantom study.

作者信息

Lacombe Hugo, Labour Joey, de Oliveira Fabien, Robert Antoine, Houmeau Angèle, Villien Marjorie, Boccalini Sara, Beregi Jean-Paul, Douek Philippe C, Greffier Joël, Si-Mohamed Salim A

机构信息

Université de Lyon, INSA-Lyon, Université Claude Bernard Lyon 1, UJM-Saint Etienne, CNRS, INSERM, CREATIS UMR 5220, U1206, 69100 Villeurbanne, France; CT Clinical Science, Philips, 92150, Suresnes, France.

Université de Lyon, INSA-Lyon, Université Claude Bernard Lyon 1, UJM-Saint Etienne, CNRS, INSERM, CREATIS UMR 5220, U1206, 69100 Villeurbanne, France.

出版信息

Diagn Interv Imaging. 2025 Feb;106(2):60-67. doi: 10.1016/j.diii.2024.09.011. Epub 2024 Oct 2.

DOI:10.1016/j.diii.2024.09.011

PMID:39358155

Abstract

PURPOSE

The purpose of this study was to compare lung image quality obtained with ultra-high resolution (UHR) spectral photon-counting CT (SPCCT) with that of dual-layer CT (DLCT), at standard and low dose levels using an image quality phantom and an anthropomorphic lung phantom.

METHODS

An image quality phantom was scanned using a clinical SPCCT prototype and an 8 cm collimation DLCT from the same manufacturer at 10 mGy. Additional acquisitions at 6 mGy were performed with SPCCT only. Images were reconstructed with dedicated high-frequency reconstruction kernels, slice thickness between 0.58 and 0.67 mm, and matrix between 512 and 1024 mm, using a hybrid iterative algorithm at level 6. Noise power spectrum (NPS), task-based transfer function (TTF) for iodine and air inserts, and detectability index (d') were assessed for ground-glass and solid nodules of 2 mm to simulate highly detailed lung lesions. Subjective analysis of an anthropomorphic lung phantom was performed by two radiologists using a five-point quality score.

RESULTS

At 10 mGy, noise magnitude was reduced by 29.1 % with SPCCT images compared to DLCT images for all parameters (27.1 ± 11.0 [standard deviation (SD)] HU vs. 38.2 ± 1.0 [SD] HU, respectively). At 6 mGy with SPCCT images, noise magnitude was reduced by 8.9 % compared to DLCT images at 10 mGy (34.8 ± 14.1 [SD] HU vs. 38.2 ± 1.0 [SD] HU, respectively). At 10 mGy and 6 mGy, average NPS spatial frequency (f) was greater for SPCCT images (0.75 ± 0.17 [SD] mm) compared to DLCT images at 10 mGy (0.55 ± 0.04 [SD] mm) while remaining constant from 10 to 6 mGy. At 10 mGy, TTF at 50 % (f) was greater for SPCCT images (0.92 ± 0.08 [SD] mm) compared to DLCT images (0.67 ± 0.06 [SD] mm) for both inserts. At 6 mGy, f decreased by 1.1 % for SPCCT images, while remaining greater compared to DLCT images at 10 mGy (0.91 ± 0.06 [SD] mm vs. 0.67 ± 0.06 [SD] mm, respectively). At both dose levels, d' were greater for SPCCT images compared to DLCT for all clinical tasks. Subjective analysis performed by two radiologists revealed a greater median image quality for SPCCT (5; Q1, 4; Q3, 5) compared to DLCT images (3; Q1, 3; Q3, 3).

CONCLUSION

UHR SPCCT outperforms DLCT in terms of image quality for lung imaging. In addition, UHR SPCCT contributes to a 40 % reduction in radiation dose compared to DLCT.

摘要

目的

本研究旨在使用图像质量模体和拟人化肺部模体，在标准剂量和低剂量水平下，比较超高分辨率（UHR）光谱光子计数CT（SPCCT）与双层CT（DLCT）所获得的肺部图像质量。

方法

使用临床SPCCT原型和同一制造商的8 cm准直DLCT在10 mGy下扫描图像质量模体。仅使用SPCCT在6 mGy下进行额外采集。使用专用的高频重建内核、0.58至0.67 mm之间的层厚以及512至1024 mm之间的矩阵，采用6级混合迭代算法重建图像。评估噪声功率谱（NPS）、碘和空气插入物的基于任务的传递函数（TTF）以及检测指数（d'），以模拟2 mm的磨玻璃和实性结节，从而评估高度详细的肺部病变。两名放射科医生使用五点质量评分对拟人化肺部模体进行主观分析。

结果

在10 mGy时，对于所有参数，SPCCT图像的噪声幅度比DLCT图像降低了29.1%（分别为27.1±11.0[标准差（SD）]HU和38.2±1.0[SD]HU）。在SPCCT图像6 mGy时，与10 mGy的DLCT图像相比，噪声幅度降低了8.9%（分别为34.8±14.1[SD]HU和38.2±1.0[SD]HU）。在10 mGy和6 mGy时，SPCCT图像的平均NPS空间频率（f）（0.75±0.17[SD]mm）高于10 mGy的DLCT图像（0.55±0.04[SD]mm），并且从10 mGy到6 mGy保持不变。在10 mGy时，对于两种插入物，SPCCT图像在50%（f）处的TTF（0.92±0.08[SD]mm）高于DLCT图像（0.67±0.06[SD]mm）。在6 mGy时，SPCCT图像的f下降了1.1%，但仍高于10 mGy的DLCT图像（分别为0.91±0.06[SD]mm和0.67±0.06[SD]mm）。在两个剂量水平下，对于所有临床任务，SPCCT图像的d'均高于DLCT。两名放射科医生进行的主观分析显示，SPCCT的中位图像质量（5；第一四分位数，4；第三四分位数，5）高于DLCT图像（3；第一四分位数，3；第三四分位数，3）。