Comparison of a 3D CZT and conventional SPECT/CT system for quantitative Lu-177 SPECT imaging.

IF 3 2区 医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING EJNMMI Physics Pub Date : 2024-03-19 DOI:10.1186/s40658-024-00627-1
Victor Nuttens, Georg Schramm, Yves D'Asseler, Michel Koole
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Abstract

Purpose: Next-generation SPECT/CT systems with CdZnTe (CZT) digital detectors in a ring-like setup are emerging to perform quantitative Lu-177 SPECT imaging in clinical routine. It is essential to assess how the shorter acquisition time might affect the image quality and uncertainty on the mean absorbed dose of the tumors and organs at risk compared to a conventional system.

Methods: A NEMA Image Quality phantom was scanned with a 3D CZT SPECT/CT system (Veriton, by Spectrum Dynamics) using 6 min per bed position and with a conventional SPECT/CT system (Symbia T16, by Siemens) using 16 min per bed position. The sphere-to-background ratio was 12:1 and the background activity concentration ranged from 0.52 to 0.06 MBq/mL. A clinical reconstruction protocol for dosimetry purposes was determined for both systems by maximizing the sphere-to-background ratio while keeping the coefficient of variation of the background as low as possible. The corresponding image resolution was determined by the matching filter method and used for a dose uncertainty assessment of both systems following an established uncertainty model..

Results: The optimized iterative reconstruction protocol included scatter and attenuation correction for both systems and detector response modeling for the Siemens system. For the 3D CZT system, 6 iterations and 8 subsets were combined with a Gaussian post-filter of 3 mm Full Width Half Maximum (FWHM) for post-smoothing. For the conventional system, 16 iterations and 16 subsets were applied with a Gaussian post-smoothing filter of 1 mm FWHM. For these protocols, the sphere-to-background ratio was 18.5% closer to the true ratio for the conventional system compared to the 3D CZT system when considering the four largest spheres. Meanwhile, the background coefficient of variation was very similar for both systems. These protocols resulted in SPECT image resolution of 14.8 mm and 13.6 mm for the 3D CZT and conventional system respectively. Based on these resolution estimates, a 50% dose uncertainty corresponded to a lesion volume of 28 mL for the conventional system and a lesion volume of 33 mL for the 3D CZT system.

Conclusions: An optimized reconstruction protocol for a Veriton system with 6 min of acquisition time per bed position resulted in slightly higher dose uncertainties than a conventional Symbia system using 16 min of acquisition time per bed position. Therefore, a 3D CZT SPECT/CT allows to significantly reduce the acquisition times with only a very limited impact on dose uncertainties such that quantitative Lu-177 SPECT/CT imaging becomes much more accessible for treatment concurrent dosimetry. Nevertheless, the uncertainty of SPECT-based dose estimates remains high.

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用于定量 Lu-177 SPECT 成像的 3D CZT 和传统 SPECT/CT 系统的比较。
目的:新一代SPECT/CT系统在环状设置中配备了碲镉(CZT)数字探测器,可在临床常规工作中进行定量Lu-177 SPECT成像。与传统系统相比,有必要评估较短的采集时间会如何影响图像质量以及肿瘤和危险器官平均吸收剂量的不确定性:使用三维 CZT SPECT/CT 系统(Veriton,Spectrum Dynamics 公司生产)扫描了一个 NEMA 图像质量模型,每个床位 6 分钟;使用传统 SPECT/CT 系统(Symbia T16,西门子公司生产)扫描了一个 NEMA 图像质量模型,每个床位 16 分钟。球-背景比为 12:1,背景活性浓度范围为 0.52 至 0.06 MBq/mL。通过最大限度地提高球-背景比,同时保持尽可能低的背景变异系数,为两种系统确定了用于剂量测定的临床重建方案。通过匹配滤波法确定了相应的图像分辨率,并按照既定的不确定性模型对两种系统进行了剂量不确定性评估:优化的迭代重建方案包括对两种系统进行散射和衰减校正,以及对西门子系统进行探测器响应建模。对于三维 CZT 系统,6 次迭代和 8 个子集与 3 毫米半最大全宽(FWHM)的高斯后滤波器相结合进行后平滑。对于传统系统,则采用 16 次迭代和 16 个子集,并使用 1 毫米全宽半最大值的高斯后平滑滤波器。在这些方案中,当考虑到四个最大的球体时,传统系统的球体与背景比率比 3D CZT 系统更接近真实比率的 18.5%。同时,两种系统的背景变异系数非常相似。通过这些方案,三维 CZT 和传统系统的 SPECT 图像分辨率分别为 14.8 毫米和 13.6 毫米。根据这些分辨率估算,50%剂量不确定性对应的病变体积为:传统系统 28 mL,3D CZT 系统 33 mL:Veriton系统的优化重建方案每个床位采集时间为6分钟,其剂量不确定性略高于传统的Symbia系统(每个床位采集时间为16分钟)。因此,三维 CZT SPECT/CT 可以显著缩短采集时间,但对剂量不确定性的影响非常有限,从而使定量 Lu-177 SPECT/CT 成像更容易用于治疗同时剂量测定。尽管如此,基于 SPECT 的剂量估计的不确定性仍然很高。
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来源期刊
EJNMMI Physics
EJNMMI Physics Physics and Astronomy-Radiation
CiteScore
6.70
自引率
10.00%
发文量
78
审稿时长
13 weeks
期刊介绍: EJNMMI Physics is an international platform for scientists, users and adopters of nuclear medicine with a particular interest in physics matters. As a companion journal to the European Journal of Nuclear Medicine and Molecular Imaging, this journal has a multi-disciplinary approach and welcomes original materials and studies with a focus on applied physics and mathematics as well as imaging systems engineering and prototyping in nuclear medicine. This includes physics-driven approaches or algorithms supported by physics that foster early clinical adoption of nuclear medicine imaging and therapy.
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