Adaptive prior image constrained total generalized variation for low-dose dynamic cerebral perfusion CT reconstruction.

IF 1.7 3区 医学 Q3 INSTRUMENTS & INSTRUMENTATION
Shanzhou Niu, Shuo Li, Shuyan Huang, Lijing Liang, Sizhou Tang, Tinghua Wang, Gaohang Yu, Tianye Niu, Jing Wang, Jianhua Ma
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引用次数: 0

Abstract

Background: Dynamic cerebral perfusion CT (DCPCT) can provide valuable insight into cerebral hemodynamics by visualizing changes in blood within the brain. However, the associated high radiation dose of the standard DCPCT scanning protocol has been a great concern for the patient and radiation physics. Minimizing the x-ray exposure to patients has been a major effort in the DCPCT examination. A simple and cost-effective approach to achieve low-dose DCPCT imaging is to lower the x-ray tube current in data acquisition. However, the image quality of low-dose DCPCT will be degraded because of the excessive quantum noise.

Objective: To obtain high-quality DCPCT images, we present a statistical iterative reconstruction (SIR) algorithm based on penalized weighted least squares (PWLS) using adaptive prior image constrained total generalized variation (APICTGV) regularization (PWLS-APICTGV).

Methods: APICTGV regularization uses the precontrast scanned high-quality CT image as an adaptive structural prior for low-dose PWLS reconstruction. Thus, the image quality of low-dose DCPCT is improved while essential features of targe image are well preserved. An alternating optimization algorithm is developed to solve the cost function of the PWLS-APICTGV reconstruction.

Results: PWLS-APICTGV algorithm was evaluated using a digital brain perfusion phantom and patient data. Compared to other competing algorithms, the PWLS-APICTGV algorithm shows better noise reduction and structural details preservation. Furthermore, the PWLS-APICTGV algorithm can generate more accurate cerebral blood flow (CBF) map than that of other reconstruction methods.

Conclusions: PWLS-APICTGV algorithm can significantly suppress noise while preserving the important features of the reconstructed DCPCT image, thus achieving a great improvement in low-dose DCPCT imaging.

用于低剂量动态脑灌注 CT 重建的自适应先验图像约束总广义变异。
背景:动态脑灌注 CT(DCPCT)可通过观察脑内血液的变化来深入了解脑血流动力学。然而,标准 DCPCT 扫描方案的相关高辐射剂量一直是病人和辐射物理学的一大担忧。最大限度地减少对患者的 X 射线照射一直是 DCPCT 检查的主要工作。实现低剂量 DCPCT 成像的一个简单而经济的方法是降低数据采集时的 X 射线管电流。然而,由于量子噪声过大,低剂量 DCPCT 的图像质量会下降:为了获得高质量的 DCPCT 图像,我们提出了一种基于惩罚性加权最小二乘法(PWLS)的统计迭代重建(SIR)算法,并使用自适应先验图像约束总广义变异(APICTGV)正则化(PWLS-APICTGV):APICTGV 正则化将对比扫描前的高质量 CT 图像作为低剂量 PWLS 重建的自适应结构先验。因此,低剂量 DCPCT 的图像质量得到了改善,同时还很好地保留了图像的基本特征。为了解决 PWLS-APICTGV 重建的成本函数,我们开发了一种交替优化算法:使用数字脑灌注模型和患者数据对 PWLS-APICTGV 算法进行了评估。与其他同类算法相比,PWLS-APICTGV 算法在降噪和结构细节保留方面表现更佳。此外,与其他重建方法相比,PWLS-APICTGV 算法能生成更精确的脑血流(CBF)图:结论:PWLS-APICTGV 算法能显著抑制噪声,同时保留重建 DCPCT 图像的重要特征,从而极大地改进了低剂量 DCPCT 成像。
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来源期刊
CiteScore
4.90
自引率
23.30%
发文量
150
审稿时长
3 months
期刊介绍: Research areas within the scope of the journal include: Interaction of x-rays with matter: x-ray phenomena, biological effects of radiation, radiation safety and optical constants X-ray sources: x-rays from synchrotrons, x-ray lasers, plasmas, and other sources, conventional or unconventional Optical elements: grazing incidence optics, multilayer mirrors, zone plates, gratings, other diffraction optics Optical instruments: interferometers, spectrometers, microscopes, telescopes, microprobes
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