Voxelwise characterization of noise for a clinical photon-counting CT scanner with a model-based iterative reconstruction algorithm.

IF 3.7 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

European Radiology Experimental Pub Date : 2025-01-02 DOI:10.1186/s41747-024-00541-2

Luigi Masturzo, Patrizio Barca, Luca De Masi, Daniela Marfisi, Antonio Traino, Filippo Cademartiri, Marco Giannelli

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Abstract

Background: Photon-counting detector (PCD) technology has the potential to reduce noise in computed tomography (CT). This study aimed to carry out a voxelwise noise characterization for a clinical PCD-CT scanner with a model-based iterative reconstruction algorithm (QIR).

Methods: Forty repeated axial acquisitions (tube voltage 120 kV, tube load 200 mAs, slice thickness 0.4 mm) of a homogeneous water phantom and CTP404 module (Catphan-504) were performed. Water phantom acquisitions were also performed on a conventional energy-integrating detector (EID) scanner with a sinogram/image-based iterative reconstruction algorithm, using similar acquisition/reconstruction parameters. For smooth/sharp kernels, filtered back projection (FBP)- and iterative-reconstructed images were obtained. Noise maps, non-uniformity index (NUI) of noise maps, image noise histograms, and noise power spectrum (NPS) curves were computed.

Results: For FBP-reconstructed images of water phantom, mean noise was (smooth/sharp kernel) 11.7 HU/51.1 HU and 18.3 HU/80.1 HU for PCD-scanner and EID-scanner, respectively, with NUI values for PCD-scanner less than half those for EID-scanner. Percentage noise reduction increased with increasing iterative power, up to (smooth/sharp kernel) 57.7%/72.5% and 56.3%/70.1% for PCD-scanner and EID-scanner, respectively. For PCD-scanner, FBP- and QIR-reconstructed images featured an almost Gaussian distribution of noise values, whose shape did not appreciably vary with iterative power. Noise maps of CTP404 module showed increased NUI values with increasing iterative power, up to (smooth/sharp kernel) 15.7%/9.2%. QIR-reconstructed images showed limited low-frequency shift of NPS peak frequency.

Conclusion: PCD-CT allowed appreciably reducing image noise while improving its spatial uniformity. QIR algorithm decreases image noise without modifying its histogram distribution shape, and partly preserving noise texture.

Relevance statement: This phantom study corroborates the capability of photon-counting detector technology in appreciably reducing CT imaging noise and improving spatial uniformity of noise values, yielding a potential reduction of radiation exposure, though this needs to be assessed in more detail.

Key points: First voxelwise characterization of noise for a clinical CT scanner with photon-counting detector technology. Photon-counting detector technology has the capability to appreciably reduce CT imaging noise and improve spatial uniformity of noise values. In photon-counting CT, a model-based iterative reconstruction algorithm (QIR) allows decreasing effectively image noise. This is done without modifying noise histogram distribution shape, while limiting the low-frequency shift of noise power spectrum peak frequency.

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基于模型迭代重建算法的临床光子计数CT扫描仪噪声体素表征。

背景：光子计数检测器（PCD）技术具有降低计算机断层扫描（CT）噪声的潜力。本研究旨在利用基于模型的迭代重建算法（QIR）对临床PCD-CT扫描仪进行体向噪声表征。方法：对均匀水影和CTP404模块（Catphan-504）进行40次重复轴向采集（管电压120 kV，管负载200 mAs，片厚0.4 mm）。采用类似的采集/重建参数，采用基于正弦图/图像的迭代重建算法，在传统的能量积分检测器（EID）扫描仪上进行水影采集。对于光滑/锐利的核，得到滤波后的反投影（FBP）和迭代重建图像。计算噪声图、噪声图的非均匀性指数（NUI）、图像噪声直方图和噪声功率谱（NPS）曲线。结果：对于fbp重建的水影图像，pcd -扫描仪和eid -扫描仪的平均噪声分别为11.7 HU/51.1 HU和18.3 HU/80.1 HU，其中pcd -扫描仪的NUI值不到eid -扫描仪的一半。随着迭代功率的增加，降噪率增加，cd -scanner和EID-scanner分别达到（平滑/锐核）57.7%/72.5%和56.3%/70.1%。对于pcd扫描仪，FBP和qir重建图像的噪声值几乎呈高斯分布，其形状随迭代次数的变化不明显。CTP404模块的噪声图显示，NUI值随迭代功率的增加而增加，分别达到（平滑核/锐核）15.7%/9.2%。qir重建图像显示NPS峰值频率低频偏移有限。结论：PCD-CT在明显降低图像噪声的同时，提高了图像的空间均匀性。QIR算法在不改变图像直方图分布形状的情况下降低了图像噪声，并在一定程度上保留了噪声纹理。相关声明：这项幻影研究证实了光子计数检测器技术在显著降低CT成像噪声和改善噪声值的空间均匀性方面的能力，从而产生了潜在的降低辐射暴露的能力，尽管这需要更详细的评估。重点：首先利用光子计数检测器技术对临床CT扫描仪的噪声进行体素表征。光子计数检测器技术能够显著降低CT成像噪声，提高噪声值的空间均匀性。在光子计数CT中，基于模型的迭代重建算法（QIR）可以有效地降低图像噪声。这在不改变噪声直方图分布形状的情况下实现，同时限制了噪声功率谱峰值频率的低频偏移。

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