Simulating and correcting the pileup effect in deep-silicon photon-counting CT

IF 3.2 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Medical physics Pub Date : 2025-09-03 DOI:10.1002/mp.18075

Erik Fredenberg, Daniel Collin, Louis Carbonne, Mingye Wu, Bruno De Man, Fredrik Grönberg

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Abstract

Background

Photon-counting computed tomography (CT) bears promise to substantially improve spectral and spatial resolution. One reason for the relatively slow evolution of photon-counting detectors in CT—the technology has been used in nuclear medicine and planar radiology for decades—is pulse pileup, that is, the random staggering of pulses, resulting in count loss and spectral distortion, which in turn cause image bias and reduced contrast-to-noise ratio (CNR). The deterministic effects of pileup can be mitigated with a pileup-correction algorithm, but the loss of CNR cannot be recovered, and must be minimized by hardware design. In the deep-silicon photon-counting detector, each pixel is split into depth segments, which enables optimization of the count rate per detector channel to reduce pileup. Virtual clinical trials are attracting growing interest for efficient evaluation of cutting-edge technology like the deep-silicon design, but a virtual trial requires an accurate simulation model of the imaging system, a digital twin, which captures all relevant aspects of the system over the full spectrum of clinical applications.

Purpose

We are developing a framework for digital twins of deep-silicon photon-counting CT to enable in-silico system evaluation and virtual clinical trials of the technology. The primary purpose of this study is to validate the framework with respect to pileup, that is, it is not a validation of the detector performance, but a validation of the correspondence between simulation and measurements from a prototype device. A secondary purpose is to employ the framework for investigating the impact of pileup on image quality and the effectiveness of a data-driven pileup correction algorithm.

Methods

A pileup model that simulates individual photon events in accordance with the semi-nonparalyzable detector behavior was integrated into the CatSim environment. Measured count data from a prototype deep-silicon system were used to validate the simulation framework with respect to pileup. A typical image chain was integrated into the framework, including material decomposition (MD) and data-driven pileup correction. Images of a software phantom were generated to illustrate the effect of pileup on images and to assess the effectiveness of the pileup correction algorithm.

Results

Simulated data were described well by the semi-nonparalyzable detector model and exhibited deviations to the measured count rate and variance of less than 5% across energy bins and depth segments, and a wide range of tube currents. The investigated pileup correction algorithm suppressed artifacts to below the noise level in monochromatic images and material images, and reduced iodine bias from 26% to 2% in the range from a factor of 3 lower to a factor of 1.7 higher than the calibrated count rate without impacting CNR.

Conclusions

The observed discrepancies are reasonable given known uncertainties, and the model provides a reliable representation of the pileup effect. The framework for digital twins helped confirm adequate performance of the pileup correction algorithm, which can reduce the need for repeated MD calibrations in mA-modulated scans. Next steps include simulation speed up and expansion of the framework to other detector effects.

Abstract Image

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深硅光子计数CT中堆积效应的模拟与校正

光子计数计算机断层扫描（CT）有望大幅提高光谱和空间分辨率。ct中光子计数探测器的发展相对缓慢的一个原因是脉冲堆积，即脉冲的随机交错，导致计数损失和光谱畸变，从而导致图像偏差和降低对比噪声比（CNR）。该技术已在核医学和平面放射学中使用了数十年。堆积的确定性效应可以通过堆积校正算法来减轻，但不能恢复CNR的损失，必须通过硬件设计将其最小化。在深硅光子计数探测器中，每个像素被分割成深度段，这使得每个探测器通道的计数率优化，以减少堆积。虚拟临床试验吸引了越来越多的人对像深硅设计这样的尖端技术进行有效评估的兴趣，但虚拟试验需要对成像系统进行精确的模拟模型，即数字孪生体，它可以在临床应用的整个范围内捕获系统的所有相关方面。我们正在开发一个深硅光子计数CT的数字双胞胎框架，以实现该技术的硅内系统评估和虚拟临床试验。本研究的主要目的是验证关于堆积的框架，也就是说，它不是对探测器性能的验证，而是对原型设备的模拟和测量之间的对应关系的验证。第二个目的是利用该框架来研究堆积对图像质量的影响以及数据驱动的堆积校正算法的有效性。方法将模拟单个光子事件的堆垒模型与半非瘫痪检测器行为集成到CatSim环境中。利用原型深硅系统的实测计数数据对仿真框架进行了验证。将典型的图像链集成到框架中，包括材料分解（MD）和数据驱动的堆积校正。为了说明堆积对图像的影响，并评估堆积校正算法的有效性，生成了一个软件幻影图像。结果半非瘫痪检测器模型能够很好地描述模拟数据，并且在能量桶和深度段以及较大的管电流范围内显示出与测量计数率和方差的偏差小于5%。所研究的堆积校正算法在不影响CNR的情况下，将单色图像和材料图像中的伪影抑制到低于噪声水平，并将碘偏差从26%降低到2%，范围从比校准计数率低3倍到高1.7倍。结论在已知不确定性的情况下，观测到的差异是合理的，该模型提供了堆积效应的可靠表征。数字双胞胎的框架有助于确认堆积校正算法的足够性能，这可以减少在ma调制扫描中重复MD校准的需要。接下来的步骤包括模拟加速和扩展框架到其他检测器效果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Medical physics 医学-核医学

CiteScore

6.80

自引率

15.80%

发文量

660

审稿时长

1.7 months

期刊介绍： Medical Physics publishes original, high impact physics, imaging science, and engineering research that advances patient diagnosis and therapy through contributions in 1) Basic science developments with high potential for clinical translation 2) Clinical applications of cutting edge engineering and physics innovations 3) Broadly applicable and innovative clinical physics developments Medical Physics is a journal of global scope and reach. By publishing in Medical Physics your research will reach an international, multidisciplinary audience including practicing medical physicists as well as physics- and engineering based translational scientists. We work closely with authors of promising articles to improve their quality.