Advanced mathematical modeling for preciseestimation of CT energy spectrum using a calibration phantom

IF 3.3 3区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Physica Medica-European Journal of Medical Physics Pub Date : 2024-09-26 DOI:10.1016/j.ejmp.2024.104819

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Abstract

Purpose

This research aims to develop an advanced mathematical model using a CT calibration phantom to accurately estimate the CT energy spectrum in clinical settings, enhancing imaging quality and patient dose management.

Methods

Data were collected from a CT scanner using a CT calibration phantom at various energy levels (80, 100, 120, and 135 kVp). The data was optimized to refine the energy spectrum model, followed by cross-validation with Monte Carlo simulations.

Results

The developed model demonstrated high precision in estimating the CT energy spectrum at all tested energy levels, with R-squared values above 0.9738 and an R-squared value of 0.9829 at 100 kVp. The model also showed low Normalized Root Mean Square Deviation (NRMSD) ranging from 0.6698 % to 1.8745 %. The Mean Energy Difference (ΔE) between the estimated and simulated spectrum consistently remained under 0.01 keV. These results were comparable to recent studies, which reported higher NRMSD and ΔE.

Conclusions

This study presents a significantly improved model for estimating the CT energy spectrum, offering greater accuracy than existing models. Its strengths include high precision and the use of standard equipment and algorithmic values. While the current use of 13 plugs is adequate, incorporating plugs with varied densities could enhance accuracy. This model has potential for improving imaging quality and optimizing patient dosing in clinical applications. Future trends may include extending energy spectrum estimation to megavoltage domains and integrating technologies like EPID and MVCT for better dose distribution prediction in high-energy photon beam therapy.

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利用校准模型精确估算 CT 能谱的高级数学模型

目的本研究旨在利用 CT 校准模型开发一种先进的数学模型，以准确估计临床环境中的 CT 能量谱，从而提高成像质量和患者剂量管理水平。结果所开发的模型在所有测试能级下都能高精度地估计 CT 能谱，R 方值超过 0.9738，在 100 kVp 时 R 方值为 0.9829。该模型还显示出较低的归一化均方根偏差（NRMSD），从 0.6698 % 到 1.8745 % 不等。估计光谱和模拟光谱之间的平均能量差（ΔE）始终保持在 0.01 千伏以下。这些结果与最近的研究结果相当，后者报告了更高的 NRMSD 和 ΔE。它的优点包括精度高、使用标准设备和算法值。虽然目前使用 13 个塞子已经足够，但加入不同密度的塞子可以提高精确度。该模型具有提高成像质量和优化临床应用中患者剂量的潜力。未来的趋势可能包括将能谱估算扩展到兆伏域，并整合 EPID 和 MVCT 等技术，以更好地预测高能光子束治疗中的剂量分布。

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

Physica Medica-European Journal of Medical Physics 生物-生物物理

CiteScore

6.80

自引率

14.70%

发文量

493

审稿时长

78 days

期刊介绍： Physica Medica, European Journal of Medical Physics, publishing with Elsevier from 2007, provides an international forum for research and reviews on the following main topics: Medical Imaging Radiation Therapy Radiation Protection Measuring Systems and Signal Processing Education and training in Medical Physics Professional issues in Medical Physics.