Accuracy of CT numbers and electron density calibration for mixtures of materials with low and high-atomic number

Q4 Engineering
Zehra Ese, Daniel Erni, Waldemar Zylka
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Abstract

Abstract In computed tomography (CT) materials with high-atomic number Z cause image artefacts, thus, errors in CT numbers given in Hounsfield Units (HU). Also, the conventional HU scale (CHU) implemented in CT scanners is truncated, i.e., it does not cover high-Z materials. These restrictions lead to incorrect mapping of CT numbers to electron density, which are used in radiotherapy (RT) treatment planning systems (TPS). Even analytical conversion methods are only permissible for tissue-equivalent materials. In terms of HU-to-density conversion in RT TPS, we investigated the CT numbers of material mixtures up to Z<29 at the CHU and an extended-HU (EHU) scale, respectively, and quantify the systematic errors of image artefacts. In [1] the feasibility of a stoichiometric analytical calibration method were analyzed for metals and adapted for higher accurcy, for energies of 80 kV and 120 kV. In this work, we add results for 100 kV and 140 kV to cover the wide diagnostic range. The CT numbers are effected by physical and machine-based properties and depend strongly on the energy, e.g., for Cu a HU difference of 6 171HU at 80 kV and 140 kV occured. The analytical calibration parameters change with energy by a factor between 2 and 10 depending on the physical process. Although for high- Z materials our calibration procedure remains in conflict with rigorous physics [2], it offers an improved and a practical way to predict electron densities from CT numbers.
低原子序数和高原子序数混合材料CT数和电子密度校准的准确性
在计算机断层扫描(CT)中,具有高原子序数Z的材料会引起图像伪影,因此,在Hounsfield单位(HU)中给出的CT数会出现错误。此外,CT扫描仪中实现的传统HU尺度(CHU)被截断,即它不覆盖高z材料。这些限制导致在放疗(RT)治疗计划系统(TPS)中使用的CT数与电子密度的不正确映射。即使是分析转换方法也只允许用于组织等效材料。在RT TPS中的HU-to-density转换方面,我们分别研究了在CHU和扩展hu (EHU)尺度下高达Z<29的材料混合物的CT数,并量化了图像伪像的系统误差。在[1]中,分析了一种化学计量分析校准方法对金属的可行性,并适应于更高的精度,能量为80千伏和120千伏。在这项工作中,我们增加了100千伏和140千伏的结果,以覆盖较宽的诊断范围。电流互感器数受物理性质和机械性质的影响,并强烈依赖于能量,例如,对于Cu,在80 kV和140 kV时出现了6 171HU的差异。根据物理过程的不同,分析校准参数随能量变化的系数在2到10之间。尽管对于高Z材料,我们的校准程序仍然与严格的物理学相冲突[2],但它提供了一种改进的、实用的方法,可以从CT数预测电子密度。
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
Current Directions in Biomedical Engineering
Current Directions in Biomedical Engineering Engineering-Biomedical Engineering
CiteScore
0.90
自引率
0.00%
发文量
239
审稿时长
14 weeks
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