光谱亨氏单位：一个新的放射学概念。

Spectral Hounsfield units: a new radiological concept.

机构信息

Department of Radiology, University of Otago, Christchurch 8140, New Zealand.

出版信息

Eur Radiol. 2012 May;22(5):1008-13. doi: 10.1007/s00330-011-2348-3. Epub 2011 Dec 2.

DOI:10.1007/s00330-011-2348-3

PMID:22134894

Abstract

OBJECTIVE

Computed tomography (CT) uses radiographical density to depict different materials; although different elements have different absorption fingerprints across the range of diagnostic X-ray energies, this spectral absorption information is lost in conventional CT. The recent development of dual energy CT (DECT) allows extraction of this information to a useful but limited extent. However, the advent of new photon counting chips that have energy resolution capabilities has put multi-energy or spectral CT (SCT) on the clinical horizon.

METHODS

This paper uses a prototype SCT system to demonstrate how CT density measurements vary with kilovoltage.

RESULTS

While radiologists learn about linear attenuation curves during radiology training, they do not usually need a detailed understanding of this phenomenon in their clinical practice. However SCT requires a paradigm shift in how radiologists think about CT density.

CONCLUSION

Because radiologists are already familiar with the Hounsfield Unit (HU), it is proposed that a modified HU be used that includes the mean energy used to obtain the image, as a conceptual bridge between conventional CT and SCT. A suggested format would be: HU(keV).

KEY POINTS

• Spectral computed tomography uses K-edge and slope effects to identify element signatures. • New visualisation tools will be required to efficiently display spectral CT information. • This paper demonstrates HU variation with keV using the Medipix3 chip. • HU ( keV ) is a suggested format when stating spectral HU measurements.

摘要

目的

计算机断层扫描（CT）利用射线密度来描绘不同的物质；尽管不同的元素在诊断 X 射线能量范围内具有不同的吸收特征，但这种光谱吸收信息在常规 CT 中丢失了。最近双能 CT（DECT）的发展允许在一定程度上提取此信息。然而，具有能量分辨率能力的新型光子计数芯片的出现使多能量或光谱 CT（SCT）成为临床现实。

方法

本文使用原型 SCT 系统演示了 CT 密度测量如何随千伏变化而变化。

结果

虽然放射科医生在放射科培训期间了解线性衰减曲线，但他们在临床实践中通常不需要详细了解这一现象。然而，SCT 需要放射科医生在思考 CT 密度方面发生范式转变。

结论

由于放射科医生已经熟悉亨氏单位（HU），因此建议使用包含获得图像所用平均能量的修改后的 HU，作为常规 CT 和 SCT 之间的概念桥梁。建议的格式为：HU（keV）。

关键点

光谱计算机断层扫描利用 K 边和斜率效应来识别元素特征。
需要新的可视化工具来有效地显示光谱 CT 信息。
本文使用 Medipix3 芯片演示了 HU 随 keV 的变化。
在描述光谱 HU 测量值时，建议使用 HU（keV）格式。

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光谱亨氏单位：一个新的放射学概念。

Spectral Hounsfield units: a new radiological concept.

机构信息

出版信息

OBJECTIVE

METHODS

RESULTS

CONCLUSION

KEY POINTS

目的

方法

结果

结论

关键点

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