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原型深度硅光子计数和能量积分探测器CT碘定量准确性的比较。

Comparison of iodine quantification accuracy on prototype deep silicon photon-counting and energy-integrating detector CT.

作者信息

Salyapongse Aria, Shapiro Teva, Yin Zhye, Slavic Scott, Toia Giuseppe, Lubner Meghan, Szczykutowicz Timothy

机构信息

University of Wisconsin-Madison, Madison, USA.

GE HealthCare, Waukesha, USA.

出版信息

Abdom Radiol (NY). 2025 Jul 28. doi: 10.1007/s00261-025-05098-1.

DOI:10.1007/s00261-025-05098-1
PMID:40719927
Abstract

PURPOSE

This work examined the iodine quantification accuracy on a prototype deep silicon (dSi) photon-counting detector (PCD) computed tomography (CT) system compared to a rapid kV switching energy-integrating detector (EID) dual-energy (DE) CT system.

METHODS

Iodine-containing rods (0-20 mg I/mL) in a phantom (Gammex MECT) were scanned with the prototype dSi PCD and DECT systems. Iodine (water) material density images were made with prototype and commercially available material decomposition algorithms, respectively. Circular regions of interest were placed over the center of the iodine rods to measure iodine accuracy in each slice, and slices were averaged. A correction based on the known issue of background material difference from true water was determined from the 0 mg I/mL (solid water) rod and the relative rod densities and was applied to the iodine quantification. Iodine percent error was defined as the difference between corrected iodine quantification and known iodine quantification, divided by the known iodine, multiplied by 100.

RESULTS

The corrected iodine quantification was within 0.15 mg I/mL for 0-20 mg I/mL iodine rods on the prototype PCD CT and 0.2 mg I/mL for the EID DECT. This translates to iodine percent errors of 0.4-4.3% on the PCD CT and 1.1-76% on the EID DECT for 0.2-20 mg I/mL rods.

CONCLUSION

Iodine quantification on the prototype dSi PCD CT was within 4.3% for all tested iodine-containing rods, which is similar or better than the performance of the EID DECT system and previous work on the prototype dSi system.

摘要

目的

本研究比较了一款原型深硅(dSi)光子计数探测器(PCD)计算机断层扫描(CT)系统与一款快速千伏切换能量积分探测器(EID)双能(DE)CT系统的碘定量准确性。

方法

使用原型dSi PCD和DECT系统对体模(Gammex MECT)中的含碘棒(0 - 20 mg I/mL)进行扫描。分别使用原型和商用材料分解算法生成碘(水)物质密度图像。在碘棒中心放置圆形感兴趣区域,以测量每个切片中的碘准确性,并对切片进行平均。根据0 mg I/mL(固体水)棒以及相对棒密度确定基于背景材料与真实水差异这一已知问题的校正,并将其应用于碘定量。碘百分比误差定义为校正后的碘定量与已知碘定量之间的差值,除以已知碘,再乘以100。

结果

对于原型PCD CT上0 - 20 mg I/mL的碘棒,校正后的碘定量在0.15 mg I/mL以内;对于EID DECT,校正后的碘定量在0.2 mg I/mL以内。这意味着对于0.2 - 20 mg I/mL的棒,PCD CT上的碘百分比误差为0.4 - 4.3%,EID DECT上的碘百分比误差为1.1 - 76%。

结论

对于所有测试的含碘棒,原型dSi PCD CT的碘定量误差在4.3%以内,这与EID DECT系统的性能以及之前在原型dSi系统上的工作相似或更好。

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