Zhou Wei, Ataei Afrouz, Huo Donglai, Ren Liqiang, Browne Lorna P, Zhou Xin, Weinman Jason P
From the Department of Radiology, University of Colorado, Anschutz Medical Campus, Aurora, CO (W.Z., D.H., L.P.B., J.P.W.); Department of Radiology, University of Texas Southwestern Medical Center, Dallas, TX (A.A., L.R.); Department of Radiology, Children's Hospital Colorado, Aurora, CO (L.P.B., J.P.W.); Department of Bioinformatics and Computational Biology, University of Minnesota, St Paul, MN (X.Z.); and Department of Pathology, University of Colorado, Anschutz Medical Campus, Aurora, CO (X.Z.).
Invest Radiol. 2025 Apr 1;60(4):245-252. doi: 10.1097/RLI.0000000000001119. Epub 2024 Aug 20.
The comprehensive evaluation of kV selection on photon-counting computed tomography (PCCT) has yet to be performed. The aim of the study is to evaluate and determine the optimal kV options for variable pediatric body sizes on the PCCT unit.
In this study, 4 phantoms of variable sizes were utilized to represent abdomens of newborn, 5-year-old, 10-year-old, and adult-sized pediatric patients. One solid water and 4 solid iodine inserts with known concentrations (2, 5, 10, and 15 mg I/mL) were inserted into phantoms. Each phantom setting was scanned on a PCCT system (Siemens Alpha) with 4 kV options (70 and 90 kV under Quantum Mode, 120 and 140 kV under QuantumPlus Mode) and clinical dual-source (3.0 pitch) protocol. For each phantom setting, radiation dose (CTDI vol ) was determined by clinical dose settings and matched for all kV acquisitions. Sixty percent clinical dose images were also acquired. Reconstruction was matched across all acquisitions using Qr40 kernel and QIR level 3. Virtual monoenergetic images (VMIs) between 40 and 80 keV with 10 keV interval were generated on the scanner. Low-energy and high-energy images were reconstructed from each scan and subsequently used to generate an iodine map (IM) using an image-based 2-material decomposition method. Image noise of VMIs from each kV acquisition was calculated and compared between kV options. Absolute percent error (APE) of iodine CT number accuracy in VMIs was calculated and compared. Root mean square error (RMSE) and bias of iodine quantification from IMs were compared across kV options.
At the newborn size and 50 keV VMI, noise is lower at low kV acquisitions (70 kV: 10.5 HU, 90 kV: 10.4 HU), compared with high kV acquisitions (120 kV: 13.8 HU, 140 kV: 13.9 HU). At the newborn size and 70 keV VMI, the image noise from different kV options is comparable (9.4 HU for 70 kV, 8.9 HU for 90 kV, 9.7 HU for 120 kV, 10.2 HU for 140 kV). For APE of VMI, high kV (120 or 140 kV) performed overall better than low kV (70 or 90 kV). At the 5-year-old size, APE of 90 kV (median: 3.6%) is significantly higher ( P < 0.001, Kruskal-Wallis rank sum test with Bonferroni correction) than 140 kV (median: 1.6%). At adult size, APE of 70 kV (median: 18.0%) is significantly higher ( P < 0.0001, Kruskal-Wallis rank sum test with Bonferroni correction) than 120 kV (median: 1.4%) or 140 kV (median: 0.8%). The high kV also demonstrated lower RMSE and bias than the low kV across all controlled conditions. At 10-year-old size, RMSE and bias of 120 kV are 1.4 and 0.2 mg I/mL, whereas those from 70 kV are 1.9 and 0.8 mg I/mL.
The high kV options (120 or 140 kV) on the PCCT unit demonstrated overall better performance than the low kV options (70 or 90 kV), in terms of image quality of VMIs and IMs. Our results recommend the use of high kV for general body imaging on the PCCT.
尚未对光子计数计算机断层扫描(PCCT)中千伏选择进行全面评估。本研究的目的是评估并确定PCCT设备上针对不同小儿体型的最佳千伏选项。
在本研究中,使用4个不同尺寸的体模来代表新生儿、5岁、10岁和成人尺寸小儿患者的腹部。将1个固体水模和4个已知浓度(2、5、10和15 mg I/mL)的固体碘插入物插入体模中。每个体模设置在PCCT系统(西门子Alpha)上进行扫描,采用4种千伏选项(量子模式下70和90 kV,量子增强模式下120和140 kV)以及临床双源(3.0螺距)协议。对于每个体模设置,通过临床剂量设置确定辐射剂量(CTDI vol),并使所有千伏采集的剂量匹配。还采集了60%临床剂量的图像。使用Qr40内核和QIR 3级在所有采集中进行重建匹配。在扫描仪上生成40至80 keV、间隔为10 keV的虚拟单能图像(VMI)。从每次扫描中重建低能量和高能量图像,随后使用基于图像的双材料分解方法生成碘图(IM)。计算并比较每个千伏采集中VMI的图像噪声。计算并比较VMI中碘CT值准确性的绝对百分比误差(APE)。比较不同千伏选项下IM碘定量的均方根误差(RMSE)和偏差。
在新生儿体型和50 keV的VMI下,低千伏采集(70 kV:10.5 HU,90 kV:10.4 HU)的噪声低于高千伏采集(120 kV:13.8 HU,140 kV:13.9 HU)。在新生儿体型和70 keV的VMI下,不同千伏选项的图像噪声相当(70 kV为9.4 HU,90 kV为8.9 HU,120 kV为9.7 HU,140 kV为10.2 HU)。对于VMI的APE,高千伏(120或140 kV)总体表现优于低千伏(70或90 kV)。在5岁体型时,90 kV的APE(中位数:3.6%)显著高于140 kV(中位数:1.6%)(P < 0.001,经Bonferroni校正的Kruskal-Wallis秩和检验)。在成人体型时,70 kV的APE(中位数:18.0%)显著高于120 kV(中位数:1.4%)或140 kV(中位数:0.8%)(P < 0.0001,经Bonferroni校正的Kruskal-Wallis秩和检验)。在所有控制条件下,高千伏的RMSE和偏差也低于低千伏。在10岁体型时,120 kV的RMSE和偏差分别为1.4和0.2 mg I/mL,而70 kV的分别为1.9和0.8 mg I/mL。
就VMI和IM的图像质量而言,PCCT设备上的高千伏选项(120或140 kV)总体表现优于低千伏选项(70或90 kV)。我们的结果建议在PCCT上对全身成像使用高千伏。
