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采用临床光子计数探测器 CT 平台对一种口服暗硼硅酸盐造影剂的单能和多能 CT 性能进行表征。

Characterization of single- and multi-energy CT performance of an oral dark borosilicate contrast media using a clinical photon-counting-detector CT platform.

机构信息

Department of Radiology, Mayo Clinic, Rochester, Minnesota, USA.

NEXTRAST, INC., Hillsborough, California, USA.

出版信息

Med Phys. 2023 Nov;50(11):6779-6788. doi: 10.1002/mp.16713. Epub 2023 Sep 5.

DOI:10.1002/mp.16713
PMID:37669507
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10840945/
Abstract

BACKGROUND

The feasibility of oral dark contrast media is under exploration in abdominal computed tomography (CT) applications. One of the experimental contrast media in this class is dark borosilicate contrast media (DBCM), which has a CT attenuation lower than that of intra-abdominal fat.

PURPOSE

To evaluate the performances of DBCM using single- and multi-energy CT imaging on a clinical photon-counting-detector CT (PCD-CT).

METHODS

Five vials, three with iodinated contrast agent (5, 10, and 20 mg/mL; Omnipaque 350) and two with DBCM (6% and 12%; Nextrast, Inc.), and one solid-water rod (neutral contrast agent) were inserted into two multi-energy CT phantoms, and scanned on a clinical PCD-CT system (NAEOTOM Alpha) at 90, 120, 140, Sn100, and Sn140 kV (Sn: tin filter) in multi-energy mode. CARE keV IQ level was 180 (CTDIvol: 3.0 and 12.0 mGy for the small and large phantoms, respectively). Low-energy threshold images were reconstructed with a quantitative kernel (Qr40, iterative reconstruction strength 2) and slice thickness/increment of 2.0/2.0 mm. Virtual monoenergetic images (VMIs) were reconstructed from 40 to 140 keV at 10 keV increments. On all images, average CT numbers for each vial/rod were measured using circular region-of-interests and averaged over eight slices. The contrast-to-noise ratio (CNR) of iodine (5 mg/mL) against DBCM was calculated and plotted against tube potential and VMI energy level, and compared to the CNR of iodine against water. Similar analyses were performed on iodine maps and VNC images derived from the multi-energy scan at 120 kV.

RESULTS

With increasing kV or VMI keV, the negative HU of DBCM decreased only slightly, whereas the positive HU of iodine decreased across all contrast concentrations and phantom sizes. CT numbers for DBCM decreased from -178.5 ± 9.6 to -194.4 ± 6.3 HU (small phantom) and from -181.7 ± 15.7 to -192.1 ± 11.9 HU (large phantom) for DBCM-12% from 90 to Sn140 kV; on VMIs, the CT numbers for DBCM decreased minimally from -147.1 ± 15.7 to -185.1 ± 9.2 HU (small phantom) and -158.8 ± 28.6 to -188.9 ± 14.7 HU (large phantom) from 40 to 70 keV, but remained stable from 80 to 140 keV. The highest iodine CNR against DBCM in low-energy threshold images was seen at 90 or Sn140 kV for the small phantom, whereas all CNR values from low-energy threshold images for the large phantom were comparable. The CNR values of iodine against DBCM computed on VMIs were highest at 40 or 70 keV depending on iodine and DBCM concentrations. The CNR values of iodine against DBCM were consistently higher than iodine to water (up to 460% higher dependent on energy level). Further, the CNR of iodine compared to DBCM is less affected by VMI energy level than the identical comparison between iodine and water: CNR values at 140 keV were reduced by 46.6% (small phantom) or 42.6% (large phantom) compared to 40 keV; CNR values for iodine compared to water were reduced by 86.3% and 83.8% for similar phantom sizes, respectively. Compared to 70 keV VMI, the iodine CNR against DBCM was 13%-79% lower on iodine maps and VNC.

CONCLUSIONS

When evaluated at different tube potentials and VMI energy levels using a clinical PCD-CT system, DBCM showed consistently higher CNR compared to iodine versus water (a neutral contrast).

摘要

背景

口服深色对比剂在腹部计算机断层扫描(CT)应用中的可行性正在探索中。此类实验性对比剂之一是深色硼硅酸盐对比剂(DBCM),其 CT 衰减值低于腹腔脂肪。

目的

使用临床光子计数探测器 CT(PCD-CT)评估 DBCM 的性能,采用单能和多能 CT 成像。

方法

将 5 个小瓶,3 个含碘对比剂(5、10 和 20mg/mL;Omnipaque 350)和 2 个 DBCM(6%和 12%;Nextrast,Inc.),以及一个固体水棒(中性对比剂)插入两个多能 CT 体模中,并在临床 PCD-CT 系统(NAEOTOM Alpha)上以 90、120、140、Sn100 和 Sn140kV(Sn:锡滤器)进行多能扫描。CARE keV IQ 水平为 180(小和大体模的 CTDIvol 分别为 3.0 和 12.0mGy)。使用定量核(Qr40,迭代重建强度 2)和 2.0/2.0mm 的切片厚度/增量重建低能阈值图像。从 40 到 140keV 以 10keV 的增量重建虚拟单能图像(VMI)。在所有图像上,使用圆形感兴趣区域测量每个小瓶/棒的平均 CT 数,并在 8 个切片上进行平均。计算碘(5mg/mL)与 DBCM 的对比噪声比(CNR),并绘制与管电压和 VMI 能级的关系图,并与碘与水的 CNR 进行比较。在 120kV 的多能扫描中,对碘图和 VNC 图像进行了类似的分析。

结果

随着千伏或 VMI 千电子伏特的增加,DBCM 的负 HU 值仅略有下降,而碘的正 HU 值在所有对比浓度和体模尺寸下均下降。DBCM-12%的 CT 数从小体模的-178.5±9.6HU 降至-194.4±6.3HU,从-181.7±15.7HU 降至-192.1±11.9HU,从 90kV 降至 Sn140kV;在 VMI 上,DBCM 的 CT 数从 40keV 的-147.1±15.7HU 降至-185.1±9.2HU,从小体模的-158.8±28.6HU 降至-188.9±14.7HU,从 70keV 的-188.9±14.7HU 降至 140keV,但从 80keV 到 140keV 仍保持稳定。低能阈值图像中碘与 DBCM 的最高碘 CNR 值见于小体模的 90kV 或 Sn140kV,而大体模的所有低能阈值图像的 CNR 值都相当。取决于碘和 DBCM 的浓度,在 40 或 70keV 时,VMI 上碘与 DBCM 的 CNR 值最高。碘与 DBCM 的 CNR 值始终高于碘与水(取决于能级,最高可达 460%)。此外,碘与 DBCM 的 CNR 值受 VMI 能级的影响小于碘与水的相同比较:与 40keV 相比,140keV 时的 CNR 值分别降低了 46.6%(小体模)或 42.6%(大体模);对于类似的体模尺寸,碘与水的 CNR 值分别降低了 86.3%和 83.8%。与 70keV VMI 相比,碘与 DBCM 的碘 CNR 值在碘图和 VNC 上分别降低了 13%至 79%。

结论

使用临床 PCD-CT 系统在不同管电压和 VMI 能级下进行评估时,DBCM 与碘与水(中性对比)相比,始终显示出更高的 CNR。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a148/10840945/77dd5eff1b8c/nihms-1927907-f0007.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a148/10840945/77dd5eff1b8c/nihms-1927907-f0007.jpg

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