生物分布分析的CT和mri辅助荧光层析重建。

IF 7 1区 医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Investigative Radiology Pub Date : 2024-07-01 Epub Date: 2023-12-01 DOI:10.1097/RLI.0000000000001052
Sarah Schraven, Ramona Brück, Stefanie Rosenhain, Teresa Lemainque, David Heines, Hormoz Noormohammadian, Oliver Pabst, Wiltrud Lederle, Felix Gremse, Fabian Kiessling
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引用次数: 0

摘要

目的:光学荧光成像可以纵向跟踪荧光团标记的药物、纳米颗粒和抗体的生物分布。在混合计算机断层扫描-荧光断层扫描(CT- flt)中,CT提供解剖信息来生成散射和吸收图,支持从原始光学数据进行三维重建。然而,鉴于CT有限的软组织对比,荧光重建和定量可能不准确且不够详细。磁共振成像(MRI)可以克服这些限制,扩大组织表征的选择。因此,我们旨在建立一种用于全身成像的CT-MRI-FLT混合方法,并将其与CT-FLT进行比较。材料和方法:首先通过扫描充满水和椰子油的假体建立基于mri的混合成像方法,其次通过定量死亡小鼠中插入物的Cy7浓度,最后通过分析af750标记的免疫球蛋白(IgG, IgA)在活SKH1小鼠中的生物分布。利用脂肪水分离mDixon序列获得的磁共振成像、CT和FLT,使用填充白色凡士林的鼠标支架框架中的标记物共同注册,两种模式下凡士林都是固体、稳定和可见的。结果:通过Dice评分比较分割一致性,证实了ct - mri融合。在校正了梯度线性失真和化学位移后,幻影分割显示出良好的一致性。死鼠和活鼠的器官分割显示出融合的充分一致性。标记鼠标支架框架和成功的CT-MRI融合使MRI-FLT以及CT-MRI- flt重建成为可能。CT、MRI或CT-MRI支持的荧光断层扫描重建在不同位置插入60 pmol荧光的死小鼠中具有可比性。虽然标准的CT-FLT重建只考虑软组织、皮肤、肺、脂肪和骨散射的一般价值,但MRI更通用的软组织对比可以额外考虑肝脏、肾脏和大脑。然而,这并没有显著改变FLT重建和定量,而对于扩展散射图,准确分割器官和整个小鼠身体是很重要的。各种FLT重建也为荧光免疫球蛋白的体内生物分布分析提供了可比较的结果。然而,MRI还能显示胆囊、甲状腺和大脑。此外,由于肝、脾和肾的分割轮廓比CT更清晰,因此更可靠。因此,改进的分割可以更好地分配荧光信号,并与MRI-FLT更有区别的结论。结论:全身CT-MRI-FLT作为一种新颖的三模成像方法,可以更准确地分配荧光信号,从而显著改善药代动力学分析。
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CT- and MRI-Aided Fluorescence Tomography Reconstructions for Biodistribution Analysis.

Objectives: Optical fluorescence imaging can track the biodistribution of fluorophore-labeled drugs, nanoparticles, and antibodies longitudinally. In hybrid computed tomography-fluorescence tomography (CT-FLT), CT provides the anatomical information to generate scattering and absorption maps supporting a 3-dimensional reconstruction from the raw optical data. However, given the CT's limited soft tissue contrast, fluorescence reconstruction and quantification can be inaccurate and not sufficiently detailed. Magnetic resonance imaging (MRI) can overcome these limitations and extend the options for tissue characterization. Thus, we aimed to establish a hybrid CT-MRI-FLT approach for whole-body imaging and compared it with CT-FLT.

Materials and methods: The MRI-based hybrid imaging approaches were established first by scanning a water and coconut oil-filled phantom, second by quantifying Cy7 concentrations of inserts in dead mice, and finally by analyzing the biodistribution of AF750-labeled immunoglobulins (IgG, IgA) in living SKH1 mice. Magnetic resonance imaging, acquired with a fat-water-separated mDixon sequence, CT, and FLT were co-registered using markers in the mouse holder frame filled with white petrolatum, which was solid, stable, and visible in both modalities.

Results: Computed tomography-MRI fusion was confirmed by comparing the segmentation agreement using Dice scores. Phantom segmentations showed good agreement, after correction for gradient linearity distortion and chemical shift. Organ segmentations in dead and living mice revealed adequate agreement for fusion. Marking the mouse holder frame and the successful CT-MRI fusion enabled MRI-FLT as well as CT-MRI-FLT reconstructions. Fluorescence tomography reconstructions supported by CT, MRI, or CT-MRI were comparable in dead mice with 60 pmol fluorescence inserts at different locations. Although standard CT-FLT reconstruction only considered general values for soft tissue, skin, lung, fat, and bone scattering, MRI's more versatile soft tissue contrast enabled the additional consideration of liver, kidneys, and brain. However, this did not change FLT reconstructions and quantifications significantly, whereas for extending scattering maps, it was important to accurately segment the organs and the entire mouse body. The various FLT reconstructions also provided comparable results for the in vivo biodistribution analyses with fluorescent immunoglobulins. However, MRI additionally enabled the visualization of gallbladder, thyroid, and brain. Furthermore, segmentations of liver, spleen, and kidney were more reliable due to better-defined contours than in CT. Therefore, the improved segmentations enabled better assignment of fluorescence signals and more differentiated conclusions with MRI-FLT.

Conclusions: Whole-body CT-MRI-FLT was implemented as a novel trimodal imaging approach, which allowed to more accurately assign fluorescence signals, thereby significantly improving pharmacokinetic analyses.

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来源期刊
Investigative Radiology
Investigative Radiology 医学-核医学
CiteScore
15.10
自引率
16.40%
发文量
188
审稿时长
4-8 weeks
期刊介绍: Investigative Radiology publishes original, peer-reviewed reports on clinical and laboratory investigations in diagnostic imaging, the diagnostic use of radioactive isotopes, computed tomography, positron emission tomography, magnetic resonance imaging, ultrasound, digital subtraction angiography, and related modalities. Emphasis is on early and timely publication. Primarily research-oriented, the journal also includes a wide variety of features of interest to clinical radiologists.
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