Cryo-Fluorescence Tomography as a Tool for Visualizing Whole-Body Inflammation Using Perfluorocarbon Nanoemulsion Tracers.

IF 3 4区 医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Molecular Imaging and Biology Pub Date : 2024-10-01 Epub Date: 2024-07-17 DOI:10.1007/s11307-024-01926-w
Benjamin I Leach, Deanne Lister, Stephen R Adams, Julie Bykowski, Amy B Schwartz, Patrick McConville, Hemi Dimant, Eric T Ahrens
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引用次数: 0

Abstract

Purpose: We explore the use of intravenously delivered fluorescent perfluorocarbon (PFC) nanoemulsion tracers and multi-spectral cryo-fluorescence tomography (CFT) for whole-body tracer imaging in murine inflammation models. CFT is an emerging technique that provides high-resolution, three-dimensional mapping of probe localization in intact animals and tissue samples, enabling unbiased validation of probe biodistribution and minimizes reliance on laborious histological methods employing discrete tissue panels, where disseminated populations of PFC-labeled cells may be overlooked. This methodology can be used to streamline the development of new generations of non-invasive, cellular-molecular imaging probes for in vivo imaging.

Procedures: Mixtures of nanoemulsions with different fluorescent emission wavelengths were administered intravenously to naïve mice and models of acute inflammation, colitis, and solid tumor. Mice were euthanized 24 h post-injection, frozen en bloc, and imaged at high resolution (~ 50 µm voxels) using CFT at multiple wavelengths.

Results: PFC nanoemulsions were visualized using CFT within tissues of the reticuloendothelial system and inflammatory lesions, consistent with immune cell (macrophage) labeling, as previously reported in in vivo magnetic resonance and nuclear imaging studies. The CFT signals show pronounced differences among fluorescence wavelengths and tissues, presumably due to autofluorescence, differential fluorescence quenching, and scattering of incident and emitted light.

Conclusions: CFT is an effective and complementary methodology to in vivo imaging for validating PFC nanoemulsion biodistribution at high spatial localization, bridging the resolution gap between in vivo imaging and histology.

利用全氟碳纳米乳液示踪剂将低温荧光断层成像技术作为全身炎症的可视化工具
目的:我们探索了在小鼠炎症模型中使用静脉注射荧光全氟碳化物(PFC)纳米乳液示踪剂和多光谱冷冻荧光断层成像(CFT)进行全身示踪剂成像的方法。低温荧光断层扫描是一种新兴技术,它能在完整动物和组织样本中提供探针定位的高分辨率三维图谱,从而对探针的生物分布进行无偏见的验证,并最大限度地减少对采用离散组织面板的费力的组织学方法的依赖,因为这种方法可能会忽略PFC标记细胞的扩散群体。这种方法可用于简化新一代非侵入性、细胞-分子成像探针的开发:程序:给新出生的小鼠和急性炎症、结肠炎和实体瘤模型静脉注射不同荧光发射波长的纳米乳剂混合物。小鼠在注射后 24 小时安乐死,整体冷冻,并使用多波长 CFT 进行高分辨率成像(~ 50 微米体素):结果:使用 CFT 可观察到网状内皮系统组织和炎症病灶中的 PFC 纳米乳液,与之前在体内磁共振和核成像研究中报道的免疫细胞(巨噬细胞)标记一致。CFT 信号在不同荧光波长和不同组织之间存在明显差异,这可能是由于自发荧光、不同荧光淬灭以及入射光和发射光散射造成的:CFT是体内成像的一种有效补充方法,可用于验证PFC纳米乳液的高空间定位生物分布,弥补了体内成像与组织学之间的分辨率差距。
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来源期刊
CiteScore
6.90
自引率
3.20%
发文量
95
审稿时长
3 months
期刊介绍: Molecular Imaging and Biology (MIB) invites original contributions (research articles, review articles, commentaries, etc.) on the utilization of molecular imaging (i.e., nuclear imaging, optical imaging, autoradiography and pathology, MRI, MPI, ultrasound imaging, radiomics/genomics etc.) to investigate questions related to biology and health. The objective of MIB is to provide a forum to the discovery of molecular mechanisms of disease through the use of imaging techniques. We aim to investigate the biological nature of disease in patients and establish new molecular imaging diagnostic and therapy procedures. Some areas that are covered are: Preclinical and clinical imaging of macromolecular targets (e.g., genes, receptors, enzymes) involved in significant biological processes. The design, characterization, and study of new molecular imaging probes and contrast agents for the functional interrogation of macromolecular targets. Development and evaluation of imaging systems including instrumentation, image reconstruction algorithms, image analysis, and display. Development of molecular assay approaches leading to quantification of the biological information obtained in molecular imaging. Study of in vivo animal models of disease for the development of new molecular diagnostics and therapeutics. Extension of in vitro and in vivo discoveries using disease models, into well designed clinical research investigations. Clinical molecular imaging involving clinical investigations, clinical trials and medical management or cost-effectiveness studies.
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