使用钴 - 55、铜 - 64和镓 - 68对神经降压素靶向肽NOTA - NT - 20.3进行正电子发射断层显像（PET）成像

PET Imaging of the Neurotensin Targeting Peptide NOTA-NT-20.3 Using Cobalt-55, Copper-64 and Gallium-68.

作者信息

Houson Hailey A, Tekin Volkan, Lin Wilson, Aluicio-Sarduy Eduardo, Engle Jonathan W, Lapi Suzanne E

机构信息

Department of Radiology, University of Alabama at Birmingham, Birmingham, AL 35294, USA.

Department of Medical Physics, University of Wisconsin, 1111 Highland Avenue, Madison, WI 53705, USA.

出版信息

Pharmaceutics. 2022 Dec 6;14(12):2724. doi: 10.3390/pharmaceutics14122724.

DOI:10.3390/pharmaceutics14122724

PMID:36559218

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9781609/

Abstract

Introduction: Neurotensin receptor 1 (NTSR1) is an emerging target for imaging and therapy of many types of cancer. Nuclear imaging of NTSR1 allows for noninvasive assessment of the receptor levels of NTSR1 on the primary tumor, as well as potential metastases. This work focuses on a the neurotensin peptide analogue NT-20.3 conjugated to the chelator NOTA for radiolabeling for use in noninvasive positron emission tomography (PET). NOTA-NT-20.3 was radiolabeled with gallium-68, copper-64, and cobalt-55 to determine the effect that modification of the radiometal has on imaging and potential therapeutic properties of NOTA-NT-20.3. Methods: In vitro assays investigating cell uptake and subcellular localization of the radiolabeled peptides were performed using human colorectal adenocarcinoma HT29 cells. In vivo PET/CT imaging was used to determine the distribution and clearance of the peptide in mice bearing NTSR1 expressing HT29 tumors. Results: Cell uptake studies showed that the highest uptake was obtained with [55Co] Co-NOTA-NT-20.3 (18.70 ± 1.30%ID/mg), followed by [64Cu] Cu-NOTA-NT-20.3 (15.46 ± 0.91%ID/mg), and lastly [68Ga] Ga-NOTA-NT-20.3 (10.94 ± 0.46%ID/mg) (p < 0.001). Subcellular distribution was similar across the three constructs, with the membranous fraction containing the highest amount of radioactivity. In vivo PET/CT imaging of the three constructs revealed similar distribution and tumor uptake at the 1 h imaging timepoint. Tumor uptake was receptor-specific and blockable by co-injection of non-radiolabeled NOTA-NT-20.3. SUV ratios of tumor to heart at the 24 h imaging timepoint show that [55Co] Co-NOTA-NT-20.3 (20.28 ± 3.04) outperformed [64Cu] Cu-NOTA-NT-20.3 (6.52 ± 1.97). In conclusion, our studies show that enhanced cell uptake and increasing tumor to blood ratios over time displayed the superiority of [55Co] Co-NOTA-NT-20.3 over [68Ga] Ga-NOTA-NT-20.3 and [64Cu] Cu-NOTA-NT-20.3 for the targeting of NTSR1.

摘要

引言

神经降压素受体1（NTSR1）是多种癌症成像和治疗中一个新兴的靶点。NTSR1的核成像能够对原发性肿瘤以及潜在转移灶上NTSR1的受体水平进行无创评估。这项工作聚焦于与螯合剂NOTA偶联的神经降压素肽类似物NT - 20.3，用于放射性标记以用于无创正电子发射断层扫描（PET）。NOTA - NT - 20.3用镓 - 68、铜 - 64和钴 - 55进行放射性标记，以确定放射性金属修饰对NOTA - NT - 20.3的成像和潜在治疗特性的影响。方法：使用人结肠腺癌HT29细胞进行体外实验，研究放射性标记肽的细胞摄取和亚细胞定位。体内PET/CT成像用于确定该肽在携带表达NTSR1的HT29肿瘤的小鼠体内的分布和清除情况。结果：细胞摄取研究表明，[55Co]Co - NOTA - NT - 20.3的摄取量最高（18.70±1.30%ID/mg），其次是[64Cu]Cu - NOTA - NT - 20.3（15.46±0.91%ID/mg），最后是[68Ga]Ga - NOTA - NT - 20.3（10.94±0.46%ID/mg）（p<0.001）。三种构建体的亚细胞分布相似，膜部分的放射性最高。三种构建体的体内PET/CT成像显示在1小时成像时间点分布和肿瘤摄取相似。肿瘤摄取具有受体特异性，可通过共注射非放射性标记的NOTA - NT - 20.3来阻断。在24小时成像时间点肿瘤与心脏的SUV比值表明，[55Co]Co - NOTA - NT - 20.3（20.28±3.04）优于[64Cu]Cu - NOTA - NT - 20.3（6.52±1.97）。总之，我们的研究表明，随着时间推移，[55Co]Co - NOTA - NT - 20.3在细胞摄取增强和肿瘤与血液比值增加方面显示出优于[68Ga]Ga - NOTA - NT - 20.3和[64Cu]Cu - NOTA - NT - 20.3用于靶向NTSR1的优势。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/90ce/9781609/527428bbdf02/pharmaceutics-14-02724-g001.jpg

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使用钴 - 55、铜 - 64和镓 - 68对神经降压素靶向肽NOTA - NT - 20.3进行正电子发射断层显像（PET）成像

PET Imaging of the Neurotensin Targeting Peptide NOTA-NT-20.3 Using Cobalt-55, Copper-64 and Gallium-68.

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