Department of Nuclear Science and Technology, Nanjing University of Aeronautics and Astronautics, No. 29 Jiangjun Ave, Nanjing, 211016, People's Republic of China.
JYAMS PET Research and Development Limited, No. 568 Longmian Ave, Nanjing, 211100, People's Republic of China.
Eur J Nucl Med Mol Imaging. 2022 Jul;49(8):2618-2633. doi: 10.1007/s00259-022-05750-8. Epub 2022 Mar 26.
This study was to design and synthesize a novel bifunctional chelator, named Dar, primarily validated by conjugating to tumor targeting motifs, labeled with radiometals, and performed preclinical evaluation of tumor imaging and cancer therapy in murine tumor models.
The designed Dar was synthesized and characterized by X-ray crystallography, H/C NMR, and mass spectrometry. Dar-PSMA-617 was conjugated and radiolabeled with Ga, Lu, and Zr. The in vivo behavior of Ga/Zr-labeled Dar-PSMA-617 were evaluated using micro-PET imaging and biodistribution from image quantitation and tissue radioactivity counting, with Ga/Zr-labeled NOTA/DOTA/DFO-PSMA-617 analogs as controls, respectively. The [Lu]-Dar-PSMA-617, with [Lu]-DOTA-PSMA-617 as control, was evaluated in competitive cell uptake, tumor cell internalization, and efflux studies. The treatment efficacy of [Lu]Lu-Dar-PSMA-617, with [Lu]Lu-DOTA-PSMA-617 as control, was evaluated in PSMA-positive LNCaP tumor-bearing mice. In addition, the ability of Dar for radiolabeling nanobody was tested by conjugating Dar to KN035 nanobody. The resultant [Zr]Zr-Dar-KN035 nanobody, with [Zr]Zr-DFO-KN035 as control, was evaluated by micro-PET imaging and biodistribution in a mouse model bearing MC38&MC38-hPD-L1 colon cancer.
Ga, Zr, and Lu-radiolabeled Dar-PSMA-617 complexes were able to be produced under mild condition with high radiochemical yield and purity successfully. [Lu]Lu-Dar-PSMA-617 had higher cellular uptake yet similar internalization and efflux properties in LNCaP cells, as compared to [Lu]Lu-DOTA-PSMA-617. Micro-PET images demonstrated significantly higher tumor uptake of [Ga]Ga-Dar-PSMA-617, than that of the analog [Ga]Ga-DOTA-PSMA-617. The tumor uptake values of [Ga]Ga-Dar-PSMA-617 at multiple time points are comparable to that of [Ga]Ga-NOTA-PSMA-617, although a higher and persistently prolonged kidney retention was resulted in during the study period. The Dar chelator can also successfully mediate the radiolabeling with Zr, while the resultant [Zr]Zr-Dar-PSMA-617 demonstrated a similar biodistribution with [Zr]Zr-DFO-PSMA-617 measured at 96 h p.i. The treatment with [Lu]Lu-Dar-PSMA-617 significantly inhibited the tumor growth, showing much better efficacy than that of [Lu]Lu-DOTA-PSMA-617 at the same injected radioactivity and mass dose. Dar was covalently linked to KN035 nanobody and enabled radiolabeling with Zr in high yield and radiochemical purity at room temperature. The resultant [Zr]Zr-Dar-KN035, with [Zr]Zr-DFO-KN035 as control, demonstrated superior tumor uptake and detection capability in PET imaging studies.
The Dar, as a novel bifunctional chelator for medicating the labeling of radiometals onto tumor targeting carriers, was successfully synthesized and chemically characterized. Test radiolabeling, on PSMA-617 and a nanobody as tool targeting molecule carriers, demonstrated the Dar has potential as a universal bifunctional chelator for radiolabeling various radiometals (at least Ga, Lu, and Zr tested) commonly used for clinical imaging and therapy. Using a novel Dar chelator results in altered in vivo behavior of the carriers even though labeled with the same nuclide. This capability makes Dar an alternative to the existing choices for radiolabeling new carrier molecules with various radiometals, especially the radiometals with large radius.
本研究旨在设计和合成一种新型双功能螯合剂,命名为 Dar,主要通过与肿瘤靶向基序缀合,标记放射性金属,并在小鼠肿瘤模型中进行肿瘤成像和癌症治疗的临床前评估。
通过 X 射线晶体学、H/C NMR 和质谱对设计的 Dar 进行合成和表征。Dar-PSMA-617 与 Ga、Lu 和 Zr 偶联并标记。使用 micro-PET 成像和生物分布从图像定量和组织放射性计数评估 Ga/Zr 标记的 Dar-PSMA-617 的体内行为,并分别以 Ga/Zr 标记的 NOTA/DOTA/DFO-PSMA-617 类似物作为对照。[Lu]-Dar-PSMA-617 与[Lu]-DOTA-PSMA-617 作为对照,在竞争性细胞摄取、肿瘤细胞内化和外排研究中进行评估。以[Lu]Lu-DOTA-PSMA-617 作为对照,评估[Lu]Lu-Dar-PSMA-617 的治疗效果。此外,通过将 Dar 与 KN035 纳米体缀合来测试 Dar 对放射性标记纳米体的能力。用[Zr]Zr-Dar-KN035 纳米体,以[Zr]Zr-DFO-KN035 作为对照,通过 micro-PET 成像和生物分布在携带 MC38&MC38-hPD-L1 结肠癌的小鼠模型中进行评估。
在温和条件下,成功地制备了 Ga、Zr 和 Lu 放射性标记的 Dar-PSMA-617 复合物,具有高放射化学产率和纯度。与[Lu]Lu-DOTA-PSMA-617 相比,[Lu]Lu-Dar-PSMA-617 在 LNCaP 细胞中的细胞摄取更高,但内化和外排特性相似。micro-PET 图像显示,与类似物[Ga]Ga-DOTA-PSMA-617 相比,[Ga]Ga-Dar-PSMA-617 对肿瘤的摄取明显更高。尽管在研究期间导致肾脏保留时间延长和保留时间延长,但[Ga]Ga-Dar-PSMA-617 在多个时间点的肿瘤摄取值与[Ga]Ga-NOTA-PSMA-617 相当。Dar 螯合剂也可以成功介导与 Zr 的放射性标记,而所得[Zr]Zr-Dar-PSMA-617 的生物分布与[Zr]Zr-DFO-PSMA-617 相似,在 96 h p.i. 时测量。[Lu]Lu-Dar-PSMA-617 的治疗显著抑制肿瘤生长,与相同注入放射性和质量剂量的[Lu]Lu-DOTA-PSMA-617 相比,疗效更好。Dar 与 KN035 纳米体共价连接,并能在室温下以高收率和放射化学纯度标记 Zr。所得[Zr]Zr-Dar-KN035,以[Zr]Zr-DFO-KN035 作为对照,在 PET 成像研究中显示出更好的肿瘤摄取和检测能力。
作为一种新型双功能螯合剂,用于介导放射性金属标记到肿瘤靶向载体上,成功合成并进行了化学表征。对 PSMA-617 和纳米体作为工具靶向分子载体的放射性标记测试表明,Dar 有可能成为一种通用的双功能螯合剂,用于标记各种放射性金属(至少测试了 Ga、Lu 和 Zr),常用于临床成像和治疗。使用新型 Dar 螯合剂会改变载体的体内行为,即使标记的是相同的核素。这种能力使 Dar 成为用各种放射性金属标记新载体分子的现有选择的替代物,特别是对于大半径的放射性金属。
