Novel astatine (211At)-labelled prostate-specific membrane antigen ligand with a neopentyl-glycol structure: evaluation of stability, efficacy, and safety using a prostate cancer xenograft model.

PURPOSE: Prostate-specific membrane antigen (PSMA)-targeted alpha therapy is considered a promising alternative treatment for metastatic castration-resistant prostate cancer (mCRPC). Though astatine-211 (211At) is potentially useful alpha-emitter producible by cyclotrons, its clinical application has been limited by instability and a tendency to deastatination in vivo. To overcome these challenges, we developed [211At]At-NpG-PSMA, a novel PSMA ligand with a neopentyl-glycol structure that enhances in vivo stability against deastatination. This study aimed to evaluate the stability, anti-tumour effect, and safety of [211At]At-NpG-PSMA in mice. METHODS: Xenograft models were prepared by subcutaneous transplantation of PSMA-positive PC-3 PIP cells into BALB/c nu/nu mice. [211At]At-NpG-PSMA was administered to assess biodistribution, and the anti-tumour effect was evaluated at doses of 0.32, 1.00 and 1.93 MBq in comparison with saline. Histopathological examinations were performed to evaluate damage to normal organs. RESULTS: [211At]At-NpG-PSMA demonstrated high tumour uptake (42.0 ± 13.1%ID/g at 3 h) with minimal uptake in non-target tissues, including thyroid, stomach and salivary grands (0.28 ± 0.20%ID, 0.71 ± 0.12%ID/g and 0.88 ± 0.10%ID/g at 3 h, respectively). A dose-dependent anti-tumour effect was observed, with tumour volumes increasing by 796.0 ± 437.6% in the control versus 161.0 ± 213.4%, -76.4 ± 19.2% and - 59.5 ± 41.6% in the 0.32, 1.00 and 1.93 MBq groups, respectively, by day 15. Mild renal tubule regeneration was noted in the 1.00 MBq group. CONCLUSION: [211At]At-NpG-PSMA demonstrated significant stability in vivo and anti-tumour effects with minimal side effects, indicating its potential as a new therapeutic drug for PSMA-targeted alpha therapy in mCRPC.

Development of a Neopentyl 211At-Labeled Activated Ester Providing In Vivo Stable 211At-Labeled Antibodies for Targeted Alpha Therapy.

In this study we developed a neopentyl 211At-labeled activated ester that incorporates a triazole spacer and applied it to the synthesis of an 211At-labeled cetuximab. The activated ester was synthesized via the nucleophilic 211At-astatination of a neopentyl sulfonate carrying two long alkyl chains that serve as a lipid tag, which was followed by the hydrolysis of an acetal. Additionally, we developed a novel Resin-Assisted Purification and Deprotection (RAPD) protocol involving a solid-phase extraction of the protected 211At-labeled compound from the mixture of the labeling reaction, hydrolysis of the acetal on the resin, and finally an elution of the 211At-labeled activator from the resin. This method allows the synthesis of an 211At-labeled activated ester with high purity through a simplified procedure that circumvents the need for HPLC purification. Using this 211At-labeled activated ester, we efficiently synthesized 211At-labeled cetuximab in 27±1 % radiochemical yield with 95 % radiochemical purity. This 211At-activated ester demonstrated high reactivity, and enabled the completion of the reaction with the antibody within 10 min. In comparative biodistribution studies between 211At-labeled cetuximab and the corresponding 125I-labeled cetuximab in normal mice, both the thyroid and stomach showed radioactivity levels that were less than 1.0 % of the injected dose.