Development and Preclinical Evaluation of [211At]PSAt-3-Ga: An Inhibitor for Targeted α-Therapy of Prostate Cancer.

The application of prostate-specific membrane antigen (PSMA)-targeted α-therapy is a promising alternative to ß--particle-based treatments. 211At is among the potential α-emitters that are favorable for this concept. Herein, 211At-based PSMA radiopharmaceuticals were designed, developed, and evaluated. Methods: To identify a 211At-labeled lead, a surrogate strategy was applied. Because astatine does not exist as a stable nuclide, it is commonly replaced with iodine to mimic the pharmacokinetic behavior of the corresponding 211At-labeled compounds. To facilitate the process of structural design, iodine-based candidates were radiolabeled with the PET radionuclide 68Ga to study their preliminary in vitro and in vivo properties before the desired 211At-labeled lead compound was formed. The most promising candidate from this evaluation was chosen to be 211At-labeled and tested in biodistribution studies. Results: All 68Ga-labeled surrogates displayed affinities in the nanomolar range and specific internalization in PSMA-positive LNCaP cells. PET imaging of these compounds identified [68Ga]PSGa-3 as the lead compound. Subsequently, [211At]PSAt-3-Ga was synthesized in a radiochemical yield of 35% and showed tumor uptake of 19 ± 8 percentage injected dose per gram of tissue (%ID/g) at 1 h after injection and 7.6 ± 2.9 %ID/g after 24 h. Uptake in off-target tissues such as the thyroid (2.0 ± 1.1 %ID/g), spleen (3.0 ± 0.6 %ID/g), or stomach (2.0 ± 0.4 %ID/g) was low, indicating low in vivo deastatination of [211At]PSAt-3-Ga. Conclusion: The reported findings support the use of iodine-based and 68Ga-labeled variants as a convenient strategy for developing astatinated compounds and confirm [211At]PSAt-3 as a promising radiopharmaceutical for targeted α-therapy.

Targeted imaging of uPAR expression in vivo with cyclic AE105 variants.

A comprehensive literature reports on the correlation between elevated levels of urokinase-type plasminogen activator receptor (uPAR) and the severity of diseases with chronic inflammation including solid cancers. Molecular imaging is widely used as a non-invasive method to locate disease dissemination via full body scans and to stratify patients for targeted treatment. To date, the only imaging probe targeting uPAR that has reached clinical phase-II testing relies on a high-affinity 9-mer peptide (AE105), and several studies by positron emission tomography (PET) scanning or near-infra red (NIR) fluorescence imaging have validated its utility and specificity in vivo. While our previous studies focused on applying various reporter groups, the current study aims to improve uPAR-targeting properties of AE105. We successfully stabilized the small uPAR-targeting core of AE105 by constraining its conformational landscape by disulfide-mediated cyclization. Importantly, this modification mitigated the penalty on uPAR-affinity typically observed after conjugation to macrocyclic chelators. Cyclization did not impair tumor targeting efficiency of AE105 in vivo as assessed by PET imaging and a trend towards increased tracer uptake was observed. In future studies, we predict that this knowledge will aid development of new fluorescent AE105 derivatives with a view to optical imaging of uPAR to assist precision guided cancer surgery.

3D blood-brain barrier-organoids as a model for Lyme neuroborreliosis highlighting genospecies dependent organotropism.

Lyme neuroborreliosis (LNB), a tick-borne infection caused by spirochetes within the Borrelia burgdorferi sensu lato (s.L.) complex, is among the most prevalent bacterial central nervous system (CNS) infections in Europe and the US. Here we have screened a panel of low-passage B. burgdorferi s.l. isolates using a novel, human-derived 3D blood-brain barrier (BBB)-organoid model. We show that human-derived BBB-organoids support the entry of Borrelia spirochetes, leading to swelling of the organoids and a loss of their structural integrity. The use of the BBB-organoid model highlights the organotropism between B. burgdorferi s.l. genospecies and their ability to cross the BBB contributing to CNS infection.

Development of a 64Cu-labeled CD4+ T cell targeting PET tracer: evaluation of CD4 specificity and its potential use in collagen-induced arthritis.

BACKGROUND: CD4+ T cells are central inflammatory mediators in the pathogenesis of autoimmune rheumatoid arthritis (RA), as they are one of the dominating cell types in synovial inflammation. Molecular imaging of CD4+ T cells has potential role for early detection and monitoring of RA. Here, we developed a new radiotracer for in vivo immunoPET imaging of murine CD4+ T cells and tested it in the collagen-induced arthritis (CIA) mouse model of human RA. RESULTS: The tracer, [64Cu]Cu-NOTA-CD4-F(ab)'2 ([64Cu]Cu-NOTA-CD4), was generated from F(ab)'2 fragments of R-anti-mouse CD4 antibodies conjugated to the 2-S-(isothiocyanatbenzyl)-1,4,7-triazacyclononane-1,4,7-triacetic acid (p-SCN-Bn-NOTA) chelator and radiolabeled with copper-64. Accumulation of the tracer and isotype control was evaluated in the CIA model and mice receiving whole-body irradiation (WBI) (5 Gy). The potential of [64Cu]Cu-NOTA-CD4 for response assessment was evaluated in CIA induced mice treated with dexamethasone (DXM). Imaging data were compared with flow cytometry and immunohistochemistry (IHC) of inflammatory cells including CD4+ T cells. [64Cu]Cu-NOTA-CD4 showed increased accumulation in T cell-rich tissues compared with isotype control (p < 0.0001). In addition, reduced accumulation of [64Cu]Cu-NOTA-CD4 was observed in T cell-depleted tissue (p < 0.0001). Flow cytometry and IHC confirmed the increased infiltration of CD4+ T cells in CIA mice. CONCLUSIONS: We developed and evaluated a new radiotracer, [64Cu]Cu-NOTA-CD4, for immunoPET imaging of murine CD4+ T cells. [64Cu]Cu-NOTA-CD4 was successfully synthesized by F(ab)'2 fragments of R-anti-mouse CD4 antibodies conjugated to a chelator and radiolabeled with copper-64. We found that our novel CD4 PET tracer can be used for noninvasive visualization of murine CD4+ T cells.

Corrigendum to 'quantitative determination of 64Cu-liposome accumulation at inflammatory and infectious sites: Potential for future theranostic system': [journal of controlled release 327 (2020) 737-746].

BACKGROUND: Therapeutic interventions for infectious and inflammatory diseases are becoming increasingly challenging in terms of therapeutic resistance and side-effects. Theranostic systems to ameliorate diagnosis and therapy are therefore highly warranted. The pathophysiological changes in inflammatory lesions provide an attractive basis for extravasation and accumulation of PEGylated liposomes. The objective of this study was to provide direct quantitative information on the theranostic potential of radiolabeled liposome for accumulation in inflammatory models using position emission tomography (PET). METHOD: Preclinical murine models of inflammation (turpentine and LPS), infection (Staphylococcus aureus) and collagen-induced arthritis (CIA) was established and monitored using bioluminescence imaging (BLI). Across all models PET imaging using radiolabeled PEGylated liposomes (64Cu-liposomes) were performed and evaluated in terms of accumulation properties in inflammatory and infectious lesions. RESULTS: BLI demonstrated that the inflammatory and infectious models were successfully established and provided information on lesion pathology. Activity of 64Cu-liposomes were increased in inflammatory and infectious lesions between early (10-min or 3-h) and late (24-h) PET scans, which validates that a continuous extravasation and accumulation of long circulation PEGylated liposomes occurs. CONCLUSION: The theranostic potential of long circulating PEGylated radiolabeled liposomes was shown in multiple preclinical models. Impressive accumulation was seen in both inflammatory and infectious lesions. These results are encouraging towards advancing PEGylated liposomes as imaging and drug delivery systems in inflammatory and infectious diseases.