Developments toward the Implementation of 44Sc Production at a Medical Cyclotron.

44Sc has favorable properties for cancer diagnosis using Positron Emission Tomography (PET) making it a promising candidate for application in nuclear medicine. The implementation of its production with existing compact medical cyclotrons would mean the next essential milestone in the development of this radionuclide. While the production and application of 44Sc has been comprehensively investigated, the development of specific targetry and irradiation methods is of paramount importance. As a result, the target was optimized for the 44Ca(p,n)44Sc nuclear reaction using CaO instead of CaCO3, ensuring decrease in target radioactive degassing during irradiation and increased radionuclidic yield. Irradiations were performed at the research cyclotron at the Paul Scherrer Institute (~11 MeV, 50 µA, 90 min) and the medical cyclotron at the University of Bern (~13 MeV, 10 µA, 240 min), with yields varying from 200 MBq to 16 GBq. The development of targetry, chemical separation as well as the practical issues and implications of irradiations, are analyzed and discussed. As a proof-of-concept study, the 44Sc produced at the medical cyclotron was used for a preclinical study using a previously developed albumin-binding prostate-specific membrane antigen (PSMA) ligand. This work demonstrates the feasibility to produce 44Sc with high yields and radionuclidic purity using a medical cyclotron, equipped with a commercial solid target station.

Therapeutic Potential of 47Sc in Comparison to 177Lu and 90Y: Preclinical Investigations.

Targeted radionuclide therapy with 177Lu- and 90Y-labeled radioconjugates is a clinically-established treatment modality for metastasized cancer. 47Sc is a therapeutic radionuclide that decays with a half-life of 3.35 days and emits medium-energy ß--particles. In this study, 47Sc was investigated, in combination with a DOTA-folate conjugate, and compared to the therapeutic properties of 177Lu-folate and 90Y-folate, respectively. In vitro, 47Sc-folate demonstrated effective reduction of folate receptor-positive ovarian tumor cell viability similar to 177Lu-folate, but 90Y-folate was more potent at equal activities due to the higher energy of emitted ß--particles. Comparable tumor growth inhibition was observed in mice that obtained the same estimated absorbed tumor dose (~21 Gy) when treated with 47Sc-folate (12.5 MBq), 177Lu-folate (10 MBq), and 90Y-folate (5 MBq), respectively. The treatment resulted in increased median survival of 39, 43, and 41 days, respectively, as compared to 26 days in untreated controls. There were no statistically significant differences among the therapeutic effects observed in treated groups. Histological assessment revealed no severe side effects two weeks after application of the radiofolates, even at double the activity used for therapy. Based on the decay properties and our results, 47Sc is likely to be comparable to 177Lu when employed for targeted radionuclide therapy. It may, therefore, have potential for clinical translation and be of particular interest in tandem with 44Sc or 43Sc as a diagnostic match, enabling the realization of radiotheragnostics in future.

Implementation of a new separation method to produce qualitatively improved 64 Cu.

BACKGROUND: 64 Cu (T1/2  = 12.7 h) is an important radionuclide for diagnostic purposes and used for positron emission tomography (PET). A previous method utilized at Paul Scherrer Institute (PSI) proved to be unreliable and, while a method using anion exchange chromatography is a popular choice worldwide, it was felt a different approach was required to obtain a robust chemical separation method. METHODS: Enriched 64 Ni targets were created by electroplating on gold foil. The targets were irradiated with protons degraded to approximately 11 MeV at PSI's Injector 2 72 MeV research cyclotron and subsequently dissolved in HCl. The resultant solution was loaded onto AG MP-50 cation exchange resin and the 64 Cu separated from its target material and radiocobalt impurities, produced as part of the irradiation process, using various specific mixtures of HCl/acetone solution. The eluted product was evaporated and picked up in dilute HCl (0.05 M). The chemical purity of 64 Cu was determined by radiolabeling experiments at the highest possible molar activities. RESULTS: Reproducible results were obtained, yielding 3.6 to 8.3 GBq 64 Cu of high radionuclidic and radiochemical purity. The product was labeled to NODAGA-RGD, achieved at up to 500 MBq/nmol, indicating the high chemical purity. In a proof-of-concept in vivo study, 64 Cu-NODAGA-RGD was used for PET imaging of a tumor-bearing mouse. CONCLUSION: The chemical separation devised to produce high-quality 64 Cu proved to be robust and reproducible. The concept can be used at medical cyclotrons utilizing a solid target station, such that 64 Cu can be used at hospitals for PET imaging.

Design and Preclinical Evaluation of an Albumin-Binding PSMA Ligand for 64Cu-Based PET Imaging.

Recently, we developed an albumin-binding radioligand (177Lu-PSMA-ALB-56), which showed higher PSMA-specific tumor uptake in mice than the previously developed 177Lu-PSMA-617 under the same experimental conditions. Such a radioligand may be of interest also for PET imaging, possibly enabling better visualization of even small metastases at late time-points after injection. The aim of this study was, therefore, to modify PSMA-ALB-56 by exchanging the DOTA chelator with a NODAGA chelator for stable coordination of 64Cu ( T1/2 = 12.7 h; Eß+av = 278 keV). The resulting NODAGA-functionalized PSMA-ALB-89 ligand, and the previously establish DOTA-functionalized PSMA-ALB-56 ligand were labeled with 64Cu and evaluated in vitro and in vivo. Both radioligands showed plasma protein-binding properties in vitro and PSMA-specific uptake in PC-3 PIP cells. Biodistribution studies, performed in tumor-bearing mice, revealed high accumulation of 64Cu-PSMA-ALB-89 in PSMA-positive PC-3 PIP tumor xenografts (25.9 ± 3.41% IA/g at 1 h p.i.), which was further increased at later time-points (65.1 ± 7.82% IA/g at 4 h p.i. and 97.1 ± 7.01% IA/g at 24 h p.i.). High uptake of 64Cu-PSMA-ALB-89 was also seen in the kidneys, however, 64Cu-PSMA-ALB-89 was efficiently excreted over time. Mice injected with 64Cu-PSMA-ALB-56 showed increased accumulation of radioactivity in the liver (25.3 ± 4.20% IA/g) when compared to the liver uptake of 64Cu-PSMA-ALB-89 (4.88 ± 0.21% IA/g, at 4 h p.i.). This was most probably due to in vivo instability of the 64Cu-DOTA complex, which was also the reason for lower tumor uptake (49.7 ± 16.1% IA/g at 4 h p.i. and 28.3 ± 3.59% IA/g at 24 h p.i.). PET/CT imaging studies confirmed these findings and enabled excellent visualization of the PSMA-positive tumor xenografts in vivo after injection of 64Cu-PSMA-ALB-89. These data indicate that 64Cu-PSMA-ALB-89 is favorable over 64Cu-PSMA-ALB-56 with regard to the in vivo stability and tissue distribution profile. Moreover, 64Cu-PSMA-ALB-89 outperformed previously developed 64Cu-labeled PSMA ligands. Further optimization of long-circulating PSMA-targeting PET radioligands will be necessary before translating this concept to the clinics.

In Vivo Labeling of Plasma Proteins for Imaging of Enhanced Vascular Permeability in the Lungs.

Increased vascular permeability is an important hallmark of many diseases, including cancer, cerebral ischemia, and severe inflammatory disorders. In this regard, the noninvasive assessment of pathologically increased vascular permeability in vivo is of great interest. In this study, the potential of albumin- and transthyretin-binding radioligands was evaluated for imaging of vascular hyperpermeability. For this purpose, the bleomycin-induced lung injury model was used as a model of inflammation-associated vascular leakage. The plasma protein-binding ligands, which bind to albumin (DOTA-PPB-01) and transthyretin (DOTA-PPB-03), were radiolabeled and used for nuclear imaging and biodistribution studies. In this regard, 177Lu was employed as a surrogate nuclide for detailed preclinical investigations, including single-photon emission computed tomography (SPECT) studies, whereas 44Sc was proposed as a radionuclide for positron emission tomography (PET), which may be relevant for future clinical translation. Mice were administered with these radioligands 6-9 days after intratracheal instillation of bleomycin or saline. Bleomycin-treated mice developed pronounced lung inflammation with enhanced vascular permeability that was reflected in significantly increased lung size and weight due to edema and infiltration with inflammatory cells. Biodistribution studies revealed significantly higher accumulation of 177Lu-DOTA-PPB-01 in injured lungs as compared to lungs of control animals at all investigated time points (4-48 h p.i.). The best contrast was achieved at late time points (16.1 ± 2.91% IA/g vs 2.03 ± 1.22% IA/g, 48 h p.i.) when the blood activity levels were ∼7.5% IA/g. Injection of 177Lu-DOTA-PPB-03 also resulted in increased lung accumulation in bleomycin-treated mice at all investigated time points (2-8 h p.i.). The pharmacokinetics was significantly faster, however, resulting in good contrast already at 8 h p.i. (4.32 ± 0.85% IA/g vs 1.06 ± 0.10% IA/g) when blood activity levels were ∼2% IA/g. The absolute lung accumulation of 177Lu-DOTA-PPB-03 was significantly lower than that of 177Lu-DOTA-PPB-01. PET/CT scans performed with 44Sc-DOTA-PPB-01 distinguished injured from healthy lungs only at late time points (20 h p.i.), whereas 44Sc-DOTA-PPB-03 already allowed the differentiation at 4 h p.i. due to its faster clearance. The investigated radioligands, 44Sc/177Lu-DOTA-PPB-01 and 44Sc/177Lu-DOTA-PPB-03, hold promise for the visualization of vascular leakage in a variety of pathological conditions. 44Sc would be the radionuclide of choice for clinical application as it can be stably coordinated with a DOTA chelator and enables PET imaging over extended periods.