Design and Evaluation of Novel Albumin-Binding Folate Radioconjugates: Systematic Approach of Varying the Linker Entities.

Tumor targeting using folate radioconjugates is a promising strategy for theragnostics of folate receptor-positive tumors. The aim of this study was to investigate the impact of structural modifications of folate radioconjugates on their pharmacokinetic properties. Four novel folate radioconjugates ([177Lu]Lu-OxFol-2, [177Lu]Lu-OxFol-3, [177Lu]Lu-OxFol-4, and [177Lu]Lu-OxFol-5), modified with a lipophilic or hydrophilic linker entity in close proximity to the albumin-binding 4-(p-iodophenyl)butanoate entity or the DOTA chelator, respectively, were designed and evaluated for comparison with the previously developed [177Lu]Lu-OxFol-1. A hydrophobic 4-(aminomethyl)benzoic acid linker, incorporated in close proximity to the 4-(p-iodophenyl)butanoate entity, enhanced the albumin-binding properties (relative affinity 7.3) of [177Lu]Lu-OxFol-3 as compared to those of [177Lu]Lu-OxFol-1 (relative affinity set as 1.0). On the other hand, a hydrophilic d-glutamic acid (d-Glu) linker entity used in [177Lu]Lu-OxFol-2 compromised the albumin-binding properties. [177Lu]Lu-OxFol-4 and [177Lu]Lu-OxFol-5, in which the respective linker entities were incorporated adjacent to the DOTA chelator, showed similar albumin-binding properties (0.6 and 1.0, respectively) as [177Lu]Lu-OxFol-1. Biodistribution studies in KB tumor-bearing nude mice revealed twofold higher tumor-to-kidney ratios at 4 h and 24 h after injection of [177Lu]Lu-OxFol-3 (∼1.2) than after injection of [177Lu]Lu-OxFol-1 (∼0.6). The tumor-to-kidney ratios of [177Lu]Lu-OxFol-2 were, however, much lower (∼0.2) due to the high kidney retention of this radioconjugate. The tumor-to-kidney ratios of [177Lu]Lu-OxFol-5 were only slightly increased (∼0.9), and the ratios for [177Lu]Lu-OxFol-4 (∼0.7) were in the same range as for [177Lu]Lu-OxFol-1. SPECT/CT imaging studies demonstrated similar tumor uptake of all radioconjugates but a clearly improved tumor-to-kidney ratio for [177Lu]Lu-OxFol-3 as compared to that for [177Lu]Lu-OxFol-1. Based on these data, it can be concluded that the linker entity in close proximity to the 4-(p-iodophenyl)butanoate entity affects the radioconjugate's pharmacokinetic profile considerably due to the altered affinity to albumin. Changes in the linker entity, which connects the DOTA chelator with the folate molecule, do not have a major impact on the radioconjugate's tissue distribution profile, however. As a result of these findings, [177Lu]Lu-OxFol-3 had a comparable therapeutic effect to that of [177Lu]Lu-OxFol-1 but appeared advantageous in preventing kidney damage. Provided that the kidneys will present the dose-limiting organs in patients, [177Lu]Lu-OxFol-3 would be the preferred candidate for a clinical translation.

Novel Synthetic Strategies Enable the Efficient Development of Folate Conjugates for Cancer Radiotheranostics.

The folate receptor (FR) is an interesting target for radiotheranostics due to its overexpression in several tumor types. The progress in developing novel folate radioconjugates is, however, slow due to the synthetic challenges that folate chemistry presents. The goal of this study was, thus, to establish versatile solid-phase synthetic strategies for a convenient preparation of novel folate conjugates. Two approaches were established based on an orthogonal fluorenylmethyloxycarbonyl (Fmoc)-protection strategy to enable a modular buildup of an albumin-binding DOTA conjugate (known as OxFol-1) using folic acid (oxidized folate version) as a targeting agent. The main difference between the two approaches was the sequence of conjugating the single structural units. The approach that introduced the folate entity as the last unit appeared particularly useful for the preparation of conjugates based on 6R- or 6S-5-methyltetrahydrofolic acid (5-MTHF; a reduced folate version) as targeting entity. Three types of folate conjugates were synthesized either with a p-iodophenyl-based albumin binder (OxFol-1, 6R-RedFol-1, and 6S-RedFol-1) or without an albumin-binding entity (OxFol-14, 6R-RedFol-14, and 6S-RedFol-14). All six conjugates were obtained with high chemical purity (>98%) after 9-13 synthesis steps and a single final HPLC purification. Radiolabeling with lutetium-177 was feasible at high molar activity, and the resulting radioconjugates were stable over at least 24 h. Biodistribution and SPECT/CT imaging studies confirmed the favorable effect of an albumin-binding entity to increase the tumor uptake and reduce kidney retention of folate radioconjugates. The increased tumor-to-kidney ratios obtained with [177Lu]Lu-6R-RedFol-1 and [177Lu]Lu-6S-RedFol-1 as compared to [177Lu]Lu-OxFol-1 indicated that 5-MTHF is the preferred FR-targeting agent for albumin-binding radioconjugates. This was, however, not the case for folate radioconjugates without an albumin binder. Thanks to the established synthesis strategy, the preparation of further folate radioconjugates will be facilitated, potentially enabling the optimization of the tissue distribution characteristics even more.

Identification of a PET Radiotracer for Imaging of the Folate Receptor-α: A Potential Tool to Select Patients for Targeted Tumor Therapy.

The aim of this study was to identify a folate receptor-α (FRα)-selective PET agent potentially suitable for the selection of patients who might profit from FRα-targeted therapies. The 6R and 6S isomers of 18F-aza-5-methyltetrahydrofolate (MTHF) were assessed regarding their binding to FRα and FRß, expressed on cancer and inflammatory cells, respectively, and compared with 18F-AzaFol, the folic acid-based analog. Methods: FR selectivity was investigated using FRα-transfected (RT16) and FRß-transfected (D4) CHO cells. The cell uptake of 18F-folate tracers was investigated, and receptor-binding affinities were determined with the nonradioactive analogs. In vitro autoradiography of the 18F-folate tracers was performed using RT16 and D4 tissue sections. Biodistribution studies and PET/CT imaging of the radiotracers were performed on mice bearing RT16 and D4 xenografts. Results: The uptake of 18F-6R-aza-5-MTHF was high when using RT16 cells (62% ± 10% of added activity) but much lower when using D4 cells (5% ± 2%). The FRα selectivity of 18F-6R-aza-5-MTHF was further demonstrated by its approximately 43-fold higher binding affinity to FRα (half-maximal inhibitory concentration [IC50], 1.8 ± 0.1 nM) than to FRß (IC50, 77 ± 27 nM). The uptake of 18F-6S-aza-5-MTHF and 18F-AzaFol was equal in both cell lines (52%-70%), with similar affinities to FRα (IC50, 2.1 ± 0.4 nM and 0.6 ± 0.3 nM, respectively) and FRß (0.8 ± 0.2 nM and 0.3 ± 0.1 nM, respectively). The autoradiography signal obtained with 18F-6R-aza-5-MTHF was 11-fold more intense for RT16 than for D4 tissue sections. Biodistribution data showed high uptake of 18F-6R-aza-5-MTHF in RT16 xenografts (81% ± 20% injected activity per gram [IA]/g 1 h after injection) but significantly lower accumulation in D4 xenografts (7.3% ± 2.1% IA/g 1 h after injection), which was also visualized using PET. The uptake of 18F-6S-aza-5-MTHF and 18F-AzaFol was similar in RT16 (53% ± 10% IA/g and 45% ± 2% IA/g, respectively) and D4 xenografts (77% ± 10% IA/g and 52% ± 7% IA/g, respectively). Conclusion: This study demonstrated FRα selectivity for 18F-6R-aza-5-MTHF but not for 18F-6S-aza-5-MTHF or 18F-AzaFol. This characteristic, together with its favorable tissue distribution, makes 18F-6R-aza-5-MTHF attractive for clinical translation to enable detection of FRα-positive cancer while preventing undesired accumulation in FRß-expressing inflammatory cells.

Preclinical evaluation of 5-methyltetrahydrofolate-based radioconjugates-new perspectives for folate receptor-targeted radionuclide therapy.

PURPOSE: The folate receptor (FR) is frequently overexpressed in a variety of tumor types and, hence, an interesting target for radionuclide therapy. The aim of this study was to evaluate a new class of albumin-binding radioconjugates comprising 5-methyltetrahydrofolate (5-MTHF) as a targeting agent and to compare their properties with those of the previously established folic acid-based [177Lu]Lu-OxFol-1. METHODS: [177Lu]Lu-6R-RedFol-1 and [177Lu]Lu-6S-RedFol-1 were investigated in vitro using FR-positive KB tumor cells. Biodistribution studies were performed in KB tumor-bearing mice, and the areas under the curve (AUC0 → 120h) were determined for the uptake in tumors and kidneys. [177Lu]Lu-6R-RedFol-1 was compared with [177Lu]Lu-OxFol-1 in a therapy study over 8 weeks using KB tumor-bearing mice. RESULTS: Both radioconjugates demonstrated similar in vitro properties as [177Lu]Lu-OxFol-1; however, the tumor uptake of [177Lu]Lu-6R-RedFol-1 and [177Lu]Lu-6S-RedFol-1 was significantly increased in comparison with [177Lu]Lu-OxFol-1. In the case of [177Lu]Lu-6S-RedFol-1, also the kidney uptake was increased; however, renal retention of [177Lu]Lu-6R-RedFol-1 was similar to that of [177Lu]Lu-OxFol-1. This led to an almost 4-fold increased tumor-to-kidney AUC0 → 120h ratio of [177Lu]Lu-6R-RedFol-1 as compared with [177Lu]Lu-6S-RedFol-1 and [177Lu]Lu-OxFol-1. At equal activity, the therapeutic effect of [177Lu]Lu-6R-RedFol-1 was better than that of [177Lu]Lu-OxFol-1, reflected by a slower tumor growth and, consequently, an increased median survival time (49 days vs. 34 days). CONCLUSION: This study demonstrated the promising potential of 5-MTHF-based radioconjugates for FR-targeting. Application of [177Lu]Lu-6R-RedFol-1 resulted in unprecedentedly high tumor-to-kidney ratios and, as a consequence, a superior therapeutic effect as compared with [177Lu]Lu-OxFol-1. These findings, together with the absence of early side effects, make [177Lu]Lu-6R-RedFol-1 attractive in view of a future clinical translation.

Promising potential of [177Lu]Lu-DOTA-folate to enhance tumor response to immunotherapy-a preclinical study using a syngeneic breast cancer model.

PURPOSE: It was previously demonstrated that radiation effects can enhance the therapy outcome of immune checkpoint inhibitors. In this study, a syngeneic breast tumor mouse model was used to investigate the effect of [177Lu]Lu-DOTA-folate as an immune stimulus to enhance anti-CTLA-4 immunotherapy. METHODS: In vitro and in vivo studies were performed to characterize NF9006 breast tumor cells with regard to folate receptor (FR) expression and the possibility of tumor targeting using [177Lu]Lu-DOTA-folate. A preclinical therapy study was performed over 70 days with NF9006 tumor-bearing mice that received vehicle only (group A); [177Lu]Lu-DOTA-folate (5 MBq; 3.5 Gy absorbed tumor dose; group B); anti-CTLA-4 antibody (3 × 200 µg; group C), or both agents (group D). The mice were monitored regarding tumor growth over time and signs indicating adverse events of the treatment. RESULTS: [177Lu]Lu-DOTA-folate bound specifically to NF9006 tumor cells and tissue in vitro and accumulated in NF9006 tumors in vivo. The treatment with [177Lu]Lu-DOTA-folate or an anti-CTLA-4 antibody had only a minor effect on NF9006 tumor growth and did not substantially increase the median survival time of mice (23 day and 19 days, respectively) as compared with untreated controls (12 days). [177Lu]Lu-DOTA-folate sensitized, however, the tumors to anti-CTLA-4 immunotherapy, which became obvious by reduced tumor growth and, hence, a significantly improved median survival time of mice (> 70 days). No obvious signs of adverse effects were observed in treated mice as compared with untreated controls. CONCLUSION: Application of [177Lu]Lu-DOTA-folate had a positive effect on the therapy outcome of anti-CTLA-4 immunotherapy. The results of this study may open new perspectives for future clinical translation of folate radioconjugates.

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.

Combining Albumin-Binding Properties and Interaction with Pemetrexed to Improve the Tissue Distribution of Radiofolates.

Folic-acid-based radioconjugates have been developed for nuclear imaging of folate receptor (FR)-positive tumors; however, high renal uptake was unfavorable in view of a therapeutic application. Previously, it was shown that pre-injection of pemetrexed (PMX) increased the tumor-to-kidney ratio of radiofolates several-fold. In this study, PMX was combined with the currently best performing radiofolate ([177Lu]cm13), which is outfitted with an albumin-binding entity. Biodistribution studies were carried out in mice bearing KB or IGROV-1 tumor xenografts, both FR-positive tumor types. SPECT/CT was performed with control mice injected with [177Lu]folate only and with mice that received PMX in addition. Control mice showed high uptake of radioactivity in KB and IGROV-1 tumor xenografts, but retention in the kidneys was also high, resulting in tumor-to-kidney ratios of ~0.85 (4 h p.i.) and ~0.60 (24 h p.i.) or ~1.17 (4 h p.i.) and ~1.11 (24 h p.i.) respectively. Pre-injection of PMX improved the tumor-to-kidney ratio to values of ~1.13 (4 h p.i.) and ~0.92 (24 h p.i.) or ~1.79 (4 h p.i.) and ~1.59 (24 h p.i.), respectively, due to reduced uptake in the kidneys. It was found that a second injection of PMX­3 h or 7 h after administration of the radiofolate­improved the tumor-to-kidney ratio further to ~1.03 and ~0.99 or ~1.78 and ~1.62 at 24 h p.i. in KB and IGROV-1 tumor-bearing mice, respectively. SPECT/CT scans readily visualized the tumor xenografts, whereas accumulation of radioactivity in the kidneys was reduced in mice that received PMX. In this study, it was shown that PMX had a positive impact in terms of reducing the kidney uptake of albumin-binding radiofolates; hence, the administration of PMX resulted in ~1.3⁻1.7-fold higher tumor-to-kidney ratios. This is, however, a rather moderate effect in comparison to the previously shown effect of PMX on conventional radiofolates (without albumin binder), which led to 5⁻6-fold increased tumor-to-kidney ratios. An explanation for this result may be the different pharmacokinetic profiles of PMX and long-circulating radiofolates, respectively. Despite the promising potential of this concept, it is believed that a clinical translation would be challenging, particularly when PMX had to be injected more than once.

[1,4]-sigmatropic rearrangement of chiral nitrones and their utilization in the synthesis of new iminosugars.

Reflection on the epimerization of the α-stereocenter of sugar nitrones leads to the conclusion that the process may occur through [1,4]-sigmatropic rearrangement. Participation of an ionic mechanism was excluded by a deuterium labeling experiment, and DFT calculations showed a reasonable energy barrier for the proposed [1,4]-shift. Products of the intramolecular 1,3-dipolar cycloaddition of the studied nitrones were utilized in the diversity-oriented synthesis of polyhydroxy derivatives of piperidine, indolizidine and quinolizidine. Minimal activity against the screened glucosidases and human melanoma cell lines was observed for some of the obtained compounds.