Reducing the Kidney Uptake of High Contrast CXCR4 PET Imaging Agents via Linker Modifications

Modification of Asp-Peptide Adapters: Giving the FAP-Targeted Radioligand a "Squirrel Tail"

Fibroblast activation protein (FAP) is a promising target for cancer theranostics, but most FAP-targeted radioprobes showed relatively insufficient tumor uptake and retention, which seriously hampered their further application. Inspired by the squirrel tail, this study developed a novel FAP-targeted molecule, FSND3, which is modified with three Asp-peptide adapters to enable both 68Ga ([68Ga]Ga-FSND3) and 18F ([18F]AlF-FSND3) PET imaging. Compared to [68Ga]Ga-FAPI-04, [68Ga]Ga-FAPI-42, and [18F]AlF-FAPI-42, [18F]AlF-FSND3 and [68Ga]Ga-FSND3 showed enhanced tumor uptake and prolonged residence in HT-1080-FAP and pancreatic tumor models, demonstrating the effectiveness of Asp-peptide adapters in pharmacomodulating FAP-targeted radioligands. The first-in-human pilot study revealed that [18F]AlF- and [68Ga]Ga-FSND3 exhibited comparable uptake in the primary lesion, higher-contrast images, and higher uptake in some metastases like in bone and brain, to 2-[18F] FDG PET/CT imaging. As a proof of concept, these results offer a significant enhancement to the diversity of the FAP-targeted tracer arsenal.

Influence of Linker Molecules on the Biodistribution Characteristics of 99mTc-labeled Mannose Derivatives with an Isocyanide-Coordinated Group

A hallmark of cancer cells is their increased glucose demand, which is mediated by glucose transporters (GLUTs). Mannose is imported into cells via GLUTs, thereby prompting the selection of mannose as the targeting molecule for designing radioactive derivatives for tumor imaging. In this study, five 99mTc-labeled mannose derivatives were prepared and evaluated in vitro and in vivo. The derivatives were conjugated with an isonitrile group and different linkers, including (CH2)5-Dpro, (CH2)6-Dpro, (CH2)7-Dpro, (CH2)5-Lpro, and (CH2)6-Lpro. All five radioactive compounds exhibited hydrophilicity and in vitro stability. A comparative biodistribution study demonstrated that probes modified with D-proline exhibited greater uptake in tumors than those modified with L-proline. [99mTc]Tc-L1 exhibited the highest accumulation in the tumor and the most favorable tumor-to-nontarget ratios. SPECT/CT imaging results of [99mTc]Tc-L1 demonstrated clear accumulation and visualization at the tumor site. Blocking studies in cells and mice bearing S180 tumors revealed that [99mTc]Tc-L1 was transported into cancer cells via a GLUT-mediated mechanism. These findings suggest that [99mTc]Tc-L1 is a promising probe for SPECT tumor imaging and that linker molecules significantly affect biodistribution characteristics.

Synthesis and preclinical evaluation of [18F]AlF-NOTA-Asp2-PEG2-JR11 as a novel antagonist radioligand for PET imaging of somatostatin receptor

PURPOSE

Somatostatin receptor (SSTR) antagonists have recently emerged as preferable radiotracers for SSTR-targeted imaging and therapy. This study aimed to design a novel SSTR antagonist, [18F]AlF-NOTA-Asp2-PEG2-JR11, and compare its preclinical performance with the previously reported antagonist, [18F]AlF-NOTA-JR11, and the agonist [68Ga]Ga-DOTA-TATE.

METHODS

[18F]AlF-NOTA-Asp2-PEG2-JR11 was synthesized via a one-step radiolabeling process involving [18F]AlF chelation. The binding affinity, internalization, and cellular uptake were evaluated using AR42J/SSTR + cells. Biodistribution and PET/CT imaging were conducted in mice bearing xenografted AR42J/SSTR + or HCT116/SSTR- tumor xenografts.

RESULTS

[18F]AlF-NOTA-Asp2-PEG2-JR11 was manually synthesized within 30 min with an uncorrected radiochemical yield of 39.56 ± 3.25% (n > 5) and radiochemical purity (RCP) exceeding 99% (n > 5). [18F]AlF-NOTA-Asp2-PEG2-JR11 demonstrated excellent in vivo stability over 2 h (RCP > 95%). Among AR42J cells, [18F]AlF-NOTA-Asp2-PEG2-JR11 exhibited high affinity, specific uptake, and low internalization, similar to [18F]AlF-NOTA-JR11. Biodistribution and micro-PET/CT imaging studies revealed comparable tumor uptake between [18F]AlF-NOTA-Asp2-PEG2-JR11 and [18F]AlF-NOTA-JR11 (9.26 ± 0.49 vs. 10.18 ± 0.82%ID/g, p = 0.147) at 60 min post-injection (p.i), both were significantly higher than [68Ga]Ga-DOTA-TATE (6.79 ± 0.29%ID/g, p = 0.001). Co-injecting the corresponding inhibitor significantly reduced the tumor uptake of all three tracers. Notably, [18F]AlF-NOTA-Asp2-PEG2-JR11 reached peak tumor uptake at 30 min p.i. and exhibited the lowest uptake and fastest clearance in most normal organs, including the kidney, bone, liver, and muscle, resulting in the highest and increasing tumor-to-background ratios (TBR) over time among the three tracers.

CONCLUSION

The synthesis of [18F]AlF-NOTA-Asp2-PEG2-JR11 is efficient, with high radiochemical yield and RCP. [18F]AlF-NOTA-Asp2-PEG2-JR11 exhibits excellent in vivo stability, high tumor uptake, and superior TBR, making it a promising potential tracer for imaging SSTR-positive tumors.

Lessons learned in application driven imaging agent design for image-guided surgery

To meet the growing demand for intraoperative molecular imaging, the development of compatible imaging agents plays a crucial role. Given the unique requirements of surgical applications compared to diagnostics and therapy, maximizing translational potential necessitates distinctive imaging agent designs. For effective surgical guidance, exogenous signatures are essential and are achievable through a diverse range of imaging labels such as (radio)isotopes, fluorescent dyes, or combinations thereof. To achieve optimal in vivo utility a balanced molecular design of the tracer as a whole is required, which ensures a harmonious effect of the imaging label with the affinity and specificity (e.g., pharmacokinetics) of a pharmacophore/targeting moiety. This review outlines common design strategies and the effects of refinements in the molecular imaging agent design on the agent's pharmacological profile. This includes the optimization of affinity, pharmacokinetics (including serum binding and target mediated background), biological clearance route, the achievable signal intensity, and the effect of dosing hereon.

Synthesis and Preclinical Evaluation of [18F]AlF-NOTA-Asp2-PEG2-Folate as a Novel Folate-Receptor-Targeted Tracer for PET Imaging

Recently, the folate receptor (FR) has become an exciting target for the diagnosis of FR-positive malignancies. Nevertheless, suboptimal in vivo pharmacokinetic properties, particularly high uptake in the renal and hepatobiliary systems, are important limiting factors for the clinical translation of most FR-based radiotracers. In this study, we developed a novel 18F-labeled FR-targeted positron emission tomography (PET) tracer [18F]AlF-NOTA-Asp2-PEG2-Folate modified with a hydrophilic linker (-Asp2-PEG2) to optimize its pharmacokinetic properties and conducted a comprehensive preclinical assessment. The [18F]AlF-NOTA-Asp2-PEG2-Folate was manually synthesized within 30 min with a non-decay-corrected radiochemical yield of 16.3 ± 2.0% (n = 5). Among KB cells, [18F]AlF-NOTA-Asp2-PEG2-Folate exhibited high specificity and affinity for FR. PET/CT imaging and biodistribution experiments in KB tumor-bearing mice showed decent tumor uptake (1.7 ± 0.3% ID/g) and significantly decreased uptake in kidneys and liver (22.2 ± 2.1 and 0.3 ± 0.1% ID/g at 60 min p.i., respectively) of [18F]AlF-NOTA-Asp2-PEG2-Folate, compared to the known tracer [18F]AlF-NOTA-Folate (78.6 ± 5.1 and 5.3 ± 0.5 % ID/g at 90 min p.i., respectively). The favorable properties of [18F]AlF-NOTA-Asp2-PEG2-Folate, including its efficient synthesis, decent tumor uptake, relatively low renal uptake, and rapid clearance from most normal organs, portray it as a promising PET tracer for FR-positive tumors.

Precision peptide theranostics: developing N- to C-terminus optimized theranostics targeting cholecystokinin-2 receptor

Peptides are ideal for theranostic development as they afford rapid target accumulation, fast clearance from background tissue, and exhibit good tissue penetration. Previously, we developed a novel series of peptides that presented discreet folding propensity leading to an optimal candidate [68Ga]Ga-DOTA-GA1 ([D-Glu]6-Ala-Tyr-NMeGly-Trp-NMeNle-Asp-Nal-NH2) with 50 pM binding affinity against cholecystokinin-2 receptors (CCK2R). However, we were confronted with challenges of unfavorably high renal uptake. Methods: A structure activity relationship study was undertaken of the lead theranostic candidate. Prudent structural modifications were made to the peptide scaffold to evaluate the contributions of specific N-terminal residues to the overall biological activity. Optimal candidates were then evaluated in nude mice bearing transfected A431-CCK2 tumors, and their biodistribution was quantitated ex vivo. Results: We identified and confirmed that D-Glu3 to D-Ala3 substitution produced 2 optimal candidates, [68Ga]Ga-DOTA-GA12 and [68Ga]Ga-DOTA-GA13. These radiopeptides presented with high target/background ratios, enhanced tumor retention, excellent metabolic stability in plasma and mice organ homogenates, and a 4-fold reduction in renal uptake, significantly outperforming their non-alanine counterparts. Conclusions: Our study identified novel radiopharmaceutical candidates that target the CCK2R. Their high tumor uptake and reduced renal accumulation warrant clinical translation.

Chelator impact: investigating the pharmacokinetic behavior of copper-64 labeled PD-L1 radioligands

BACKGROUND

Programmed cell death ligand 1 (PD-L1) plays a critical role in the tumor microenvironment and overexpression in several solid cancers has been reported. This was associated with a downregulation of the local immune response, specifically of T-cells. Immune checkpoint inhibitors showed a potential to break this localized immune paralysis, but only 30% of patients are considered responders. New diagnostic approaches are therefore needed to determine patient eligibility. Small molecule radiotracers targeting PD-L1, may serve as such diagnostic tools, addressing the heterogeneous PD-L1 expression between and within tumor lesions, thus aiding in therapy decisions.

RESULTS

Four biphenyl-based small-molecule PD-L1 ligands were synthesized using a convergent synthetic route with a linear sequence of up to eleven steps. As a chelator NODA-GA, CB-TE2A or DiAmSar was used to allow radiolabeling with copper-64 ([64Cu]Cu-14-[64Cu]Cu-16). In addition, a dimeric structure based on DiAmSar was synthesized ([64Cu]Cu-17). All four radioligands exhibited high proteolytic stability (> 95%) up to 48 h post-radiolabeling. Saturation binding yielded moderate affinities toward PD-L1, ranging from 100 to 265 nM. Real-time radioligand binding provided more promising KD values around 20 nM for [64Cu]Cu-14 and [64Cu]Cu-15. In vivo PET imaging in mice bearing both PC3 PD-L1 overexpressing and PD-L1-mock tumors was performed at 0-2, 4-5 and 24-25 h post injection (p.i.). This revealed considerably different pharmacokinetic profiles, depending on the substituted chelator. [64Cu]Cu-14, substituted with NODA-GA, showed renal clearance with low liver uptake, whereas substitution with the cross-bridged cyclam chelator CB-TE2A resulted in a primarily hepatobiliary clearance. Notably, the monomeric DiAmSar radioligand [64Cu]Cu-16 demonstrated a higher liver uptake than [64Cu]Cu-15, but was still renally cleared as evidenced by the lack of uptake in gall bladder and intestines. The dimeric structure [64Cu]Cu-17 showed extensive accumulation and trapping in the liver but was also cleared via the renal pathway. Of all tracer candidates and across all timepoints, [64Cu]Cu-17 showed the highest accumulation at 24 h p.i. in the PD-L1-overexpressing tumor of all timepoints and all radiotracers, indicating drastically increased circulation time upon dimerization of two PD-L1 binding motifs.

CONCLUSIONS

This study shows that chelator choice significantly influences the pharmacokinetic profile of biphenyl-based small molecule PD-L1 radioligands. The NODA-GA-conjugated radioligand [64Cu]Cu-14 exhibited favorable renal clearance; however, the limited uptake in tumors suggests the need for structural modifications to the binding motif for future PD-L1 radiotracers.

Towards the Magic Radioactive Bullet: Improving Targeted Radionuclide Therapy by Reducing the Renal Retention of Radioligands

Targeted radionuclide therapy (TRT) is an emerging field and has the potential to become a major pillar in effective cancer treatment. Several pharmaceuticals are already in routine use for treating cancer, and there is still a high potential for new compounds for this application. But, a major issue for many radiolabeled low-to-moderate-molecular-weight molecules is their clearance via the kidneys and their subsequent reuptake. High renal accumulation of radioactive compounds may lead to nephrotoxicity, and therefore, the kidneys are often the dose-limiting organs in TRT with these radioligands. Over the years, different strategies have been developed aiming for reduced kidney retention and enhanced therapeutic efficacy of radioligands. In this review, we will give an overview of the efforts and achievements of the used strategies, with focus on the therapeutic potential of low-to-moderate-molecular-weight molecules. Among the strategies discussed here is coadministration of compounds that compete for binding to the endocytic receptors in the proximal tubuli. In addition, the influence of altering the molecular design of radiolabeled ligands on pharmacokinetics is discussed, which includes changes in their physicochemical properties and implementation of cleavable linkers or albumin-binding moieties. Furthermore, we discuss the influence of chelator and radionuclide choice on reabsorption of radioligands by the kidneys.