Photochemische Konjugation und Eintopfradiomarkierung von Antikörpern für Immun‐PET

Eichenberger, Larissa S.; Fischer, Gregor; Holland, Jason P.

doi:10.1002/ange.201813287

“…Previously, we introduced alternative ways of making radiolabeled proteins by using photochemical processes. − Photoradiosynthesis has been shown to be compatible with various radionuclides, including 68 Ga, 89 Zr, and 111 In (as well as 99m Tc, 177 Lu, and 188 Re, unpublished data), and the methods were also extended to the use of photoactivatable fluorophores (PhotoTags). − The potential of using 64/67 Cu nuclides as a theranostic pair for diagnosis and radioimmunotherapy encouraged us to investigate the photoradiosynthesis of proteins with 64 Cu. Herein, we present the synthesis of a new tacn-based chelator bearing two methylthiazolyl pendants and an additional carboxylic acid function for further derivatization (H NODThia , Figure ) with peptide vectors or with a discrete water-soluble tris-polyethylene glycol (PEG 3 ) linker bearing an aryl azide (ArN 3 ) as a photoactivatable unit.…”

Section: Introductionmentioning

confidence: 99%

HNODThia: A Promising Chelator for the Development of ⁶⁴Cu Radiopharmaceuticals

Hierlmeier

¹

,

Guillou

²

,

Earley

³

et al. 2023

Inorg. Chem.

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Herein, we present the synthesis and coordination chemistry of copper(II) and zinc(II) complexes of two novel heterocyclic triazacyclononane (tacn)-based chelators (HNODThia and NODThia-AcNHEt). The chelator HNODThia was further derivatized to obtain a novel PSMA-based bioconjugate (NODThia-PSMA) and a bifunctional photoactivatable azamacrocyclic analogue, NODThia-PEG 3 -ArN 3 , for the development of copper-64 radiopharmaceuticals. 64Cu radiolabeling experiments were performed on the different metal-binding chelates, whereby quantitative radiochemical conversion (RCC) was obtained in less than 10 min at room temperature. The in vitro stability of NODThia-PSMA in human plasma was assessed by ligand-challenge and copper-exchange experiments. Next, we investigated the viability of the photoactivatable analog (NODThia-PEG 3 -ArN 3 ) for the light-induced photoradiosynthesis of radiolabeled proteins. One-pot photoconjugation reactions to human serum albumin (HSA) as a model protein and the clinically relevant monoclonal antibody formulation MetMAb were performed. [64Cu]Cu-7-azepin-HSA and [64Cu]Cu-7-azepin-onartuzumab were prepared in less than 15 min by irradiation at 395 nm, with radiochemical purities (RCP) of >95% and radiochemical yields (RCYs) of 42.7 ± 5.3 and 49.6%, respectively. Together, the results obtained here open the way for the development of highly stable 64Cu-radiopharmaceuticals by using aza-heterocyclic tacn-based chelators, and the method can easily be extended to the development of 67Cu radiopharmaceuticals for future applications in molecularly targeted radio(immuno)therapy.

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Supramolecular Rotaxane‐Based Multi‐Modal Probes for Cancer Biomarker Imaging**

d’Orchymont

¹

,

Holland

²

2022

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Mechanically interlocked molecules present opportunities to construct therapeutic drugs and diagnostic imaging agents but harnessing supramolecular chemistry to make biologically active probes in water is a challenge. Here, we describe a rotaxane-based approach to synthesise radiolabelled proteins and peptides for molecular imaging of cancer biomarkers in vivo. Host-guest chemistry using β-cyclodextrin-and cucurbit-[6]uril-catalysed cooperative capture synthesis produced gallium-68 or zirconium-89 radiolabelled metallo-[4]rotaxanes. Photochemical conjugation to trastuzumab led to a viable positron emission tomography (PET) radiotracer. The rotaxane architecture can be tuned to accommodate different radiometal ion complexes, other protein-or peptide-based drugs, and fluorophores for optical detection. This technology provides a platform to explore how mechanical bonding can improve drug delivery, enhance tumour specificity, control radiotracer pharmacokinetics, and reduce dosimetry.

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Supramolecular Rotaxane‐Based Multi‐Modal Probes for Cancer Biomarker Imaging**

d’Orchymont

¹

,

Holland

²

2022

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Mechanically interlocked molecules present opportunities to construct therapeutic drugs and diagnostic imaging agents but harnessing supramolecular chemistry to make biologically active probes in water is a challenge. Here, we describe a rotaxane-based approach to synthesise radiolabelled proteins and peptides for molecular imaging of cancer biomarkers in vivo. Host-guest chemistry using β-cyclodextrin-and cucurbit-[6]uril-catalysed cooperative capture synthesis produced gallium-68 or zirconium-89 radiolabelled metallo-[4]rotaxanes. Photochemical conjugation to trastuzumab led to a viable positron emission tomography (PET) radiotracer. The rotaxane architecture can be tuned to accommodate different radiometal ion complexes, other protein-or peptide-based drugs, and fluorophores for optical detection. This technology provides a platform to explore how mechanical bonding can improve drug delivery, enhance tumour specificity, control radiotracer pharmacokinetics, and reduce dosimetry.

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Photochemische Konjugation und Eintopfradiomarkierung von Antikörpern für Immun‐PET

Cited by 7 publications

References 33 publications

HNODThia: A Promising Chelator for the Development of ⁶⁴Cu Radiopharmaceuticals

HNODThia: A Promising Chelator for the Development of ⁶⁴Cu Radiopharmaceuticals

Supramolecular Rotaxane‐Based Multi‐Modal Probes for Cancer Biomarker Imaging**

Supramolecular Rotaxane‐Based Multi‐Modal Probes for Cancer Biomarker Imaging**

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Photochemische Konjugation und Eintopfradiomarkierung von Antikörpern für Immun‐PET

Cited by 7 publications

References 33 publications

HNODThia: A Promising Chelator for the Development of 64Cu Radiopharmaceuticals

HNODThia: A Promising Chelator for the Development of 64Cu Radiopharmaceuticals

Supramolecular Rotaxane‐Based Multi‐Modal Probes for Cancer Biomarker Imaging**

Supramolecular Rotaxane‐Based Multi‐Modal Probes for Cancer Biomarker Imaging**

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Product

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HNODThia: A Promising Chelator for the Development of ⁶⁴Cu Radiopharmaceuticals

HNODThia: A Promising Chelator for the Development of ⁶⁴Cu Radiopharmaceuticals