The Evolving Coordination Chemistry of Radiometals for Targeted Alpha Therapy

Grieve, Melyssa L.; Paterson, Brett M.

doi:10.1071/ch21184

Cited by 11 publications

(13 citation statements)

References 185 publications

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“…The key criteria for the choice of alpha-particle-emitting radionuclides are the half-life, the stable binding to a chelating system, the particle energy, the possible decay chain properties, and the kinetics of the daughters, as well as the costs and availability. These features result in a small number of radionuclides that are suitable, including thorium-227, actinium-225, radium-223/-224, bismuth-212/-213, astatine-211, and terbium-149 [ 14 , 15 ]. Additionally, lead-212 can be mentioned in this list, while delivering one beta particle prior to the alpha decay.…”

Section: Radiochemistry and Concept Of Theranostic Matched Radionucli...mentioning

confidence: 99%

“…In aqueous environments, Pb is primarily found as a bivalent cation in the oxidation state +2. The most frequently used chelators for radioconjugate preparation are DOTA [ 52 ] and TCMC or DOTAM (1,4,7,10-tetraaza-1,4,7,10-tetra(2-carbamoylmethyl)cyclododecane) and the derivatives thereof, whereas DOTAM seems to have a higher in vivo stability compared to DOTA [ 14 ]. A total CN of 8 was found in the Pb complexes of the standard chelators DOTA, DOTAM, or DTPA with high log K values of >18.…”

Section: Radioisotopes Of Lead For Theranosticsmentioning

confidence: 99%

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Alpha-Emitting Radionuclides: Current Status and Future Perspectives

Miederer,

Benešová-Schäfer,

Mamat

et al. 2024

Pharmaceuticals

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The use of radionuclides for targeted endoradiotherapy is a rapidly growing field in oncology. In particular, the focus on the biological effects of different radiation qualities is an important factor in understanding and implementing new therapies. Together with the combined approach of imaging and therapy, therapeutic nuclear medicine has recently made great progress. A particular area of research is the use of alpha-emitting radionuclides, which have unique physical properties associated with outstanding advantages, e.g., for single tumor cell targeting. Here, recent results and open questions regarding the production of alpha-emitting isotopes as well as their chemical combination with carrier molecules and clinical experience from compassionate use reports and clinical trials are discussed.

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Section: Radiochemistry and Concept Of Theranostic Matched Radionucli...mentioning

confidence: 99%

Section: Radioisotopes Of Lead For Theranosticsmentioning

confidence: 99%

Alpha-Emitting Radionuclides: Current Status and Future Perspectives

Miederer,

Benešová-Schäfer,

Mamat

et al. 2024

Pharmaceuticals

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“…238 Despite this complication, DOTA and TCMC (also known as DOTAM) (1,4,7,10tetrakis(carbamoylmethyl)-1,4,7,10-tetraazacyclododecane), where the carboxylate arms are modified to carbamoylmethyl groups, remain the two most used chelators for the [ 212 Pb]Pb II /[ 203 Pb]Pb II pair to date, although others are in early stages of development. 239,240 Both have been conjugated to small molecules, 231,241 peptides, 234,242 and antibodies. 243−245 The therapeutic efficacy of DOTAMTATE (Figure 28) radiolabeled with lead-212 was evaluated in AR42J neuroendocrine tumor models.…”

Section: Targeted Therapy With Actinium-225 Macropa Conjugatesmentioning

confidence: 99%

“…For example, as [ 212 Pb]Pb(DOTA) decays to [ 212 Bi]Bi(DOTA), 35% of the bismuth ion is released from the ligand due to the formation of highly ionized Bi V and Bi VII as a result of the internal conversion process . Despite this complication, DOTA and TCMC (also known as DOTAM) (1,4,7,10-tetrakis(carbamoylmethyl)-1,4,7,10-tetraazacyclododecane), where the carboxylate arms are modified to carbamoylmethyl groups, remain the two most used chelators for the [ 212 Pb]Pb II /[ 203 Pb]Pb II pair to date, although others are in early stages of development. , Both have been conjugated to small molecules, , peptides, , and antibodies. − The therapeutic efficacy of DOTAMTATE (Figure ) radiolabeled with lead-212 was evaluated in AR42J neuroendocrine tumor models . Fractionated dosing showed a promising 100% survival rate when 3 × 555 kBq were administered over 2 or 3 week intervals with a combination of 5-fluorouracil to maximize tumor devastation.…”

Section: The Rise Of Targeted α Particle Therapymentioning

confidence: 99%

Theranostic Nuclear Medicine with Gallium-68, Lutetium-177, Copper-64/67, Actinium-225, and Lead-212/203 Radionuclides

Morgan,

Rudd,

Noor

et al. 2023

Chem. Rev.

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Molecular changes in malignant tissue can lead to an increase in the expression levels of various proteins or receptors that can be used to target the disease. In oncology, diagnostic imaging and radiotherapy of tumors is possible by attaching an appropriate radionuclide to molecules that selectively bind to these target proteins. The term “theranostics” describes the use of a diagnostic tool to predict the efficacy of a therapeutic option. Molecules radiolabeled with γ-emitting or β+-emitting radionuclides can be used for diagnostic imaging using single photon emission computed tomography or positron emission tomography. Radionuclide therapy of disease sites is possible with either α-, β-, or Auger-emitting radionuclides that induce irreversible damage to DNA. This Focus Review centers on the chemistry of theranostic approaches using metal radionuclides for imaging and therapy. The use of tracers that contain β+-emitting gallium-68 and β-emitting lutetium-177 will be discussed in the context of agents in clinical use for the diagnostic imaging and therapy of neuroendocrine tumors and prostate cancer. A particular emphasis is then placed on the chemistry involved in the development of theranostic approaches that use copper-64 for imaging and copper-67 for therapy with functionalized sarcophagine cage amine ligands. Targeted therapy with radionuclides that emit α particles has potential to be of particular use in late-stage disease where there are limited options, and the role of actinium-225 and lead-212 in this area is also discussed. Finally, we highlight the challenges that impede further adoption of radiotheranostic concepts while highlighting exciting opportunities and prospects.

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“…Among the radionuclides considered for TAT, thorium-227 ( 227 Th) has shown significant promise for this application. − In its decay to stable lead-207 ( 207 Pb), 227 Th produces five high-energy α particles, which cause DNA double-strand breaks and subsequent cell death. , The 18.7-day half-life ( t 1/2 ) of 227 Th is suitable for use with antibody-based targeting vectors that have a long circulation time in vivo. Another benefit of 227 Th for targeted radiotherapy is that the γ-rays emitted by this radionuclide may be used to quantitatively assess the distribution of the administered radiotherapeutic agent and the progress of the treatment in vivo using single-photon emission computed tomography/computed tomography (SPECT/CT) imaging. , Lastly, 227 Th is the parent isotope of 223 Ra, meaning that established strategies currently used for the production of 223 Ra can be directly applied to generation of 227 Th, − suggesting that sufficient quantities of this radioisotope may be available to sustain preclinical and clinical studies.…”

Section: Introductionmentioning

confidence: 99%

Macrocyclic 1,2-Hydroxypyridinone-Based Chelators as Potential Ligands for Thorium-227 and Zirconium-89 Radiopharmaceuticals

Woods,

Cosby,

Wacker

et al. 2023

Inorg. Chem.

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Thorium-227 (227Th) is an α-emitting radionuclide that has shown preclinical and clinical promise for use in targeted α-therapy (TAT), a type of molecular radiopharmaceutical treatment that harnesses high energy α particles to eradicate cancerous lesions. Despite these initial successes, there still exists a need for bifunctional chelators that can stably bind thorium in vivo. Toward this goal, we have prepared two macrocyclic chelators bearing 1,2-hydroxypyridinone groups. Both chelators can be synthesized in less than six steps from readily available starting materials, which is an advantage over currently available platforms. The complex formation constants (log βmlh) of these ligands with Zr4+ and Th4+, measured by spectrophotometric titrations, are greater than 34 for both chelators, indicating the formation of exceedingly stable complexes. Radiolabeling studies were performed to show that these ligands can bind [227Th]Th4+ at concentrations as low as 10–6 M, and serum stability experiments demonstrate the high kinetic stability of the formed complexes under biological conditions. Identical experiments with zirconium-89 (89Zr), a positron-emitting radioisotope used for positron emission tomography (PET) imaging, demonstrate that these chelators can also effectively bind Zr4+ with high thermodynamic and kinetic stability. Collectively, the data reported herein highlight the suitability of these ligands for use in 89Zr/227Th paired radioimmunotheranostics.

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The Evolving Coordination Chemistry of Radiometals for Targeted Alpha Therapy

Cited by 11 publications

References 185 publications

Alpha-Emitting Radionuclides: Current Status and Future Perspectives

Alpha-Emitting Radionuclides: Current Status and Future Perspectives

Theranostic Nuclear Medicine with Gallium-68, Lutetium-177, Copper-64/67, Actinium-225, and Lead-212/203 Radionuclides

Macrocyclic 1,2-Hydroxypyridinone-Based Chelators as Potential Ligands for Thorium-227 and Zirconium-89 Radiopharmaceuticals

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