H<sub>2</sub>BZmacropa-NCS: A Bifunctional Chelator for Actinium-225 Targeted Alpha Therapy

Kadassery, Karthika J.; King, Alan; Fayn, S.; Baidoo, Kwamena E.; MacMillan, Samantha N.; Escorcia, Freddy E.; Wilson, Justin J.

doi:10.1021/acs.bioconjchem.2c00190

Cited by 21 publications

(22 citation statements)

References 49 publications

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“…This explains the slight decrease in the difference between the ionic radii of actinium and lanthanum compared to those expected from the literature (0.06 Å vs 0.09 Å) . The chemical similarity ,, of La 3+ and Ac 3+ also proves the correctness of the results.…”

Section: Resultssupporting

confidence: 79%

“…This explains the slight decrease in the difference between the ionic radii of actinium and lanthanum compared to those expected from the literature (0.06 Å vs 0.09 Å). 30 The chemical similarity 17,18,29 of La 3+ and Ac 3+ also proves the correctness of the results. The H 4 octapa ligand, like H 4 BATA, has four donor nitrogen atoms and four carboxyl oxygens coordinating lanthanum.…”

Section: Calculated Structure Of [Labata]supporting

confidence: 60%

“…To test the applicability of the liquid extraction technique, first, we determined the stability constant of the complex of La 3+ with the H 4 BATA ligand. La 3+ is usually used in works where it is impossible to conduct an experiment with the trace amounts of Ac 3+ . ,,, The reason is that the Ac 3+ ion possesses chemical properties that are similar to that of the lanthanide and Ln 3+ ions. Specifically, lanthanum, La 3+ , is a suitable nonradioactive surrogate for the Ac 3+ ion .…”

Section: Resultsmentioning

confidence: 99%

“…La 3+ is usually used in works where it is impossible to conduct an experiment with the trace amounts of Ac 3+ . 17,18,23,29 The reason is that the Ac 3+ ion possesses chemical properties that are similar to that of the lanthanide and Ln 3+ ions. Specifically, lanthanum, La 3+ , is a suitable nonradioactive surrogate for the Ac 3+ ion.…”

Section: ■ Introductionmentioning

confidence: 99%

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Insights into Actinium Complexes with Tetraacetates─AcBATA versus AcDOTA: Thermodynamic, Structural, and Labeling Properties

Matazova,

Egorova,

Zubenko

et al. 2023

Inorg. Chem.

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In the current research, we conducted a comparative study of the Ac 3+ complex with H 4 DOTA and H 4 BATA. The stability constants of the [AcBATA] − and [AcDOTA] − complexes were studied directly by extraction methods. We discovered that the thermodynamic properties of the [AcBATA] − complex are superior to those of [AcDOTA] − . Moreover, the fast kinetics of H 4 BATA complexation with Ac 3+ during the radiolabeling experiment was observed already at room temperature. Ac 3+ was placed inside the macrocyclic cavity of the [AcBATA] − complex, preventing the release of the cation. According to DFT studies, two possible conformations were found, where two pendant arms coordinate with the metal cation on one side of the azacrown cavity and two on the other side, or three pendant arms are located on one side and one on the other. Finally, high inertness in vitro and in vivo of [AcBATA] − was discovered, making the H 4 BATA ligand highly preferable for application as a component of actinium-based radiopharmaceuticals.

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Section: Resultssupporting

confidence: 79%

Section: Calculated Structure Of [Labata]supporting

confidence: 60%

Section: Resultsmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

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Insights into Actinium Complexes with Tetraacetates─AcBATA versus AcDOTA: Thermodynamic, Structural, and Labeling Properties

Matazova,

Egorova,

Zubenko

et al. 2023

Inorg. Chem.

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“…The resistance to human serum for [ 225 Ac]Ac 3+ −macropa observed here is also consistent with prior studies. 15,30,53 Although the radiolabeling efficiency of py 2 -macrodipa is comparable to that of pymacrodipa, the kinetic stability of [ 225 Ac]Ac 3+ −py 2 -macrodipa is substantially enhanced relative to that of [ 225 Ac]Ac 3+ −pymacrodipa, which showed a ∼90% complex dissociation in human serum at 37 °C after 24 h. 15 This observation is also consistent with the DTPA transchelation challenge results (Table 2), which also revealed an overall higher Ln 3+ complex kinetic stability for py 2 -macrodipa. Collectively, py 2 -macrodipa shows promise for use with 225 Ac 3+ based on its efficient radiolabeling and high complex stability.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Chelating Rare-Earth Metals (Ln³⁺) and ²²⁵Ac³⁺ with the Dual-Size-Selective Macrocyclic Ligand Py₂-Macrodipa

Simms

Kertész

et al. 2022

Inorg. Chem.

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Radioisotopes of metallic elements, or radiometals, are widely employed in both therapeutic and diagnostic nuclear medicine. For this application, chelators that efficiently bind the radiometal of interest and form a stable metal–ligand complex with it are required. Toward the development of new chelators for nuclear medicine, we recently reported a novel class of 18-membered macrocyclic chelators that is characterized by their ability to form stable complexes with both large and small rare-earth metals (Ln3+), a property referred to as dual size selectivity. A specific chelator in this class called py-macrodipa, which contains one pyridyl group within its macrocyclic core, was established as a promising candidate for 135La3+, 213Bi3+, and 44Sc3+ chelation. Building upon this prior work, here we report the synthesis and characterization of a new chelator called py2-macrodipa with two pyridyl units fused into the macrocyclic backbone. Its coordination chemistry with the Ln3+ series was investigated by NMR spectroscopy, X-ray crystallography, density functional theory (DFT) calculations, analytical titrations, and transchelation assays. These studies reveal that py2-macrodipa retains the expected dual size selectivity and possesses an enhanced thermodynamic affinity for all Ln3+ compared to py-macrodipa. By contrast, the kinetic stability of Ln3+ complexes with py2-macrodipa is only improved for the light, large Ln3+ ions. Based upon these observations, we further assessed the suitability of py2-macrodipa for use with 225Ac3+, a large radiometal with valuable properties for targeted α therapy. Radiolabeling and stability studies revealed py2-macrodipa to efficiently incorporate 225Ac3+ and to form a complex that is inert in human serum over 3 weeks. Although py2-macrodipa does not surpass the state-of-the-art chelator macropa for 225Ac3+ chelation, it does provide another effective 225Ac3+ chelator. These studies shed light on the fundamental coordination chemistry of the Ln3+ series and may inspire future chelator design efforts.

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Chelator‐Assisted Precipitation‐Based Separation of the Rare Earth Elements Neodymium and Dysprosium from Aqueous Solutions

Gao,

Licup,

Bigham

et al. 2024

Angewandte Chemie

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The rare earth elements (REEs) are critical resources for many clean energy technologies, but are difficult to obtain in their elementally pure forms because of their nearly identical chemical properties. Here, an analogue of macropa, G‐macropa, was synthesized and employed for an aqueous precipitation‐based separation of Nd3+ and Dy3+. G‐macropa maintains the same thermodynamic preference for the large REEs as macropa, but shows smaller thermodynamic stability constants. Molecular dynamics studies demonstrate that the binding affinity differences of these chelators for Nd3+ and Dy3+ is a consequence of the presence or absence of an inner‐sphere water molecule, which alters the donor strength of the macrocyclic ethers. Leveraging the small REE affinity of G‐macropa, we demonstrate that within aqueous solutions of Nd3+, Dy3+, and G‐macropa, the addition of HCO3– selectively precipitates Dy2(CO3)3, leaving the Nd3+–G‐macropa complex in solution. With this method, remarkably high separation factors of 841 and 741 are achieved for 50:50 and 75:25 mixtures. Further studies involving Nd3+:Dy3+ ratios of 95:5 in authentic magnet waste also afford an efficient separation as well. Lastly, G‐macropa is recovered via crystallization with HCl and used for subsequent extractions, demonstrating its good recyclability.

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H₂BZmacropa-NCS: A Bifunctional Chelator for Actinium-225 Targeted Alpha Therapy

Cited by 21 publications

References 49 publications

Insights into Actinium Complexes with Tetraacetates─AcBATA versus AcDOTA: Thermodynamic, Structural, and Labeling Properties

Insights into Actinium Complexes with Tetraacetates─AcBATA versus AcDOTA: Thermodynamic, Structural, and Labeling Properties

Chelating Rare-Earth Metals (Ln³⁺) and ²²⁵Ac³⁺ with the Dual-Size-Selective Macrocyclic Ligand Py₂-Macrodipa

Chelator‐Assisted Precipitation‐Based Separation of the Rare Earth Elements Neodymium and Dysprosium from Aqueous Solutions

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H2BZmacropa-NCS: A Bifunctional Chelator for Actinium-225 Targeted Alpha Therapy

Cited by 21 publications

References 49 publications

Insights into Actinium Complexes with Tetraacetates─AcBATA versus AcDOTA: Thermodynamic, Structural, and Labeling Properties

Insights into Actinium Complexes with Tetraacetates─AcBATA versus AcDOTA: Thermodynamic, Structural, and Labeling Properties

Chelating Rare-Earth Metals (Ln3+) and 225Ac3+ with the Dual-Size-Selective Macrocyclic Ligand Py2-Macrodipa

Chelator‐Assisted Precipitation‐Based Separation of the Rare Earth Elements Neodymium and Dysprosium from Aqueous Solutions

Contact Info

Product

Resources

About

H₂BZmacropa-NCS: A Bifunctional Chelator for Actinium-225 Targeted Alpha Therapy

Chelating Rare-Earth Metals (Ln³⁺) and ²²⁵Ac³⁺ with the Dual-Size-Selective Macrocyclic Ligand Py₂-Macrodipa