Eva R. Birnbaum scite author profile

Actinium-225 is a promising isotope for targeted-α therapy. Unfortunately, progress in developing chelators for medicinal applications has been hindered by a limited understanding of actinium chemistry. This knowledge gap is primarily associated with handling actinium, as it is highly radioactive and in short supply. Hence, AcIII reactivity is often inferred from the lanthanides and minor actinides (that is, Am, Cm), with limited success. Here we overcome these challenges and characterize actinium in HCl solutions using X-ray absorption spectroscopy and molecular dynamics density functional theory. The Ac–Cl and Ac–OH2O distances are measured to be 2.95(3) and 2.59(3) Å, respectively. The X-ray absorption spectroscopy comparisons between AcIII and AmIII in HCl solutions indicate AcIII coordinates more inner-sphere Cl1– ligands (3.2±1.1) than AmIII (0.8±0.3). These results imply diverse reactivity for the +3 actinides and highlight the unexpected and unique AcIII chemical behaviour.

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Structures, Electronic Properties, and Oxidation-Reduction Reactivity of Halogenated Iron Porphyrins

Grinstaff¹,

Hill²,

Birnbaum³

et al. 1995

Inorg. Chem.

132

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Molecular structures of both Fe"'(TFPPBr8)Cl and Fe"(TFPPBrE)(py)z porphyrins reveal saddle distortions: Fell'-(TFPPBr8)Cl in triclinic space group Pi, a = 13.649(4) A, b = 14.474(4) A, c = 14.537 A, a = 89.26(2)", p = 67.13(1)", y = 71.82(2)", V = 2494.3(13) A3, Z = 2; Fe"(TFPPBrs)(py)z in triclinic space group Pi, a = 12.459-(7) A, b = 13.125(8) A, c = 20.989(11) A, a = 84.72(5)", , L3 = 72.87(4)", y = 69.04(5)", V = 3063(3) A3, Z =2. Similar to other chloro-iron(II1) porphyrins, peff at room temperature (5.96 p~) is that of a 6A1 state; peff at 2 K (4.2 p~) indicates a large zero-field splitting.

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Alpha-Emitters and Targeted Alpha Therapy in Oncology: from Basic Science to Clinical Investigations

et al. 2018

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Alpha-emitters are radionuclides that decay through the emission of high linear energy transfer α-particles and possess favorable pharmacologic profiles for cancer treatment. When coupled with monoclonal antibodies, peptides, small molecules, or nanoparticles, the excellent cytotoxic capability of α-particle emissions has generated a strong interest in exploring targeted α-therapy in the pre-clinical setting and more recently in clinical trials in oncology. Multiple obstacles have been overcome by researchers and clinicians to accelerate the development of targeted α-therapies, especially with the recent improvement in isotope production and purification, but also with the development of innovative strategies for optimized targeting. Numerous studies have demonstrated the in vitro and in vivo efficacy of the targeted α-therapy. Radium-223 (Ra) dichloride (Xofigo®) is the first α-emitter to have received FDA approval for the treatment of prostate cancer with metastatic bone lesions. There is a significant increase in the number of clinical trials in oncology using several radionuclides such as Actinium-225 (Ac), Bismuth-213 (Bi), Lead-212 (Pb), Astatine (At) or Radium-223 (Ra) assessing their safety and preliminary activity. This review will cover their therapeutic application as well as summarize the investigations that provide the foundation for further clinical development.

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Proton-induced cross sections relevant to production of 225Ac and 223Ra in natural thorium targets below 200MeV

Weidner

Mashnik

John

et al. 2012

Applied Radiation and Isotopes

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Cross sections for (223,)(225)Ra, (225)Ac and (227)Th production by the proton bombardment of natural thorium targets were measured at proton energies below 200 MeV. Our measurements are in good agreement with previously published data and offer a complete excitation function for (223,)(225)Ra in the energy range above 90 MeV. Comparison of theoretical predictions with the experimental data shows reasonable-to-good agreement. Results indicate that accelerator-based production of (225)Ac and (223)Ra below 200 MeV is a viable production method.

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Eva R. Birnbaum

19F NMR Spectra and Structures of Halogenated Porphyrins

Spectroscopic and computational investigation of actinium coordination chemistry

Structures, Electronic Properties, and Oxidation-Reduction Reactivity of Halogenated Iron Porphyrins

Alpha-Emitters and Targeted Alpha Therapy in Oncology: from Basic Science to Clinical Investigations

Proton-induced cross sections relevant to production of 225Ac and 223Ra in natural thorium targets below 200MeV

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