B. Ballard scite author profile

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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Gold(III) bis-thiosemicarbazonato complexes: synthesis, characterization, radiochemistry and X-ray crystal structure analysis

Bottenus

Kan

Jenkins

et al. 2010

Nuclear Medicine and Biology

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225Ac and 223Ra production via 800MeV proton irradiation of natural thorium targets

Weidner

Mashnik

John

et al. 2012

Applied Radiation and Isotopes

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Radioarsenic from a Portable 72Se/72As Generator: A Current Perspective

Ballard¹,

Nortier²,

Birnbaum³

et al. 2012

CRP

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Positron emission tomography (PET) of slower biological processes calls for the use of longer lived positron emitting radioisotopes. Beyond radionuclide production considerations, practicality and rapidity of subsequent labeling chemistry further limits the selection of radioisotopes with potentially favorable nuclear properties. One additional limitation is the availability of PET radiotracers at the point-of-care with appropriate on-site production methodologies or robust radionuclide generator systems. The positron emitter (72)As (half-life 26 h) is generated via decay of (72)Se (half-life 8.5 d); this pair comprises and excellent generator system for clinical availability of a longer lived PET isotope. Many (72)Se/As generator systems have been introduced utilizing the rich interplay of Se(IV)/Se(VI) and As(III) /As(V) chemical behavior. This paper describes available generator concepts, and briefly outlines some current arsenic labeling methodologies for the introduction of radioarsenic into biomolecules.

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Selenium-72 formation via natBr(p,x) induced by 100MeV Protons: Steps towards a novel 72Se/72As generator system

Ballard

Wycoff

Birnbaum

et al. 2012

Applied Radiation and Isotopes

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B. Ballard

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

Gold(III) bis-thiosemicarbazonato complexes: synthesis, characterization, radiochemistry and X-ray crystal structure analysis

225Ac and 223Ra production via 800MeV proton irradiation of natural thorium targets

Radioarsenic from a Portable 72Se/72As Generator: A Current Perspective

Selenium-72 formation via natBr(p,x) induced by 100MeV Protons: Steps towards a novel 72Se/72As generator system

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