Chromatographic separation of selenium and arsenic: A potential 72Se/72As generator

Wycoff, Donald E.; Gott, Merryn; DeGraffenreid, Anthony J.; Morrow, Ryan P.; Sisay, Nebiat; Embree, Mary; Ballard, B.; Fassbender, Michael E.; Cutler, Cathy S.; Ketring, Alan R.; Jurisson, Silvia S.

doi:10.1016/j.chroma.2014.03.033

Cited by 21 publications

(17 citation statements)

References 24 publications

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“…Arsenic-72 is a 26 h positron emitter for which development of a 72 Se/ 72 As generator has been reported, potentially leading to portable availability of this PET radionuclide [2–6]. Arsenic-77 is a 38.8 h beta emitter that is reactor produced through neutron irradiation of enriched 76 GeO 2 followed by beta decay of 77 Ge (11.3 h).…”

Section: Introductionmentioning

confidence: 99%

Trithiols and their arsenic compounds for potential use in diagnostic and therapeutic radiopharmaceuticals

DeGraffenreid

Feng

Barnes

et al. 2016

Nuclear Medicine and Biology

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Introduction Arsenic-72 (72As; 2.49 MeV β+, 26 h) and 77As (0.683 MeV β−, 38.8 h) have nuclear properties useful for positron emission tomography (PET) and radiotherapy applications, respectively. Their half-lives are sufficiently long for targeting tumors with antibodies, as well as peptides. Potential radiopharmaceuticals based on radioarsenic require development of suitable bifunctional chelates for stable conjugation of arsenic to vectors under in vivo conditions at high dilution. Methods The thiophilic nature of arsenic led to the synthesis and characterization of a simple trithiol ligand and its arsenic complex, and radiolabeling studies at the no carrier added (NCA) 77 As level. Results 1H- and 13C-NMR spectroscopy, electrospray ionization mass spectrometry (ESI-MS), and single crystal X-ray diffraction were used to characterize the trithiol ligand and its arsenic(III) complex. Radiotracer studies with no carrier added (NCA) 77As resulted in high radiolabeling yields (>96%) with high in vitro stability. Conclusions The high yield and stability of a single NCA 77As trithiol complex indicates this framework is suitable for developing matched pair agents for non-invasive in vivo PET imaging and radiotherapy of tumors with 72,77As. This is the first reported chelate developed for NCA radioarsenic and studies are underway for developing a trithiol bifunctional chelate conjugated to a targeting vector, such as a peptide or monoclonal antibody.

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Section: Introductionmentioning

confidence: 99%

Trithiols and their arsenic compounds for potential use in diagnostic and therapeutic radiopharmaceuticals

DeGraffenreid

Feng

Barnes

et al. 2016

Nuclear Medicine and Biology

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“…There are many methods for the direct production of 72 As, however much more attention is paid to the generator 72 Se/ 72 As due to its convenient half-life of 8.4 d. Many practical extraction methods for this generator have already been reported (Al- Kouraishi and Boswell, 1978;Phillips et al, 1991;Jennewein et al, 2004Jennewein et al, , 2005Ballard et al, 2012Ballard et al, , 2012bChajduk et al, 2012;Wycoff et al, 2014;Feng et al, 2019). According to the literature, the best method for the production of 72 Se/ 72 As leads via 70 Ge( ⍺ ,2n) reaction (Amiel, 1959;Al-Kouraishi and Boswell, 1978;Calboreanu et al, 1987;Mushtaq and Qaim, 1990;Levkovskij, 1991;Jennewein et al, 2005;Szkliniarz et al, 2015;Takács et al, 2016;Feng et al, 2019).…”

Section: Asmentioning

confidence: 99%

Radionuclide candidates for β+γ coincidence PET: An overview

Sitarz

Cussonneau

Matulewicz

et al. 2020

Applied Radiation and Isotopes

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“…The radionuclide 72 As can be produced directly via various nuclear reactions; particularly noteworthy are the 72 Ge(p,n) 72 As and 72 Ge(d,2n) 72 As reactions at low‐energy cyclotrons. An alternative availability is the indirect way as a daughter radionuclide of the relatively long‐lived 72 Se using a generator system . Selenium‐72 can be produced via various charged particle reactions on Ge, Br, or As targets, the most common routes being the 70 Ge(α,2n) 72 Se or 75 As(p,4n) 72 Se reaction, which are feasible only at multiparticle and intermediate‐energy cyclotrons …”

Section: As and 74asmentioning

confidence: 99%

“…An alternative availability is the indirect way as a daughter radionuclide of the relatively long-lived 72 Se using a generator system. [92][93][94] Selenium-72 can be produced via various charged particle reactions on Ge, Br, or As targets, the most common routes being the 70 Ge(α,2n) 72 Se or 75 As(p,4n) 72 Se reaction, which are feasible only at multiparticle and intermediate-energy cyclotrons. 95,96 The production of 74 As can be realized best using the 74 Ge(p,n) 74 As or 73 Ge(d,n) 74 As reaction at a small-sized cyclotron.…”

Section: Nuclear Reactionmentioning

confidence: 99%

Labelling with positron emitters of pnicogens and chalcogens

Neumaier

2017

Labelled Comp Radiopharmac

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The increasing importance of the positron emission tomography (PET) in clinical diagnosis led to the development of a multitude of radiotracers labelled with positron‐emitting radionuclides of groups 15 (pnicogens) and 16 (chalcogens) of the periodic table of elements. The positron emitters of the endogenous occurring elements nitrogen, phosphorus, oxygen, and sulphur are characterized by very short half‐lives compared with the most commonly used PET radionuclides carbon‐11 or fluorine‐18. Therefore, the potential of their synthesis and possible applications in PET is challenging and limited. On the other hand, the nonstandard positron emitters arsenic‐72, arsenic‐74, and selenium‐73 have half‐lives in the range of hours to days and, thus, are of interest for PET studies of processes with long biological half‐lives, but novel methods have to be developed for their application, especially in the no‐carrier‐added state. This review summarizes recent research concerning the positron emitters of pnicogens and chalcogens for radiolabelling applications.

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Chromatographic separation of selenium and arsenic: A potential 72Se/72As generator

Cited by 21 publications

References 24 publications

Trithiols and their arsenic compounds for potential use in diagnostic and therapeutic radiopharmaceuticals

Trithiols and their arsenic compounds for potential use in diagnostic and therapeutic radiopharmaceuticals

Radionuclide candidates for β+γ coincidence PET: An overview

Labelling with positron emitters of pnicogens and chalcogens

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