Separation and purification of no-carrier-added arsenic from bulk amounts of germanium for use in radiopharmaceutical labelling

Jahn, Markus; Radchenko, Valery; Filosofov, D.V.; Hauser, Harald; Eisenhut, Michael; Rösch, Frank; Jennewein, M.

doi:10.1524/ract.2010.1783

Cited by 29 publications

(41 citation statements)

References 38 publications

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“…The reduction and SPE procedures detailed in this manuscript were adapted from Jahn et al 19 and Jennewein et al, 13 respectively. The result is significantly more automatable and resulted in less radiation worker dose exposure compared with the liquid-phase solvent extraction procedure adapted from Jahn et al 19 and Shehata et al 14 The conditions utilized in this work resulted in reasonable yields of 72 As in a small volume of buffered eluant, with (57 ± 5)% yield in the first 300 μ L of 1 M HEPES.…”

Section: Resultsmentioning

confidence: 99%

High Yield Production and Radiochemical Isolation of Isotopically Pure Arsenic-72 and Novel Radioarsenic Labeling Strategies for the Development of Theranostic Radiopharmaceuticals

Ellison¹,

Barnhart²,

Chen³

et al. 2015

Bioconjugate Chem.

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Radioisotopes of arsenic are of considerable interest to the field of nuclear medicine with unique nuclear and chemical properties making them well-suited for use in novel theranostic radiopharmaceuticals. However, progress must still be made in the production of isotopically pure radioarsenic and in its stable conjugation to biological targeting vectors. This work presents the production and irradiation of isotopically enriched 72Ge(m) discs in an irrigation-cooled target system allowing for the production of isotopically pure 72As with capability on the order of 10 GBq. A radiochemical separation procedure isolated the reactive trivalent radioarsenic in a small volume buffered aqueous solution, while reclaiming 72Ge target material. The direct thiol-labeling of a monoclonal antibody resulted in a conjugate exhibiting exceptionally poor in vivo stability in a mouse model. This prompted further investigations to alternative radioarsenic labeling strategies, including the labeling of the dithiol-containing chelator dihydrolipoic acid, and thiol-modified mesoporous silica nanoparticles (MSN-SH). Radioarsenic-labeled MSN-SH showed exceptional in vivo stability toward dearsenylation.

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Section: Resultsmentioning

confidence: 99%

High Yield Production and Radiochemical Isolation of Isotopically Pure Arsenic-72 and Novel Radioarsenic Labeling Strategies for the Development of Theranostic Radiopharmaceuticals

Ellison¹,

Barnhart²,

Chen³

et al. 2015

Bioconjugate Chem.

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“…Many methods to isolate As from Ge have been reported including solvent extraction [5, 6], distillation [7, 8], ion exchange [8-10], solid phase extraction [11-13], and thin layer chromatography [14]. The solvent extraction methods reported often involve several labor intensive steps, including back extractions, and are not readily adapted for high activity separations requiring remote handling.…”

Section: Introductionmentioning

confidence: 99%

“…The solvent extraction methods reported often involve several labor intensive steps, including back extractions, and are not readily adapted for high activity separations requiring remote handling. Distillation methods require heating, some to high temperature (1105 °C [7]), which increases sample processing time and may require further radioarsenic purification [8]. Chromatographic methods involving ion exchange or solid phase adsorption provide an efficient, robust purification method more readily adapted to automated, remote handling required with high levels of radioactivity.…”

Section: Introductionmentioning

confidence: 99%

“…Chromatographic methods involving ion exchange or solid phase adsorption provide an efficient, robust purification method more readily adapted to automated, remote handling required with high levels of radioactivity. Many of the current literature methods involve the use of strong acids (e.g., >8 M HNO 3 , HF, HCl) in the separation process, which are undesirable for radionuclides that will be used for synthesizing radiopharmaceuticals [8-12]. Chakravarty [13] reported a two-column separation for high purity radioarsenic from a GeO 2 target using nanocrystalline titania.…”

Section: Introductionmentioning

confidence: 99%

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Chromatographic separation of germanium and arsenic for the production of high purity 77As

Gott

DeGraffenreid

Feng

et al. 2016

Journal of Chromatography A

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A simple column chromatographic method was developed to isolate 77As (94 ± 6% (EtOH/HCl); 74 ± 11 (MeOH)) from germanium for potential use in radioimmunotherapy. The separation of arsenic from germanium was based on their relative affinities for different chromatographic materials in aqueous and organic environments. Using an organic or mixed mobile phase, germanium was selectively retained on a silica gel column as germanate, while arsenic was eluted from the column as arsenate. Subsequently, enriched 76Ge (98 ± 2) was recovered for reuse by elution with aqueous solution (neutral to basic). Greater than 98% radiolabeling yield of a 77As-trithiol was observed from methanol separated [77As]arsenate [17].

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“…This requires efficient radiochemical separation of 77 As from large amounts of Ge target material. In the past few years, there have been considerable efforts towards development of effective separation techniques involving distillation, co-precipitation, solvent extraction, thin layer chromatography, etc., for the isolation of 77 As from cyclotron or reactor irradiated germanium or germanium oxide targets [13][14][15][16][17][18][19][20][21][22][23].…”

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confidence: 99%

Polymer Embedded Nanocrystalline Titania: A New Generation Sorbent for the Separation of 77As from Ge for Biomedical Applications

et al. 2011

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The present work demonstrates the utility of polymer embedded nanocrystalline titania (TiP) as a new, accessible and viable solid sorbent for the chromatographic separation of high specific activity 77 As from neutron irradiated natural GeO 2 . Experimental parameters such as distribution ratios (K d ), equilibrium sorption capacity, breakthrough capacity and separation yields were determined. A two-step ion-exchange procedure was developed to avail 77 As, from irradiated Ge in alkaline medium. The first step involved removal of the bulk Ge from 77 As by selective sorption of Ge ions on a TiP column at pH 13. Subsequently, the effluent solution containing 77 As was further purified and concentrated by sorption on a small TiP column at pH 10. 77 As could be eluted from the second column in 2-3 mL of 0.1 M NaOH solution with[80% radiochemical yield. The 77 As obtained by this method was found to have insignificantly small level of radiocontaminants.

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Separation and purification of no-carrier-added arsenic from bulk amounts of germanium for use in radiopharmaceutical labelling

Cited by 29 publications

References 38 publications

High Yield Production and Radiochemical Isolation of Isotopically Pure Arsenic-72 and Novel Radioarsenic Labeling Strategies for the Development of Theranostic Radiopharmaceuticals

High Yield Production and Radiochemical Isolation of Isotopically Pure Arsenic-72 and Novel Radioarsenic Labeling Strategies for the Development of Theranostic Radiopharmaceuticals

Chromatographic separation of germanium and arsenic for the production of high purity 77As

Polymer Embedded Nanocrystalline Titania: A New Generation Sorbent for the Separation of 77As from Ge for Biomedical Applications

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