CERN-MEDICIS: A Review Since Commissioning in 2017

Duchemin, Charlotte; Ramos, J.P.; Stora, T.; Ahmed, E. E. M.; Aubert, Elodie; Audouin, Nadia; Barbero, E.; Barozier, Vincent; Bernardes, A. P.; Bertreix, Philippe; Boscher, A; Bruchertseifer, Frank; Catherall, R.; Chevallay, E.; Christodoulou, Pinelopi; Chrysalidis, K.; Cocolios, T. E.; Comte, Jeremie; Crepieux, B.; Deschamps, Matthieu; Dockx, Kristof; Dorsival, A.; Fedosseev, Valentin; Fernier, P.; Formento-Cavaier, R.; Idrissi, Safouane El; Ivanov, P.; Gadelshin, Vadim; Gilardoni, S.; Grenard, Jean-Louis; Haddad, Férid; Heinke, Reinhard; Juif, B.; Khalid, Umair; Khan, Moazam; Köster, U.; Lambert, Laura; Lilli, G.; Lunghi, Giacomo; Marsh, B. A.; Palenzuela, Y. Martinez; Martins, Renata; Marzari, S.; Menaa, N.; Michel, Nathalie; Munos, M.; Pozzi, Fabio; Riccardi, Francesco; Riegert, J.; Riggaz, Nicolas; Rinchet, Jean-Yves; Rothe, S.; Russell, Ben; Saury, Christelle; Schneider, Thomas; Stegemann, S.; Talip, Zeynep; Theis, Christian; Thiboud, J.; Meulen, Nicholas P. van der; Stenis, M. van; Vincke, Heinz; Vollaire, J.; Vuong, Nhat-Tan; Webster, B.; Wendt, K.; Wilkins, S. G.

doi:10.3389/fmed.2021.693682

Cited by 24 publications

(15 citation statements)

References 23 publications

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“…Figure 6B shows the activity at the implantation point for each of the foils from in-situ measurements, determined by the difference between the readout at a given point in time and the background value at the time when this foil was moved into the beam. In previous MEDICIS runs with different elements (from a few up to more than 100 MBq of 153 Sm, 155 Tb, 225 Ac) on identical collection foils ( 34 ), this value proved to be a reliable estimate for the gamma-spectrometry measurements that are performed on the foils afterwards by independent measurements in a dedicated, external setup. Yet, for the presented case this value obtained after recuperation of the foil, shown as star marker in Figure 6B with a 95% confidence interval error band, was significantly lower.…”

Section: Resultsmentioning

confidence: 82%

“…The CERN-MEDICIS (MEDical Isotopes Collected from ISolde) facility is dedicated to the production of non-conventional radionuclides for medical purposes ( 32 – 34 ). As schematically shown in Figure 1 , it comprises a 60 kV ion beam dipole sector field magnet mass separator, that uses either targets that are irradiated in a dedicated irradiation station at the adjacent CERN-ISOLDE radioactive ion beam facility ( 33 ) by a 1.4 GeV proton beam or, alternatively, radiogenic samples produced and delivered by partner institutes.…”

Section: Experimental Setup and Methodsmentioning

confidence: 99%

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Efficient Production of High Specific Activity Thulium-167 at Paul Scherrer Institute and CERN-MEDICIS

et al. 2021

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Thulium-167 is a promising radionuclide for nuclear medicine applications with potential use for both diagnosis and therapy (“theragnostics”) in disseminated tumor cells and small metastases, due to suitable gamma-line as well as conversion/Auger electron energies. However, adequate delivery methods are yet to be developed and accompanying radiobiological effects to be investigated, demanding the availability of 167Tm in appropriate activities and quality. We report herein on the production of radionuclidically pure 167Tm from proton-irradiated natural erbium oxide targets at a cyclotron and subsequent ion beam mass separation at the CERN-MEDICIS facility, with a particular focus on the process efficiency. Development of the mass separation process with studies on stable 169Tm yielded 65 and 60% for pure and erbium-excess samples. An enhancement factor of thulium ion beam over that of erbium of up to several 104 was shown by utilizing laser resonance ionization and exploiting differences in their vapor pressures. Three 167Tm samples produced at the IP2 irradiation station, receiving 22.8 MeV protons from Injector II at Paul Scherrer Institute (PSI), were mass separated with collected radionuclide efficiencies between 11 and 20%. Ion beam sputtering from the collection foils was identified as a limiting factor. In-situ gamma-measurements showed that up to 45% separation efficiency could be fully collected if these limits are overcome. Comparative analyses show possible neighboring mass suppression factors of more than 1,000, and overall 167Tm/Er purity increase in the same range. Both the actual achieved collection and separation efficiencies present the highest values for the mass separation of external radionuclide sources at MEDICIS to date.

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Section: Resultsmentioning

confidence: 82%

Section: Experimental Setup and Methodsmentioning

confidence: 99%

Efficient Production of High Specific Activity Thulium-167 at Paul Scherrer Institute and CERN-MEDICIS

et al. 2021

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“…The obtained value of 53% ionization efficiency is comparable with previous studies of laser ionization on other lanthanides ( 23 , 35 ). This ionization scheme is currently in use at the CERN-MEDICIS facility to increase the production rate of Tb medical radioisotopes [the efficiency of surface ion source in case of Tb separation is estimated to be about 2% ( 2 )].…”

Section: Discussionmentioning

confidence: 99%

“…The novel CERN-MEDICIS facility aims for the production of non-conventional medical radioisotopes, being previously unavailable on the global market for biomedical research and development ( 1 , 2 ). It is based on the use of electromagnetic mass separation for extraction of a desired radionuclide from a pre-irradiated target material ( 3 ).…”

Section: Introductionmentioning

confidence: 99%

Terbium Medical Radioisotope Production: Laser Resonance Ionization Scheme Development

et al. 2021

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Terbium (Tb) is a promising element for the theranostic approach in nuclear medicine. The new CERN-MEDICIS facility aims for production of its medical radioisotopes to support related R&D projects in biomedicine. The use of laser resonance ionization is essential to provide radioisotopic yields of highest quantity and quality, specifically regarding purity. This paper presents the results of preparation and characterization of a suitable two-step laser resonance ionization process for Tb. By resonance excitation via an auto-ionizing level, the high ionization efficiency of 53% was achieved. To simulate realistic production conditions for Tb radioisotopes, the influence of a surplus of Gd atoms, which is a typical target material for Tb generation, was considered, showing the necessity of radiochemical purification procedures before mass separation. Nevertheless, a 10-fold enhancement of the Tb ion beam using laser resonance ionization was observed even with Gd:Tb atomic ratio of 100:1.

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“…The targets are heated to very high temperatures, typically up to 2,300 • C depending on the target material and radionuclide considered, to allow for the diffusion and effusion of the isotopes of interest out of the target to the ion source for subsequent ionization. The ions are then accelerated and sent through a mass separator which is a dipole magnet (24). The dipole magnet has been modified to allow its use with the MEDICIS Laser Ion Source for Separator Assembly (MELISSA) laser laboratory (25), resembling the Ti:sapphire laser setup of the ISOLDE Resonance Ionization Laser Ion Source (RILIS) (26).…”

Section: Off-line Mass Separation Of 153 Smmentioning

confidence: 99%

Production of Sm-153 With Very High Specific Activity for Targeted Radionuclide Therapy

et al. 2021

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Samarium-153 (153Sm) is a highly interesting radionuclide within the field of targeted radionuclide therapy because of its favorable decay characteristics. 153Sm has a half-life of 1.93 d and decays into a stable daughter nuclide (153Eu) whereupon β− particles [E = 705 keV (30%), 635 keV (50%)] are emitted which are suitable for therapy. 153Sm also emits γ photons [103 keV (28%)] allowing for SPECT imaging, which is of value in theranostics. However, the full potential of 153Sm in nuclear medicine is currently not being exploited because of the radionuclide's limited specific activity due to its carrier added production route. In this work a new production method was developed to produce 153Sm with higher specific activity, allowing for its potential use in targeted radionuclide therapy. 153Sm was efficiently produced via neutron irradiation of a highly enriched 152Sm target (98.7% enriched, σth = 206 b) in the BR2 reactor at SCK CEN. Irradiated target materials were shipped to CERN-MEDICIS, where 153Sm was isolated from the 152Sm target via mass separation (MS) in combination with laser resonance enhanced ionization to drastically increase the specific activity. The specific activity obtained was 1.87 TBq/mg (≈ 265 times higher after the end of irradiation in BR2 + cooling). An overall mass separation efficiency of 4.5% was reached on average for all mass separations. Further radiochemical purification steps were developed at SCK CEN to recover the 153Sm from the MS target to yield a solution ready for radiolabeling. Each step of the radiochemical process was fully analyzed and characterized for further optimization resulting in a high efficiency (overall recovery: 84%). The obtained high specific activity (HSA) 153Sm was then used in radiolabeling experiments with different concentrations of 4-isothiocyanatobenzyl-1,4,7,10-tetraazacyclododecane tetraacetic acid (p-SCN-Bn-DOTA). Even at low concentrations of p-SCN-Bn-DOTA, radiolabeling of 0.5 MBq of HSA 153Sm was found to be efficient. In this proof-of-concept study, we demonstrated the potential to combine neutron irradiation with mass separation to supply high specific activity 153Sm. Using this process, 153SmCl3 suitable for radiolabeling, was produced with a very high specific activity allowing application of 153Sm in targeted radionuclide therapy. Further studies to incorporate 153Sm in radiopharmaceuticals for targeted radionuclide therapy are ongoing.

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CERN-MEDICIS: A Review Since Commissioning in 2017

Cited by 24 publications

References 23 publications

Efficient Production of High Specific Activity Thulium-167 at Paul Scherrer Institute and CERN-MEDICIS

Efficient Production of High Specific Activity Thulium-167 at Paul Scherrer Institute and CERN-MEDICIS

Terbium Medical Radioisotope Production: Laser Resonance Ionization Scheme Development

Production of Sm-153 With Very High Specific Activity for Targeted Radionuclide Therapy

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