The innovative <sup>52<i>g</i></sup>Mn for positron emission tomography (PET) imaging: Production cross section modeling and dosimetric evaluation

Barbaro, F.; Canton, L.; Carante, Mario Pietro; Colombi, A.; Nardo, L. De; Fontana, A.; Meléndez‐Alafort, Laura

doi:10.1002/mp.16130

Medical Physics

2022

DOI: 10.1002/mp.16130

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The innovative ^52gMn for positron emission tomography (PET) imaging: Production cross section modeling and dosimetric evaluation

F. Barbaro

L. Canton

Mario Pietro Carante

et al.

Abstract: Background: Manganese is a paramagnetic element suitable for magnetic resonance imaging (MRI) of neuronal function. However, high concentrations of Mn 2+ can be neurotoxic. 52g Mn may be a valid alternative as positron emission tomography (PET) imaging agent, to obtain information similar to that delivered by MRI but using trace levels of Mn 2+ , thus reducing its toxicity. Recently, the reaction nat V(𝛼,x) 52g Mn has been proposed as a possible alternative to the standard nat Cr(p,x) 52g Mn one, but improve… Show more

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Cited by 3 publications

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The LARAMED project at INFN-LNL: review of the research activities on medical radionuclides production with the SPES cyclotron

Pupillo,

Boschi,

Cisternino

et al. 2023

J Radioanal Nucl Chem

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The LARAMED project at INFN-LNL: review of the research activities on medical radionuclides production with the SPES cyclotron

Pupillo,

Boschi,

Cisternino

et al. 2023

J Radioanal Nucl Chem

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Cyclotron-based production of innovative medical radionuclides at the INFN-LNL: state of the art and perspective

Pupillo,

Andrighetto,

Arzenton

et al. 2023

Eur. Phys. J. Plus

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The production of medical radionuclides is one of the research activities carried out in the framework of the SPES (Selective Production of Exotic Species) project under the completion stage at the Legnaro National Laboratories of the National Institute for Nuclear Physics (INFN-LNL). The heart of SPES is the 70-MeV proton cyclotron having a dual-beam extraction, installed and commissioned in a new building equipped with ancillary laboratories currently under construction. The SPES main goal is the realization of an advanced ISOL (Isotope Separation On-Line) facility to produce re-accelerated exotic ion beams for fundamental nuclear physics studies. The cyclotron double-beam extraction system allows to simultaneously carry out applied research, such as radionuclides production for medicine (SPES-$$\gamma$$ γ ). This paper summarizes the results obtained with the interdisciplinary projects LARAMED (LAboratory of RAdionuclides for MEDicine) and ISOLPHARM (ISOL technique for radioPHARMaceuticals). The first one, based upon the direct activation method, is focused on the production of the radionuclides under the spotlight of the international community (e.g., $$^{99m}$$ 99 m Tc, $$^{67}$$ 67 Cu, $$^{52/51}$$ 52 / 51 Mn, $$^{47}$$ 47 Sc and Tb isotopes), from the nuclear cross-section measurements up to the preclinical studies. The other one exploits the ISOL technique for the development and production of radioisotopes with high-specific activity, such as $$^{111}$$ 111 Ag, going beyond the state of the art in the field. The most recent SPES-$$\gamma$$ γ research activities and future perspective are here described, characterized by a consolidated network of collaborations with national and international institutions.

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155Tb production by cyclotrons: what level of 155Gd enrichment allows clinical applications?

Barbaro,

Canton,

Uzunov

et al. 2024

EJNMMI Phys

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Background 155Tb represents a potentially useful radionuclide for diagnostic medical applications, but its production remains a challenging problem, in spite of the fact that many production routes have been already investigated and tested. A recent experimental campaign, conducted with low-energy proton beams impinging on a 155Gd target with 91.9% enrichment, demonstrated a significant co-production of 156gTb, a contaminant of great concern since its half-life is comparable to that of 155Tb and its high-energy γ emissions severely impact on the dose released and on the quality of the SPECT images. In the present investigation, the isotopic purity of the enriched 155Gd target necessary to minimize the co-production of contaminant radioisotopes, in particular 156gTb, was explored using various computational simulations. Results Starting from the recent experimental data obtained with a 91.9% 155Gd-enriched target, the co-production of other Tb radioisotopes besides 155Tb has been theoretically evaluated using the Talys code. It was found that 156Gd, with an isotopic content of 5.87%, was the principal contributor to the co-production of 156gTb. The analysis also demonstrated that the maximum amount of 156Gd admissible for 155Tb production with a radionuclidic purity higher than 99% was 1%. A less stringent condition was obtained through computational dosimetry analysis, suggesting that a 2% content of 156Gd in the target can be tolerated to limit the dose increase to the patient below the 10% limit. Moreover, it has been demonstrated that the imaging properties of the produced 155Tb are not severely affected by this level of impurity in the target. Conclusions 155Tb can be produced with a quality suitable for medical applications using low-energy proton beams and 155Gd-enriched targets, if the 156Gd impurity content does not exceed 2%. Under these conditions, the dose increase due to the presence of contaminant radioisotopes remains below the 10% limit and good quality images, comparable to those of 111In, are guaranteed.

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The innovative ^52gMn for positron emission tomography (PET) imaging: Production cross section modeling and dosimetric evaluation

Cited by 3 publications

References 56 publications

The LARAMED project at INFN-LNL: review of the research activities on medical radionuclides production with the SPES cyclotron

The LARAMED project at INFN-LNL: review of the research activities on medical radionuclides production with the SPES cyclotron

Cyclotron-based production of innovative medical radionuclides at the INFN-LNL: state of the art and perspective

155Tb production by cyclotrons: what level of 155Gd enrichment allows clinical applications?

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The innovative 52gMn for positron emission tomography (PET) imaging: Production cross section modeling and dosimetric evaluation

Cited by 3 publications

References 56 publications

The LARAMED project at INFN-LNL: review of the research activities on medical radionuclides production with the SPES cyclotron

The LARAMED project at INFN-LNL: review of the research activities on medical radionuclides production with the SPES cyclotron

Cyclotron-based production of innovative medical radionuclides at the INFN-LNL: state of the art and perspective

155Tb production by cyclotrons: what level of 155Gd enrichment allows clinical applications?

Contact Info

Product

Resources

About

The innovative ^52gMn for positron emission tomography (PET) imaging: Production cross section modeling and dosimetric evaluation