Production of Scandium Radioisotopes: History
Please note this is an old version of this entry, which may differ significantly from the current revision.

The concept of theranostics is based on the use of radioisotopes of the same or chemically similar elements to label biological ligands in a way that allows the use of diagnostic and therapeutic radiation for a combined diagnosis and treatment regimen.

  • theranostics
  • scandium radioisotopes
  • radiolabeling
  • radiopharmaceuticals

1. Introduction

The development of technologies related to nuclear medicine requires providing new solutions in the field of imaging and the production of radioisotopes that can perform specific functions. One of them is the concept of personalized medicine, where the treatment process is matched based on individual screening of tumor phenotypes [1]. In this approach, dedicated compounds with a high affinity for cancer cells are designed based on test results [2]. These compounds can be labeled with diagnostic or therapeutic radioisotopes to obtain information about the development and progression of the disease or the implementation of a therapeutic process [3].
The concept of theranostics is based on the use of radioisotopes of the same or chemically similar elements to label biological ligands in a way that allows the use of diagnostic and therapeutic radiation for a combined diagnosis and treatment regimen. Despite several theranostic pairs being present in clinical practice, theranostic pairs based on the same element are relatively rare [4]. However, when using radionuclides of two different elements, differences in the pharmacokinetic and pharmacodynamic profile could be observed. For scandium, the radioisotopes -43 and -44 can be used as diagnostic markers, while radioisotope scandium-47 can be used in the same configuration for targeted therapy [5]; therefore, theranostic agents that incorporate the matched-pair radionuclides of scandium-43/scandium-47 or scandium-44/scandium-47 would guarantee identical chemistries and pharmacologic profiles.
Another interesting property of the scandium-44 radioisotope is the relatively rare decay consisting of the co-emission of a positron and a gamma quantum. This feature was used in the development and validation of diagnostic methods that, to refine the imaging, use the detection of two gamma quanta originating from positron annihilation in the coincidence mode, supported by the detection of a single gamma quantum, the so-called 3γ positron emission tomography (PET). The work in [6] supports improvement in the resolution and imaging characteristics of PET.

2. Scandium Radioisotopes

The chemical properties of scandium are similar to the group of lanthanides, while its ionic radius in the range of about 68–74 pm classifies it among the elements with chemical properties most similar to yttrium. In macrocyclic systems, Sc has a coordination number from three to nine and due to its similarity to other M3+ radiometals, such as gallium, yttrium, and lutetium, forms complexes with ligands by connecting through oxygen, nitrogen, and halogen. Acid–base equilibria strongly influence the chemical form in which scandium occurs in aqueous solutions. The distribution of individual chemical forms of scandium indicates that, at pH < 4, the hydrated Sc3+ cation is the dominant form. Due to the ease of forming hydroxy complexes together with increasing pH, ScOH2+ and Sc(OH)2+ ions appear in the solution. At a pH value around 4, gradual precipitation of Sc(OH)3 begins, but other ions present in the solution can influence scandium solubility: acetates increase the solubility, while phosphates reduce via coprecipitation of ScPO4 [7]. Depending on the source of literature data, the solubility constant (Ksp) ranges from 10−29 to 10−33 and could be used for selective separation of Sc via precipitation [8][9].
Naturally occurring scandium is composed of one stable isotope: scandium-45 [10]. Other scandium radioisotopes are characterized by short half-lives, with only five having half-lives exceeding seconds. Among these five, scandium-43, scandium-44, scandium-47, and scandium-48 exhibit favorable emission profiles for radiopharmaceutical applications. The last of the relatively stable scandium radioisotopes, scandium-46, is a low-energy beta emitter with a half-life of 83.8 days and is complementarily used in basic research. Specifically, scandium-47 and scandium-48 are β emitters with a half-life of 3.3492 days and 43.67 h, while scandium-43 and scandium-44 are positron emitters with half-lives of 3.891 h and 4.0421 h, respectively [10]. These radioisotopes have shown promising prospects for theranostic systems and may be effectively employed in diagnostic and therapeutic procedures in the realm of nuclear medicine.

3. Production of Scandium Radioisotopes

Due to their properties, scandium radioisotopes can be produced in different ways: using cyclotrons, accelerators, or reactors. In the case of cyclotron production, it is possible to use standard proton or deuteron beams with moderate energies available in medical cyclotrons (p,d, 10–20 MeV per particle) or cyclotrons providing α beams.
The starting elements for the production of scandium are calcium, scandium, titanium, and vanadium isotopes. Three of them in their natural form have a promising property, i.e., a very significant dominance of one of the isotopes: natural calcium contains 96.9% calcium-40, natural scandium contains 100% scandium-45, and vanadium is composed of 99.75% vanadium-51. This makes it possible to irradiate naturally occurring materials, which increases availability and reduces costs (see Table 1). The abundance of titanium isotopes is less favorable, where 73.7% is titanium-48, 8.25% titanium-46, 7.4% titanium-47, and just over 5% are isotopes of titanium-49 and -50. Therefore, it is necessary to use separated isotopes enriched in a specific isotope as target materials. This causes a significant increase in target costs (tens or hundreds of EUR/mg) and difficulties in obtaining appropriately enriched separated isotopes. Another issue is the need to reuse the target material; thus, the target processing has to include a recovery step and not introduce any additional impurities. Examples of production methods are presented in Table 1.
Table 1. Production of scandium radioisotopes.
Another potentially attractive pathway for the production of scandium radioisotopes is production from a generator by the decay of the parent radionuclide, which is immobilized on the solid phase and then selectively eluted on the scandium radioisotope. It replicates the concepts of technetium-99 m and gallium-68 generators commonly and successfully introduced in nuclear medicine, significantly facilitating the availability of radioisotopes in clinical applications [22]. Scandium-44 is produced as a decay product of titanium-44 formed in the reaction 45Sc(p,2n)44Ti, while scandium-47 is a decay product of calcium-47 produced in 46Ca (n,γ)47Ca or 48Ca(γ,n)47Ca reactions. The status of generator systems for scandium-44 was recently reviewed [22]. In its current state, the concept is very interesting, but it has not been possible to create a generator that would provide enough activity for clinical applications. The first solutions [23] offered 185 MBq of activity suitable for simple preclinical studies, but the eluate required an additional purification step for effective labeling [24]. However, the availability of scandium-44 from the generator enabled a significant development of preclinical work aimed at searching for appropriate macrocyclic ligands for scandium [25]. Work is being carried out to increase the efficiency of the 44Ti/44Sc generators, significantly increasing the quality of the eluate [26][27][28][29], but at present no generator solution has been presented that could routinely and commonly provide access to the radioisotope similar to technetium or gallium generators.
The idea supporting the development of scandium generators is proof of the concept of the 47Ca/47Sc generator, which would supplement the theranostic pair with a therapeutic radioisotope from the generator. One approach is to irradiate 46Ca (n,γ)47Ca- > 47Sc. Although the cross-section of this reaction is 740 mb, which is promising, the natural abundance of calcium-46 (0.004%) and low enrichment (~30% 46Ca) combined with the ~4000 EUR/mg price of enriched material make this technology extremely expensive. Chemical isolation of scandium-47 from the target material enabled the formulation of up to 1.5 GBq of scandium-47 with high radionuclidic purity (>99.99%) in a small volume (~700 μL) [21]. Another approach is production via photonuclear reaction 48Ca(γ,n)47Ca- > 47Sc, but the effects of irradiation of the natCaCl2 target reached only 1–1.5 MBq of scandium-47 in eluate [30]. Using an enriched calcium-48 target increases results up to tens of MBq activity of scandium-47 [31]. The potential drawback is the relatively short half-life of the produced calcium-47 (T1/2 = 4.5 d), resulting in a 10–15-day shelf life of the generator, which poses challenges similar to the logistics of technetium generators.
The possibility of creating complementary 44Ti/44Sc diagnostic and 47Ca/47Sc therapeutic generators would be an ideal solution from the point of view of clinical theranostics, but this vision is quite distant yet.
In conclusion, the comparison of scandium radioisotope production methods reveals a wide range of techniques and available hardware platforms. However, a notable challenge lies in the mismatch between cost-effective and readily available target materials, which demand specialized and less common irradiation systems. Conversely, the more widely used irradiation systems necessitate separated materials and, in certain cases, the production conditions for specific radioisotopes are at the limits of the hardware capabilities.

This entry is adapted from the peer-reviewed paper 10.3390/molecules28227668

References

  1. Dugger, S.A.; Platt, A.; Goldstein, D.B. Drug Development in the Era of Precision Medicine. Nat. Rev. Drug Discov. 2018, 17, 183–196.
  2. Refardt, J.; Hofland, J.; Kwadwo, A.; Nicolas, G.P.; Rottenburger, C.; Fani, M.; Wild, D.; Christ, E. Theranostics in neuroendocrine tumors: An overview of current approaches and future challenges. Rev. Endocr. Metab. Disord. 2021, 22, 581–594.
  3. Roesch, F.; Martin, M. Radiometal-theranostics: The first 20 years. J. Radioanal. Nucl. Chem. 2023, 332, 1557–1576.
  4. Duan, H.; Iagaru, A.; Aparici, C.M. Radiotheranostics—Precision Medicine in Nuclear Medicine and Molecular Imaging. Nanotheranostics 2022, 6, 103–117.
  5. Mikolajczak, R.; Huclier-Markai, S.; Alliot, C.; Haddad, F.; Szikra, D.; Forgacs, V.; Garnuszek, P. Production of scandium radionuclides for theranostic applications: Towards standardization of quality requirements. EJNMMI Radiopharm. Chem. 2021, 6, 19.
  6. Sitarz, M.; Cussonneau, J.-P.; Matulewicz, T.; Haddad, F. Radionuclide candidates for β+γ coincidence PET: An overview. Appl. Radiat. Isot. 2020, 155, 108898.
  7. Kilian, K.; Pyrzyńska, K.; Pęgier, M. Comparative Study of Sc(III) Sorption onto Carbon-based Materials. Solvent Extr. Ion Exch. 2017, 35, 450–459.
  8. Wood, S.A.; Samson, I.M. The aqueous geochemistry of gallium, germanium, indium and scandium. Ore Geol. Rev. 2006, 28, 57–102.
  9. Feitknecht, W.; Schindler, P. Solubility constants of metal oxides, metal hydroxides and metal hydroxide salts in aqueous solution. Pure Appl. Chem. 1963, 6, 125–206.
  10. Kondev, F.G.; Wang, M.; Huang, W.J.; Naimi, S.; Audi, G. The NUBASE2020 evaluation of nuclear physics properties. Chin. Phys. C 2021, 45, 030001.
  11. Szkliniarz, K.; Sitarz, M.; Walczak, R.; Jastrzębski, J.; Bilewicz, A.; Choiński, J.; Jakubowski, A.; Majkowska, A.; Stolarz, A.; Trzcińska, A.; et al. Production of medical Sc radioisotopes with an α particle beam. Appl. Radiat. Isot. 2016, 118, 182–189.
  12. Minegishi, K.; Nagatsu, K.; Fukada, M.; Suzuki, H.; Ohya, T.; Zhang, M.-R. Production of scandium-43 and -47 from a powdery calcium oxide target via the nat/44Ca(α,x)-channel. Appl. Radiat. Isot. 2016, 116, 8–12.
  13. Chakravarty, R.; Banerjee, D.; Chakraborty, S. Alpha-induced production and robust radiochemical separation of 43Sc as an emerging radiometal for formulation of PET radiopharmaceuticals. Appl. Radiat. Isot. 2023, 199, 110921.
  14. Lowis, C.; Ferguson, S.; Paulßen, E.; Hoehr, C. Improved Sc-44 production in a siphon-style liquid target on a medical cyclotron. Appl. Radiat. Isot. 2021, 172, 109675.
  15. Kurakina, E.S.; Wharton, L.; Hoehr, C.; Orving, C.; Magomedbekov, E.P.; Filosofov, D.; Radchenko, V. Improved separation scheme for 44Sc produced by irradiation of natCa targets with 12.8 MeV protons. Nucl. Med. Biol. 2022, 104–105, 22–27.
  16. Filosofov, D.V.; Loktionova, N.S.; Rösch, F. A 44Ti/44Sc radionuclide generator for potential application of 44Sc-based PET-radiopharmaceuticals. Radiochim. Acta 2010, 98, 149–156.
  17. Pupillo, G.; Mou, L.; Boschi, A.; Calzaferri, S.; Canton, L.; Cisternino, S.; De Dominicis, L.; Duatti, A.; Fontana, A.; Haddad, F.; et al. Production of 47Sc with natural vanadium targets: Results of the PASTA project. J. Radioanal. Nucl. Chem. 2019, 322, 1711–1718.
  18. Snow, M.S.; Foley, A.; Ward, J.L.; Kinlaw, M.T.; Stoner, J.; Carney, K.P. High purity 47Sc production using high-energy photons and natural vanadium targets. Appl. Radiat. Isot. 2021, 178, 109934.
  19. Domnanich, A.; Eicher, R.; Mueller, C.; Jordi, S.; Yakusheva, V.; Braccini, S.; Behe, M.; Schibli, R.; van der Meulen, N.P. Production and separation of 43Sc for radiopharmaceutical purposes. EJNMMI Radiopharm. Chem. 2017, 2, 14.
  20. Becker, K.V.; Aluicio-Sarduy, E.; Bradshaw, T.; Hurley, S.A.; Olson, A.P.; Barrett, K.E.; Batterton, J.; Ellison, P.A.; Barnhart, T.E.; Pirasteh, A.; et al. Cyclotron production of 43Sc and 44gSc from enriched 42CaO, 43CaO, and 44CaO targets. Front. Chem. 2023, 11, 1167783.
  21. Domnanich, K.A.; Müller, C.; Benešová, M.; Dressler, R.; Haller, S.; Köster, U.; Ponsard, B.; Schibli, R.; Türler, A.; van der Meulen, N.P. 47Sc as useful β–-emitter for the radiotheragnostic paradigm: A comparative study of feasible production routes. EJNMMI Radiopharm. Chem. 2017, 2, 5.
  22. Schmidt, C.E.; Gajecki, L.; Deri, M.A.; Sanders, V.A. Current State of 44Ti/44Sc Radionuclide Generator Systems and Separation Chemistry. Curr. Radiopharm. 2023, 16, 95–106.
  23. Pruszyński, M.; Loktionova, N.; Filosofov, D.; Rösch, F. Post-elution processing of 44Ti/44Sc generator-derived 44Sc for clinical application. Appl. Radiat. Isot. 2010, 68, 1636–1641.
  24. Majkowska-Pilip, A.; Bilewicz, A. Macrocyclic complexes of scandium radionuclides as precursors for diagnostic and therapeutic radiopharmaceuticals. J. Inorg. Biochem. 2011, 105, 313–320.
  25. Radchenko, V.; Meyer, C.; Engle, J.; Naranjo, C.; Unc, G.; Mastren, T.; Brugh, M.; Birnbaum, E.; John, K.; Nortier, F.; et al. Separation of 44Ti from proton irradiated scandium by using solid-phase extraction chromatography and design of 44Ti/44Sc generator system. J. Chromatogr. A 2016, 1477, 39–46.
  26. Radchenko, V.; Engle, J.W.; Medvedev, D.G.; Maassen, J.M.; Naranjo, C.M.; Unc, G.A.; Meyer, C.A.; Mastren, T.; Brugh, M.; Mausner, L.; et al. Proton-induced production and radiochemical isolation of 44Ti from scandium metal targets for 44Ti/44Sc generator development. Nucl. Med. Biol. 2017, 50, 25–32.
  27. Larenkov, A.A.; Makichyan, A.G.; Iatsenko, V.N. Separation of 44Sc from 44Ti in the context of a generator system for radiopharmaceutical purposes with the example of Sc-PSMA-617 and Sc-PSMA-I&T synthesis. Molecules 2021, 26, 6371.
  28. Benabdallah, N.; Zhang, H.; Unnerstall, R.; Fears, A.; Summer, L.; Fassbender, M.; Rodgers, B.E.; Abou, D.; Radchenko, V.; Thorek, D.L.J. Engineering a modular 44Ti/44Sc generator: Eluate evaluation in preclinical models and estimation of human radiation dosimetry. EJNMMI Res. 2023, 13, 6371.
  29. Gajecki, L.; Marino, C.M.; Cutler, C.S.; Sanders, V.A. Evaluation of hydroxamate-based resins towards a more clinically viable 44Ti/44Sc radionuclide generator. Appl. Radiat. Isot. 2023, 192, 110588.
  30. Kankanamalage, P.H.; Brossard, T.; Song, J.; Nolen, J.; Rotsch, D.A. Photonuclear production of 47Ca for 47Ca/47Sc generator from natural CaCO3 targets. Appl. Radiat. Isot. 2023, 200, 110943.
  31. Rane, S.; Harris, J.T.; Starovoitova, V.N. 47Ca production for 47Ca/47Sc generator system using electron linacs. Appl. Radiat. Isot. 2015, 97, 188–192.
More
This entry is offline, you can click here to edit this entry!
ScholarVision Creations