Preparation of nanodiamond conjugates with scandium isotopes for use in nuclear medicine

Cover Page

Cite item

Full Text

Open Access Open Access
Restricted Access Access granted
Restricted Access Subscription Access

Abstract

In this work, we studied the sorption of scandium, whose isotopes 44Sc and 47Sc are studied for diagnostics and therapy in nuclear medicine, by aggregates of commercial (TAN, STP) and oxidized ND nanodiamonds (ox-STP) from aqueous solutions. The sorption capacity of the studied NDs for scandium was determined; it was shown that 100 μg of NDs is sufficient for the sorption of 1 GBq of 47Sc, which is equivalent to the activity of isotopes used in therapy. It has been shown that the supposed mechanism for the binding of Sc(III) to ND aggregates is chemisorption, and the chemical composition of the ND surface affects the sorption efficiency to a greater extent than the forms of scandium in solution. The obtained data on Sc(III) sorption are compared with the sizes of ND aggregates; it is shown that sorption under experimental conditions does not depend on the size of the aggregates. Optimal carriers of the 47Sc isotope have been found for further studies of radiopharmaceuticals based on it – TAN and ox-STP.

Full Text

Restricted Access

About the authors

A. G. Kazakov

Vernadsky Institute of Geochemistry and Analytical Chemistry, Russian Academy of Sciences

Author for correspondence.
Email: adeptak92@mail.ru
Russian Federation, Moscow

T. Y. Ekatova

Vernadsky Institute of Geochemistry and Analytical Chemistry, Russian Academy of Sciences

Email: adeptak92@mail.ru
Russian Federation, Moscow

S. E. Vinokurov

Vernadsky Institute of Geochemistry and Analytical Chemistry, Russian Academy of Sciences

Email: adeptak92@mail.ru
Russian Federation, Moscow

E. Y. Khvorostinin

Vernadsky Institute of Geochemistry and Analytical Chemistry, Russian Academy of Sciences

Email: adeptak92@mail.ru
Russian Federation, Moscow

I. A. Ushakov

National Research Tomsk Polytechnic University

Email: adeptak92@mail.ru
Russian Federation, Tomsk

V. V. Zukau

National Research Tomsk Polytechnic University

Email: adeptak92@mail.ru
Russian Federation, Tomsk

E. S. Stasyuk

National Research Tomsk Polytechnic University

Email: adeptak92@mail.ru
Russian Federation, Tomsk

E. A. Nesterov

National Research Tomsk Polytechnic University

Email: adeptak92@mail.ru
Russian Federation, Tomsk

V. L. Sadkin

National Research Tomsk Polytechnic University

Email: adeptak92@mail.ru
Russian Federation, Tomsk

A. S. Rogov

National Research Tomsk Polytechnic University

Email: adeptak92@mail.ru
Russian Federation, Tomsk

B. F. Myasoedov

Vernadsky Institute of Geochemistry and Analytical Chemistry, Russian Academy of Sciences; Interdepartmental Center for Analytical Research in Physics, Chemistry and Biology, Russian Academy of Sciences

Email: adeptak92@mail.ru
Russian Federation, Moscow; Moscow

References

  1. Phua V.J.X., Yang C.-T., Xia B., Yan S.X., Liu J., Aw S.E. et al. // Nanomaterials. 2022. Vol. 12. N 4. Article 582.
  2. Islam W., Niidome T., Sawa T. // JPM. 2022. Vol. 12. N 12. Article 1964.
  3. Peltek O.O., Muslimov A.R., Zyuzin M.V., Timin A.S. // J Nanobiotechnol. 2019. Vol. 17. N. 1. P. 90.
  4. Xu J., Chow E.K.-H. // SLAS Technol. 2023. Vol. 28. N. 4. P. 214–222.
  5. Turcheniuk K., Mochalin V.N. // Nanotechnology. 2017. Vol. 28. N 25. Article 252001.
  6. Ali M.S., Metwally A.A., Fahmy R.H., Osman R. // Carbohydr. Polym. 2020. Vol. 245. Article 116528.
  7. Cui J., Zhao W., Wu J., Zhang D., Liu L., Qiao H. et al. // J. Drug Deliv. Sci. Technol. 2023. Vol. 88. Article 104984.
  8. Казаков А.Г., Гаращенко Б.Л., Яковлев Р.Ю., Винокуров С.Е., Калмыков С.Н., Мясоедов Б.Ф. // Радиохимия. 2020. T. 62. № 5. C. 394–399.
  9. Казаков А.Г., Гаращенко Б.Л., Бабеня Ю.С., Иванова М.К., Винокуров С.Е., Мясоедов Б.Ф. // Вопр. радиац. безопасности. 2020. T. 3. C. 73–83.
  10. Казаков А.Г., Гаращенко Б.Л., Яковлев Р.Ю., Винокуров С.Е., Мясоедов Б.Ф. // Радиохимия. 2020. T. 62. № 6. C. 519–525.
  11. Babenya J.S., Kazakov A.G., Ekatova T.Y., Yakovlev R.Y. // J. Radioanal. Nucl. Chem. 2021. Vol. 329. N 2. P. 1027–1031.
  12. Winter G., Eberhardt N., Löffler J., Raabe M., Alam M.N.A., Hao L. et al. // Nanomaterials. 2022. Vol. 12. N 24. Article 4471.
  13. Müller C., Domnanich K.A., Umbricht C.A., van der Meulen N.P. // Br. J. Radiol. 2018. Vol. 91. Article 20180074.
  14. Blower P.J. // Dalton Trans. 2015. Vol. 44. P. 4819–4844.
  15. Müller C., Bunka M., Haller S., Köster U., Groehn V., Bernhardt P. et al. // J. Nucl. Med. 2014. Vol. 55. P. 1658–1664.
  16. Kazakov A.G., Babenya J.S., Ekatova T.Y., Vinokurov S. E., Myasoedov B.F. // Advances in Geochemistry, Analytical Chemistry and Planetary Sciences. 2023. P. 595–601.
  17. Yakovlev R.Y., Dogadkin N.N., Kulakova I.I., Lisichkin G.V., Leonidov N.B., Kolotov V.P. // Diam. Relat. Mater. 2015. Vol. 55. P. 77–86.
  18. Karpukhin A.V., Avkhacheva N.V., Yakovlev R.Y., Kulakova I.I., Yashin V.A., Lisichkin G.V., Safronova V.G. // Cell. Biol. Int. 2011. Vol. 35. N 7. P. 727–733.
  19. Dolmatov V.Y., Rudenko D.V., Burkat G.K., Aleksandrova A.S., Vul’ A.Yu., Aleksenskii A.E. et al. // J. Superhard Mater. 2019. Vol. 41. N 3. P. 169–177.
  20. Казаков А.Г., Бабеня Ю.С., Екатова Т.Ю., Винокуров С.Е., Хворостинин Е.Ю., Ушаков И.А., Зукау В.В., Стасюк Е.С., Нестеров Е.А., Садкин В.Л., Рогов А.С., Мясоедов Б.Ф. // Радиохимия. 2024. Т. 66. № 2. С. ??? (рег. номер 10138.)
  21. Verweij W. // CHEAQS Next Ver. 0.2.1.10. https://www.cheaqs.eu/
  22. Buchatskaya Y., Romanchuk A., Yakovlev R., Shiryaev A., Kulakova I., Kalmykov S. // Radiochim. Acta. 2015. Vol. 103. N 3. P. 205–211.
  23. Zhukov A.N., Shvidchenko A.V., Yudina E.B. // Colloid J. 2020. Vol. 82. N 4. P. 369–375.
  24. Shvidchenko A.V., Zhukov A.N., Dideikin A.T., Baidakova M.V., Shestakov M.S., Shnitov V.V., Vul’ A.Y. // Colloid J. 2016. Vol. 78. N 2. P. 235–241.
  25. Inagaki M., Sekimoto S., Tanaka W., Tadokoro Т., Ueno Y., Kani Y., Tsutomu O. // J. Radioanal. Nucl. Chem. 2019. Vol. 322. P. 1703–1709.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download
2. Fig. 1. Kinetics of Sc(III) sorption by TAN (a), STP (b) and ox-STP (c) aggregates (20 ng/ml Sc, 100 μg/ml NA).

Download (247KB)
Indexing metadata
3. Fig. 2. Forms of Sc(III) in aqueous solutions of HCl and NaOH at 20 ng/ml Sc(III), according to calculations [21].

Download (138KB)
Indexing metadata
4. Fig. 3. Comparison of the degree of Sc(III) sorption obtained in this work with the sizes of TAN (a), STP (b) and ox-STP (c) aggregates [20].

Download (243KB)
Indexing metadata

Copyright (c) 2024 Russian Academy of Sciences