Spectroscopic study of inorganic nanoparticles ngdyvo4:eu3+ and organic carbocyanine dyes interactions in aqueous solutions

  • T. N. Tkacheva Institute for Scintillation Materials National Academy of Sciences of Ukraine
  • S. L. Yefimova Institute for Scintillation Materials National Academy of Sciences of Ukraine
  • V. K. Klochkov Institute for Scintillation Materials National Academy of Sciences of Ukraine
  • A. V. Sorokin Institute for Scintillation Materials National Academy of Sciences of Ukraine
  • I. A. Borovoy Institute for Scintillation Materials National Academy of Sciences of Ukraine
  • Yu. V. Malyukin Institute for Scintillation Materials National Academy of Sciences of Ukraine
Keywords: dye, nanoparticle, complex «inorganic nanoparticle — organic molecule», adsorption capacity

Abstract

The interaction of the inorganic anionic nanoparticles (nGdYVO4:Eu3+, d = 2 nm) and organic cationic
carbocyanine dyes 3,3’ -diethyloxacarbocyanine perchlorate (DiOC2) 1,1’-dimethyl-3,3,3’,3’-
tetramethylindocarbocyanine perchlorate (DiIC1) 1,1’-dimethyl-3,3,3’,3’- tetramethylindodicarbocyanine
tetrafluorineborate (DiDC1) has been studied spectrophotometrically. The formation of complexes of dye
molecules with spherical nanoparticles nGdYVO4:Eu3+ in aqueous solutions of cationic dye DiOC2 was
found. It is shown that spherical nanoparticle nGdYVO4:Eu3+ can form a complex with molecules of the
cationic dyes in aqueous solution. The adsorption capacity of nGdYVO4:Eu3+nanoparticles has been
found to be about 10 molecules of dye on one nanoparticle.

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Author Biographies

T. N. Tkacheva, Institute for Scintillation Materials National Academy of Sciences of Ukraine

60 Lenin Ave., Kharkov, 61001, Ukraine

S. L. Yefimova, Institute for Scintillation Materials National Academy of Sciences of Ukraine

60 Lenin Ave., Kharkov,61001, Ukraine

V. K. Klochkov, Institute for Scintillation Materials National Academy of Sciences of Ukraine

60 Lenin Ave., Kharkov,61001, Ukraine

A. V. Sorokin, Institute for Scintillation Materials National Academy of Sciences of Ukraine

60 Lenin Ave., Kharkov,61001, Ukraine

I. A. Borovoy, Institute for Scintillation Materials National Academy of Sciences of Ukraine

60 Lenin Ave., Kharkov,61001, Ukraine

Yu. V. Malyukin, Institute for Scintillation Materials National Academy of Sciences of Ukraine

60 Lenin Ave., Kharkov, 61001, Ukraine

References

1. Grossman J.H. Nanotechnology in Cancer medicine / J.H. Grossman, S. E. McNeil // Physics Today. – 2012. – V. 65. – №3. – P. 38-42.

2. Petros R. Strategies in design of nanoparticles for therapeutic applications / R. Petros, J.M. DeSimone // Nature Reviews. Drug Discovery. – 2010. – V. 9. – P. 615-627.

3. Luminescence nanomaterials for biological labelling / F. Wang, W.B. Tan, Y. Zhang, [et al.] // Nanotechnologies. – 2006. – V. 17. – R1-R13.

4. Murcia M.J., Naumann C.A. Biofunctionalization of nanoparticles / Ed. by Challa S.S.R. Kummar // Nanotechnologies for Life Sciences. – V. 1. Wiley-VCH Verlag GmbH. – 2005. – P.1-39.

5. You C.C. The biomacromolecule- nanoparticle interface / C.C. You, A. Chompoosor, V.M. Rotello // Nanotoday. – 2007. – V. 2 (3). – P.34-43.

6. Block copolymer nanostructures / T. Smart, H. Lomas, M. Massignani, [et al.] // Nanotoday. – 2008. – V. 3(3-4). – P. 38-46.

7. A magnetic, luminescent and mesoporous core-shell structured composite material as drug carrier / P. Yang, Z. Quan, Z. Hou, [et al.] // Biomaterials. -2009. – V. 30. – P. 4780-4795.

8. Bouzigues C. Biological applications of rare-earth based nanoparticles / C. Bouzigues, Th. Gacoin, A. Alexandrou // ACS Nano. – 2011. – V.5 (11). – P. 8488-8505.

9. Luminescent mesoporous LaVO4:Eu3+ core-shell nanoparticles: synthesis, characterization, biocompartibility and their cytotoxicity / A. Anees, A. Manawwer, P. Joselito, [et al.] // J. Mater. Chemistry. – 2011. – V. 27. – P. 19310-19316.

10. Lewinski N. Cytotoxicity of Nanoparticles / N. Lewinski, V. Colvin, R. Drezek // Small. – 2008. – V. 1. – P.26-49.

11.Nonfunctionalized nanocrystals can exploit a cell’s active transport machinery delivering them to specific nuclear and cytoplasmic compartment / I. Nabiev, S. Mitchell, A. Davies, [et al.] // Nano Letters. – 2007. – V.7(11). – P. 3452-3461.

12. JianBo L. Fluorescent nanoparticles for chemical and biological sensing / L. JianBo, Y.XiaoHai, He XiaoXiao // Science China Chemistry. – 2011. – V. 54(8). – P.1157-1176.

13. Олейников В.А. Флуоресцентные полупроводниковые кристаллы в биологии и медицине / В.А. Олейников, А.В. Суханова, И.Р. Набиев // Российские нанотехнологии. – 2007. – Т. 2(1). – С.160-173. /Olejnikov V.A. Fluorescentnye poluprovodnikovye kristally v biologii i medicine /Olejnikov V.A. Fluorescentnye poluprovodnikovye kristally v biologii i medicine /V.A. Olejnikov, A.V. Suhanova, I.R. Nabiev // Rossijskie nanotehnologii. – 2007. – T. 2(1). – S.160-173./

14. Эффект специфического взаимодействия нанокристаллов GdYVO4:Eu3+ с ядрами клеток / В.К.Клочков, Н.С.Кавок, Ю.В.Малюкин, [и др.] // Нац. академия наук Украины. – 2010. – Т. 10(81). – С. 81-86. /Jeffekt specificheskogo vzaimodejstvija nanokristallov GdYVO4:Eu3+ s jadrami kletok / V.K.Klochkov, N.S.Kavok, Ju.V.Maljukin, [i dr.] // Nac. akademija nauk Ukrainy. – 2010. – T. 10(81). – S. 81-86./

15. Size selective mechanism governs engineered nanoparticle-induced membrane receptor trafficking / W. Jiang, B.Y. Kim, J.T. Rutka, W.C.W. Chan // Nature Nanotechnology. – 2008. – 3(3). – P. 145-150.

16. Bagatolli L. Phase behavior of multicomponent membranes: Experimental and computational techniques / L. Bagatolli, P.B.S. Kumar // Soft Matter. – 2009. – 5. – P. 3234-3248.

17. Клочков В.К. Водные коллоидные растворы нанолюминофоров nReVO4: Eu3+ (Re = Y, Gd, La) / В.К. Клочков // Наноструктурное материаловедение. – 2009. – № 2. – С. 3–8. /Klochkov V.K. Vodnye kolloidnye rastvory nanoljuminoforov nReVO4: Eu3+ (Re = Y, Gd, La) / V.K. Klochkov // Nanostrukturnoe materialovedenie. – 2009. – № 2. – S. 3–8./

18. Klochkov V.K. Coagulation of luminescent colloid nGdVO4: Eu solutions with inorganic electrolytes / V.K. Klochkov // Functional materials. – 2009. – 16, No 2. – С. 141–144.

19. Теренин А.Н. Фотоника молекул красителя / А.Н. Теренин. – Л.: Наука. – 1967. – 616 с. /Terenin A.N. Fotonika molekul krasitelja / A.N. Terenin. – L.: Nauka. – 1967. – 616 s./

20. The interaction between gold nanoparticles and cationic and anionic dyes: enhanced UV-visible absorption N. Narband, M. Uppal, C.W. Dunnill, [et al.] // Phys. Chem. Chem.Phys. – 2009. – V. 11. – P. 10513-10518.

21. Mekkawi D. Interaction and photostability od some xanthenes and selected azo sensitizing dyes with TiO2 nanoparticles / D.Mekkawi, M.S.F. Abdel-Mottaleb // International Journal of Photoenergy. – 2005. – V. 7. – P.95-101.

22. Inbaray В.S. Adsorption characteristics of magnetite nanoparticles coated with a biopolymer poly(-glutamic acid) / В.S. Inbaray, B.H. Chen // Bioresource Technology. – 2011. – 102. – P. 8868-8876.

23. Preferential and enhanced adsorption of different dyes on iron oxide nanoparticles: a comparative study / B. Saha, S. Das, J. Saika, G. Das // J. Phys. Chem. C. – 2011. – 115. – P. 8024-8033.

24. Характеристики золей nReVO4:Eu3+ (Re = La, Gd, Y, Sm) с наночастицами разной формы и размеров. В.К. Клочков, А.В. Григорова, О.О. Седых, [и др.] // ЖПС. – 2012. – 79(5). – С. 738-742. /Harakteristiki zolej nReVO4:Eu3+ (Re = La, Gd, Y, Sm) s nanochasticami raznoj formy i razmerov. V.K. Klochkov, A.V. Grigorova, O.O. Sedyh, [i dr.] // ZhPS. – 2012. – 79(5). – S. 738-742./
Cited
How to Cite
Tkacheva, T. N., Yefimova, S. L., Klochkov, V. K., Sorokin, A. V., Borovoy, I. A., & Malyukin, Y. V. (1). Spectroscopic study of inorganic nanoparticles ngdyvo4:eu3+ and organic carbocyanine dyes interactions in aqueous solutions. Biophysical Bulletin, 1(28). Retrieved from https://periodicals.karazin.ua/biophysvisnyk/article/view/2499