Influence of the isoelectric point of gelatin on its adsorption on nanosilica surface
DOI: https://doi.org/10.15407/hftp12.03.175
Abstract
The joint efforts of chemists, physicians and technologists conducting researches to create new medical sorbents and combined drugs based on nanosilica, which have not only a detoxifying effect, but also antibacterial, wound healing, hemostatic and other important properties. One of the stages of such a research is developing regulatory documentation.
To control the quality of the sorbent, the method of point measurements is most often used, according to it, the amount of adsorption of the marker substance at the single point of the adsorption curve is determined. The suitability of sorbents based on nanosilicа for using is determined by the value of the adsorption capacity concerning to medical gelatin. No other requirements for the process of test adsorption of gelatin by the sorbent are given. although it is known that the adsorption of proteins depends on the pH of the solution. Its maximum value is reached at a pH value corresponding to the isoelectric point (pI) of the protein. Each protein can be characterized by its own isoelectric point. Domestic and foreign standards give only the value of “pH of aqueous solutions” of gelatin and do not contain the indicator “isoelectric point”.
The aim of the work is to study the influence of the isoelectric point of gelatin on its adsorption on nanosilica surface at different pH to appreciate the suitability of conditions for determining the adsorption activity of medical sorbents based on nanosilica.
The adsorption of three samples of gelatin was examined in the work: A – edible gelatin (pI = 4.3–4.8); B – that from the catalog “Merck” (pI = 4.3–4.8) and C – that from the catalog “Fluka” (pI = 7.5–7.7) on nanosilica surface in the pH range from 3 to 8. It has been shown that for samples A and B the dependence has a maximum at pH ~ 4.5–5; and for sample C, the adsorption increases monotonically with increasing pH. It was noted that at pH ~ 5 the adsorption values for all gelatin samples were approximately equal. The adsorption activity of nanosilica concerning to proteins determined from the isotherms and the method of point measurements is compared. It has been found that the adsorption value of gelatin A onto the nanosilica at Cinitial = 700 mg/100 ml is equal to the Aave value determined by the Langmuir isotherms. This fact verifies the applicability of the method of point measurements for nanosilica/gelatin system to characterize the pharmacological activity of nanosilica based sorbents.
Keywords
References
Chuiko A.A. Silica in medicine and biology. (Kyiv-Stavropol, 1993). [in Russian].
https://orisilpharm.com/atoksyl
http://omnifarma.kiev.ua/ru/produkcija/belij_ugol.html
Polesya T.L. PhD (Med.) Thesis. (Vinnitsa, 1992). [in Russian].
Shtatko E.I. PhD (Med.) Thesis. (Vinnitsa, 1993). [in Russian].
Tertishna O.V. PhD (Med.) Thesis. (Kyiv, 1994). [in Ukrainian].
Gerashchenko I.I. Doctoral (Med.) Thesis. (Vinnitsa, 1997). [in Russian].
Chuiko A.A. Medical Chemistry and Clinical Applications of Silicon Dioxide. (Kyiv, Naukova Dumka, 2003). [in Russian].
Chuiko O.O., Pentyuk O.O., Pogorelyi V.K. Enterosorbent Silics: Properties and Clinical Application. Chapter 13. In: Colloidal silica: fundamentals and applications. (Taylor & Francis Group, Boca Raton London New York, 2006).
Nikolaev V.G., Mikhalovsky S.V., Gurina N.M. Modern enterosorbents and mechanisms of their action. Efferent therapy. 2005. 11(4): 3. [in Russian].
Common pharmacopoeia article.1.2.3.0021.15. Determination of the adsorption activity of enterosorbents.
Preclinical study of enterosorbents. Regulatory Document of Ministry of Health of Ukraine. 2010.
Pharmacopoeia article 42U-82/224-889-00. Siliks.
Weiss A. Macromolecular Chemistry of Gelatin. (Moscow: Food industry, 1971).
Medical gelatin. GF USSR, X edition. (Moscow, Medicine, 1968).
Edible gelatine GOST 11293-89.
Edible gelatine TU U 24.6-00418030-002-2007.
Gelatin raw material for the medical industry GOST 23058-89.
Nosach L.V., Voronin E.F., Pakhlov E.M. Biocompatible hybrid oxide nanoparticles for Human Health: from synthesis to applications. Chapter 7. In: Polymer modified nanosilica as a sorbent for medical applications. (Elsevier, 2019). https://doi.org/10.1016/B978-0-12-815875-3.00007-2
Voronin E.P., Nosach L.V., Pakhlov E.M., Gun'ko V.M., Chekman I.S., Rudenko A.V., Osinnya L.M., Ivasenko M.N., Kravchuk B.O., Terpilowski K. Creation of stable aqueous dispersions of nanosized silica as a sorption-detoxification agent for medical purposes. Surface. 2016. 8(23): 267. [in Ukrainian]. https://doi.org/10.15407/Surface.2016.08.267
Nosach L.V., Voronin E.F., Pakhlov E.M., Charmas B., Skubiszewska-Zięba J., Skwarek E., Janusz W., Gun'ko V.M. Nanoparticulate structures with glucose-derived char and compacted fumed silica in gaseous and aqueous media. In: Nanophysics, Nanomaterials, Interface Studies, and Applications. (Springer, 2017). https://doi.org/10.1007/978-3-319-56422-7_56
Patent UA 124890. Chekman I.S., Balko O.B., Voronin E.P., Doroshenko A.I., Doroshenko A.M. The method of determining the antimicrobial activity of the composite of nanodispersed silica and polyhexamethylene guanidine hydrochloride. 2018.
Patent UA 117179. Chernyakova G.M., Minukhin V.V., Voronin E.P., Nosach L.V., Vovk O.O. Application sorption agent for the treatment of wound infections. 2018.
Doroshenko A.I., Balko O.B., Voronin Ye.P., Doroshenko A.M., Zaychenko G.V. The in vitro antimicrobial activity of highly dispersed silica and polyhexamethylene guanidine hydrochloride composite for treating local infections. Clinical Pharmacy. 2019. 23(1): 30. https://doi.org/10.24959/cphj.19.1484
Voronin E.F., Nosach L.V., Gun'ko V.M., Charmas B. Geometric and mechano-sorption modification of fumed nanosilica in the gaseous dispersion media. Physics and Chemistry of Solid State. 2019. 20(1): 22. https://doi.org/10.15330/pcss.20.1.26
Klonos P.A., Nosach L.V., Voronin E.F., Pakhlov E.M., Kyritsis A., Pissis P. Glass Transition and Molecular Dynamics in Core-Shell type Nanocomposites Based on Fumed Silica and Polysiloxanes: Comparison between Poly(dimethylsiloxane) and Poly(ethylhydrosiloxane). J. Phys. Chem. C. 2019. 123(46): 28427. https://doi.org/10.1021/acs.jpcc.9b07247
Voronina O.E., Malysheva M.L., Nosach L.V., Voronin E.F., Gun'ko V.M., Charmas B., Skubiszewska-Zięba J. A role of free silanol groups of nanosilica surface in interaction with poly(vinyl pyrrolidone). Annales Universitatis Mariae Curie-Sklodowska, sectio AA Chemia. 2017. 72(2): 51. https://doi.org/10.17951/aa.2017.72.2.51-66
Biosil. TU U.05540209.044-2001. https://doi.org/10.1088/1126-6708/2001/03/044
Rezyapkin V.I., Slyshenkov V.S., Zavodnik I.B., Burd' V.N., Sushko L.I., Romanchuk Ye.I., Karayedova L.M. Laboratory workshop on biochemistry and biophysics. (Grodno: GrSU, 2009). [in Russian].
Frolov Yu.G. Colloidal Chemistry Course. (Moscow: Chemistry, 1988). [in Russian].
Gordon A., Ford R. Chemist's satellite: Pphysical and Chemical properties, Techniques, Bibliography. (Moscow: Mir, 1976). [in Russian].
Dawson R., Elliott D., Elliott W., Jones K. Data for Biochemical Research. (Third Edition). (Oxford University Press: Oxford, 1986).
DOI: https://doi.org/10.15407/hftp12.03.175
Copyright (©) 2021 E. P. Voronin, L. P. Golovkova, L. V. Nosach, S. L. Los
This work is licensed under a Creative Commons Attribution 4.0 International License.