Effect of Sintering Temperature of Bioactive Glass Nanoceramics on the Hemolytic Activity and Oxidative Stress Biomarkers in Erythrocytes

Overview

Journal Cell Mol Bioeng

Publisher Springer

Specialty Biomedical Engineering

Date 2020 May 20

PMID 32426058

Citations 2

Authors

Ioannis Tsamesidis

Konstantina Kazeli

Evgenia Lymperaki

Georgia K Pouroutzidou

Ilias M Oikonomou

Philomela Komninou

George Zachariadis

Karine Reybier

Antonella Pantaleo

Eleana Kontonasaki

Affiliations

Soon will be listed here.

Abstract

Introduction: The nature of the surface is critical in determining the biological activity of silica powders. A novel correlation between toxicity and surface properties of bioactive glass ceramics (BGCs) synthesized the sol-gel method was attempted in this study.

Methods: The behavior of BGCs after their attachment to the surface of red blood cells (RBCs) was evaluated and their toxic effects were determined based on hemolysis, membrane injury anti-phosphotyrosine immunoblot of Band 3, lipid peroxidation, potential to generate reactive oxygen species, and antioxidant enzyme production. In particular, three BGCs were synthesized and treated at three sintering temperatures (T1 = 835 °C, T2 = 1000 °C and T3 = 1100 °C) to investigate possible relation between surface charge or structure and hemolytic potential.

Results: Their toxicity based on hemolysis was dose dependent, while BGC-T2 had the best hemocompatibility in compare with the other BGCs.No BGCs in dosages lower than 0.125 mg/mL could damage erythrocytes. On the other hand, all BGCs promoted the production of reactive oxygen species in certain concentrations, with the BGC-T2 producing the lowest ROS and increasing the glutathione levels in RBCs protecting their damage.

Conclusions: The results suggest that various factors such as size, a probable different proportion of surface silanols, a balanced mechanism between calcium and magnesium cellular uptake or the different crystalline nature may have contributed to this finding; however, future research is needed to clarify the underlying mechanisms.

Citing Articles

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Effect of Silica Based Nanoparticles against and .

Tsamesidis I, Lymperaki E, Egwu C, Pouroutzidou G, Kazeli K, Reybier K J Xenobiot. 2021; 11(4):155-162.

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