Medical Imaging and Clinical Research

Biography

Biography: Maryam Chenani

Abstract

In the past decade, much effort has been made to develop hemostatic agents. But the existing options have ample restrictions, including failure to maintain the structure of the styptic in the face of severe bleeding and rapid changes in pH. Since variation in the pH of the injury site is an important factor in the failure of styptic and its structural damage, in this study the behavior of a gelatin-silica hybrid in severe bleeding was evaluated under different pH values. On the other hand, the effect of the hybrid particle size, which is one of the key physical properties of the hybrid, has been studied in rapid control of hemostasis. The hybrid hemostatic behavior varied drastically by changing the particle size, so that the hybrid containing SiO₂ with the average particle size of about 1 micro-meter (Hyb-MSiO₂) demonstrated very poor ability in platelet adhesion in neutral pH. Also the aPTT was not shorter than the normal time, whereas reduction of the particle size beyond a certain limit (with nano-meter SiO₂ for Hyb-NSiO₂), led to both increasing platelet adhesion and very considerable reduction of aPTT in neutral pH. Alignment of all results showed that the particle size reduction improves the hemostatic behavior of the hybrid toward its best performance by controlling excessive bleeding. By changing the pH for a certain particle size, structural integrity and thereupon the hybrid hemostatic behavior changed dramatically. So that the nano-hybrid showed the most blood absorption and acceded to a coherent structure. The results demonstrated that in alkaline or acidic environment, the hybrid hemostatic behavior was limited, so that in acidic pH the blood absorption was reduced and the normal clotting time was longer. Based on the results of this study, it was found that changes in the hybrid behavior in acidic pH were much more drastic than in alkaline pH, and also the hybrid with the optimum particle size (Hyb-NSiO₂) can maintain the structural integrity with rapid hemostasis. Based on the objective that the pH at the injury site change to the alkaline side, the resulting hybrid has an excellent ability to control excessive bleeding and can be proposed for further in vivo studies as a novel styptic.