Your search keyword '"Uskoković, Vuk"' showing total 4 results

1. Polymeric nanotechnologies for the treatment of periodontitis: A chronological review

Author

Uskoković, Vuk, Pejčić, Ana, Koliqi, Rozafa, and Anđelković, Zlatibor

Published

2022

2. Factors defining the stability of poly(lactide-co-glycolide) spheres for the sustained release of a cysteine protease inhibitor.

Author

Uskoković, Vuk

Subjects

*CYSTEINE proteinase inhibitors, *PARTICLE size distribution, *AMEBIASIS, *SUPERSATURATION, *SPHERES, *COLLOIDAL stability

Abstract

Colloidal stability and the regularity of the release kinetics benefit from the high circularity and the narrow size dispersion of polymeric particles as drug delivery carriers. A method for obtaining such particles composed of poly(lactide- co -glycolide) (PLGA), averaging at 1.0 ± 0.3 µm in size, is reported here, along with the analysis of the effects of different synthesis parameters on their morphological characteristics. As in agreement with the classical nucleation theory, the particle size and the degree of cohesion were inversely proportional to supersaturation. Consequently, the optimal conditions for the precipitation of small and narrowly dispersed particles involved an abrupt elevation of supersaturation. Owing to the high colloidal stability of the particles, centrifugation exhibited a counterintuitive effect on them, refining their morphological features and promoting their individuation. Polyvinyl alcohol (PVA) was used as a steric repulsion additive and its effect on the stability of PLGA spheres was concentration-dependent, with the particles aggregating, partially coalescing and losing their distinct features both with no PVA in the system and at PVA concentrations higher than the optimal. At its narrowest, the particle size distribution was bimodal, exhibiting the average circularity of 0.997 ± 0.003 and the average roundness of 0.913 ± 0.054. PLGA spheres were loaded with an inhibitor of EhCP4, a cysteine protease from E. histolytica , a parasite causing amoebic dysentery in the tropical and developing world. The burst release of the drug at early time points was followed by a zero-order release period, yielding a biphasic profile that can be of benefit in the delivery of anti-infective agents. The release profile fitted poorly with the Hixson-Crowell kinetic model and excellently with the Higuchi and the Korsmeyer-Peppas ones, indicating that the release is conditioned by diffusion rather than by the degradation of the polymer. The release and the erosion proceeded independently from one another, suggesting that the pore formation, water penetration and swelling are the primary driving forces for the release of the drug. [ABSTRACT FROM AUTHOR]

Published

2020

3. Physical, electrochemical and biological evaluations of spin-coated ε-polycaprolactone thin films containing alumina/graphene/carbonated hydroxyapatite/titania for tissue engineering applications.

Author

Afifi, M., Ahmed, M.K., Fathi, A.M., and Uskoković, Vuk

Subjects

*POLYCAPROLACTONE, *THIN films, *ALUMINUM oxide films, *POISSON'S ratio, *TISSUE engineering, *MATERIALS science

Abstract

Composite structures are at the frontier of materials science and engineering and polymeric/ceramic composites present one of their most prospective subsets. Prior studies have shown both improvements and deteriorations of properties of polymers upon the addition of ceramic phases to them, but not many studies have dealt with the direct comparison of chemically distinct inorganic additives. The goal of this study was to compare the properties of ε-polycaprolactone (PCL) thin films supplemented with alumina, graphene, carbonated hydroxyapatite or titania particles, individually, in identical amounts (12 wt%). The composite films were analyzed for their phase composition, grain size, morphology, surface roughness, porosity, cell response, mechanical properties and electrochemical performance. Each additive imparted one or more physical or biological properties onto PCL better than others. Thus, alumina increased the microhardness of the films better than any other additive, with the resulting values exceeding 10 MPa. It also led to the formation of a composite with the least porosity and the greatest stability to degradation in simulated body fluid based on open circuit potential (OCP) measurements and electrochemical impedance spectroscopy (EIS). Titania made the surface of PCL roughest, which in combination with its high porosity explained why it was the most conducive to the growth of human fibroblasts, alongside being most prone to degradation in wet, corrosive environments and having the highest Poisson's ratio. Graphene, in contrast, made the surface of PCL smoothest and the bulk structure most porous, but also most conductive, with the OCP of −37 mV. The OCP of PCL supplemented with carbonated hydroxyapatite had the highest OCP of −134 mV and also the highest mechanical moduli, including the longitudinal (781 MPa), the shear (106 MPa), the bulk (639 MPa), and the elastic (300 MPa). The only benefit of the deposition of multilayered PCL films supplemented with all four inorganic additives was to enable a relatively high resistance to degradation. This study demonstrates that the properties of thin PCL films could be effectively optimized through the simple choice of appropriate inorganic additives dispersed in them. There is no single additive that proves ideal for improving all the properties of interest in PCL thin films, but their choice should be adjusted to the actual application. One such method of compositional optimization could prove crucial in the effort to develop biocomposites for superior performance in tissue engineering applications. [ABSTRACT FROM AUTHOR]

Published

2020

4. Gold as a dopant in selenium-containing carbonated hydroxyapatite fillers of nanofibrous ε-polycaprolactone scaffolds for tissue engineering.

Author

Ahmed, M.K., Mansour, S.F., Al-Wafi, Reem, Afifi, M., and Uskoković, Vuk

Subjects

*TISSUE scaffolds, *SELENIUM, *TISSUE engineering, *BIOMATERIALS, *CELLULAR mechanics, *DOPING agents (Chemistry), *BIOLOGICAL variation, *OXYANIONS

Abstract

The necessity for finding a compromise between mechanical and biological properties of biomaterials spurs the investigation of the new methods to control and optimize scaffold processing for tissue engineering applications. A scaffold composed of ε-polycaprolactone fibers reinforced with carbonated hydroxyapatite (CHAP) dually doped with selenite oxyanions (Se) and cationic gold (Au) was synthesized using the electrospinning technique and studied at different contents of Au. Despite the fact that the amount of the Au dopant was relatively low, variations to it induced significant microstructural changes, affecting the cell response and mechanical properties in return. Au nanoparticles segregated as a separate, ternary phase at the highest Au content, corresponding to x = 0.8 in the Au x Ca 10−1.5x (PO 4) 5.8 (SeO 2) 0.2−x (CO 3) x (OH) 2 stoichiometric formula of Au/Se-CHAP. Their appearance coincided with a rapid degeneration in the density and adhesion of osteoblastic cells grown on the scaffolds. In spite of this adverse effect, the cell spreading and proliferation improved with increasing the amount of the Au dopant in the Au/Se-CHAP particles of the scaffold in the x = 0.0–0.6 range, suggesting that the biological effects of Au in the ionic and in the nanoparticulate form on the implant integration process may be diametrically opposite. The addition of Au had a dramatic effect on some mechanical properties, such as toughness and strain at break, which were both reduced twice upon the introduction of Au into Se-CHAP at the lowest amount (x = 0.2) compared to the Au-free composite. The significant variation of physical and biological properties of these composite scaffolds with trace changes in the content of the Au dopant inside the ceramic filler particles is promising, as it provides a new, relatively subtle avenue for tailoring the properties of tissue engineering scaffolds for their intended biomedical applications. [ABSTRACT FROM AUTHOR]

Published

2020