Your search keyword '"Yucel, D."' showing total 2 results

1. Collagen scaffolds with in situ-grown calcium phosphate for osteogenic differentiation of Wharton's jelly and menstrual blood stem cells.

Author

Karadas O, Yucel D, Kenar H, Torun Kose G, and Hasirci V

Subjects

Adult, Alkaline Phosphatase metabolism, Animals, Blood Cells cytology, Calcium analysis, Cell Proliferation drug effects, Collagen ultrastructure, Compressive Strength drug effects, Crystallization, Female, Humans, Materials Testing, Menstruation, Mesenchymal Stem Cells drug effects, Mesenchymal Stem Cells enzymology, Phosphates analysis, Porosity, Rats, Sprague-Dawley, Calcium Phosphates pharmacology, Cell Differentiation drug effects, Collagen pharmacology, Mesenchymal Stem Cells cytology, Osteogenesis drug effects, Tissue Scaffolds chemistry, Wharton Jelly cytology

Abstract

The aim of this research was to investigate the osteogenic differentiation potential of non-invasively obtained human stem cells on collagen nanocomposite scaffolds with in situ-grown calcium phosphate crystals. The foams had 70% porosity and pore sizes varying in the range 50-200 µm. The elastic modulus and compressive strength of the calcium phosphate containing collagen scaffolds were determined to be 234.5 kPa and 127.1 kPa, respectively, prior to in vitro studies. Mesenchymal stem cells (MSCs) obtained from Wharton's jelly and menstrual blood were seeded on the collagen scaffolds and proliferation and osteogenic differentiation capacities of these cells from two different sources were compared. The cells on the composite scaffold showed the highest alkaline phosphatase activity compared to the controls, cells on tissue culture polystyrene and cells on collagen scaffolds without in situ-formed calcium phosphate. MSCs isolated from both Wharton's jelly and menstrual blood showed a significant level of osteogenic activity, but those from Wharton's jelly performed better. In this study it was shown that collagen nanocomposite scaffolds seeded with cells obtained non-invasively from human tissues could represent a potential construct to be used in bone tissue engineering., (Copyright © 2012 John Wiley & Sons, Ltd.)

Published

2014

2. Polyester based nerve guidance conduit design.

Author

Yucel D, Kose GT, and Hasirci V

Subjects

Dimethylpolysiloxanes chemistry, Lactic Acid chemistry, Magnetic Resonance Spectroscopy, Materials Testing, Microscopy, Electron, Scanning, Polyglycolic Acid chemistry, Polylactic Acid-Polyglycolic Acid Copolymer, Porosity drug effects, Surface Properties drug effects, Tensile Strength drug effects, Guided Tissue Regeneration methods, Nerve Regeneration drug effects, Polyesters pharmacology, Tissue Scaffolds chemistry

Abstract

Nerve conduits containing highly aligned architecture that mimics native tissues are essential for efficient regeneration of nerve injuries. In this study, a biodegradable nerve conduit was constructed by converting a porous micropatterned film (PHBV-P(L-D,L)LA-PLGA) into a tube wrapping aligned electrospun fibers (PHBV-PLGA). The polymers were chosen so that the protective tube would erode slower than the fibrous core to achieve complete healing before the tube eroded. The pattern dimensions and the porosity (58.95 (%) with a maximum pore size of 4-5 microm) demonstrated that the micropatterned film would enable the migration, alignment and survival of native cells for proper regeneration. This film had sufficiently high mechanical properties (ultimate tensile strength: 3.13 MPa, Young's Modulus: 0.08 MPa) to serve as a nerve guide. Electrospun fibers, the inner part of the tubular construct, were well aligned with a fiber diameter of ca. 1.5 microm. Fiber properties were especially influenced by polymer concentration. SEM showed that the fibers were aligned parallel to the groove axis of the micropatterned film within the tube as planned considering the nerve tissue architecture. This two component nerve conduit appears to have the right organization for testing in vitro and in vivo nerve tissue engineering studies., ((c) 2009 Elsevier Ltd. All rights reserved.)

Published

2010