9 research outputs found
Thermal Barrier Coating Analysis of Remaining Life and Contaminant Composition
A novel inorganic nanocomposite material,
called BOA, which has
the form of small building blocks composed of gold nanoparticles embedded
in a polyoxoborate matrix, is presented. It is demonstrated that cotton
wool decorated with the BOA nanocomposite displays strong antibacterial
activity toward both Gram-positive and -negative bacteria strains.
Importantly, the modified cotton does not release any toxic substances,
and the bacteria are killed upon contact with the fibers coated with
the BOA. Toxicity tests show that the nanocomposite鈥搃n spite
of its antiseptic properties鈥搃s harmless for mammalian cells.
The presented method of surface modification utilizes mild, environmentally
friendly fabrication conditions. Thus, it offers a facile approach
to obtain durable nontoxic antiseptic coatings for biomedical applications
Effects of nanoporous anodic titanium oxide on human adipose derived stem cells
The aim of current bone biomaterials research is to design implants that induce controlled, guided, successful, and rapid healing. Titanium implants are widely used in dental, orthopedic, and reconstructive surgery. A series of studies has indicated that cells can respond not only to the chemical properties of the biomaterial, but also, in particular, to the changes in surface topography. Nanoporous materials remain in focus of scientific queries due to their exclusive properties and broad applications. One such material is nanostructured titanium oxide with highly ordered, mutually perpendicular nanopores. Nanoporous anodic titanium dioxide (TiO(2)) films were fabricated by a three-step anodization process in propan-1,2,3-triol-based electrolyte containing fluoride ions. Adipose-derived stem cells offer many interesting opportunities for regenerative medicine. The important goal of tissue engineering is to direct stem cell differentiation into a desired cell lineage. The influence of nanoporous TiO(2) with pore diameters of 80 and 108 nm on cell response, growth, viability, and ability to differentiate into osteoblastic lineage of human adipose-derived progenitors was explored. Cells were harvested from the subcutaneous abdominal fat tissue by a simple, minimally invasive, and inexpensive method. Our results indicate that anodic nanostructured TiO(2) is a safe and nontoxic biomaterial. In vitro studies demonstrated that the nanotopography induced and enhanced osteodifferentiation of human adipose-derived stem cells from the abdominal subcutaneous fat tissue