Polyelectrolyte multilayer-calcium phosphate composite coatings for metal implants.

The preparation of organic-inorganic composite coatings with the purpose to increase the bioactivity of bioinert metal implants was investigated. As substrates, glass plates and rough titanium surfaces (Ti-SLA) were employed. The method comprises the deposition of polyelectrolyte multilayers (PEMLs) followed by immersion of the coated substrate into a calcifying solution of low supersaturation (MCS).

Preparation of a partially calcified gelatin membrane as a model for a soft-to-hard tissue interface.

Cartilage and/or bone tissue engineering is a very challenging area in modern medicine. Since cartilage is an avascular tissue with limited capacity for self-repair, using scaffolds provides a promising option for the repair of severe cartilage damage caused by trauma, age-related degeneration, and/or diseases. Our aim in this study was to design a model for a functional biomedical membrane to form the interface between a cartilage-forming scaffold and bone.

Evaluation of methods for urine inhibitory potential for precipitation of calcium oxalate.

Renal lithiasis is a significant medical and social problem. Worldwide recurrence is anywhere from 3% to 5%. Objective of this paper is to evaluate two methods for distinguishing between stone formers and non-stone formers.

Biomimetic organic-inorganic nanocomposite coatings for titanium implants. In vitro and in vivo biological testing.

Recently described organic-inorganic nanocomposite coatings of the chemical composition: (PLL/PGA)(10)CaP[(PLL/PGA)(5)CaP](4) (coating A) and (PLL/PGA)(10)CaP[(PLL/PGA)(5)CaP](4)(PLL/PGA)(5) (coating B), applied to chemically etched titanium plates, have been tested by extensive cell culture tests and in vivo biological experiments, with uncoated titanium plates serving as controls. Before testing, coated samples were stored for extended periods of time (from 2 weeks to 8 months) under dry, sterile conditions. Cells of the cell-lines MC3T3-E1 and/or SAOS-2 were used for the following cell culture tests: initial adhesion (4 h) and proliferation (up to 21 days), cell activity (XTT test), morphology, synthesis of collagen type I and alkaline phosphatase activity (all incubation up to 21 days).

Complementary effects of multi-protein components on biomineralization in vitro.

The extracellular matrix (ECM) is composed of mixed protein fibers whose precise composition affects biomineralization. New methods are needed to probe the interactions of these proteins with calcium phosphate mineral and with each other. Here we follow calcium phosphate mineralization on protein fibers self-assembled in vitro from solutions of fibronectin, elastin and their mixture.