Preparation of a biomimetic composite scaffold from gelatin/collagen and bioactive glass fibers for bone tissue engineering.

Bone tissue is a composite material made of organic and inorganic components. Bone tissue engineering requires scaffolds that mimic bone nature in chemical and mechanical properties. This study proposes a novel method for preparing composite scaffolds that uses sub-micron bioglass fibers as the organic phase and gelatin/collagen as the inorganic phase.

Preparation and characterization of calcium sulfate-biomimetic apatite nanocomposites for controlled release of antibiotics.

In the present study, release properties of antibiotic-loaded cement-type nanocomposites of biomimetic apatite and calcium sulfate were studied. Nanocrystalline component of the nanocomposite was synthesized by soaking a mixture of calcium phosphate reactants in tris-buffered simulated body fluid (SBF). The release patterns of cephalexin and gentamicin from both pure calcium sulfate and nanocomposite cements into SBF were collected up to 144 h and fitted by Higuchi and Weibull equations.

The influence of the acidic component of the gas-foaming porogen used in preparing an injectable porous calcium phosphate cement on its properties: acetic acid versus citric acid.

In the present study, macroporous calcium phosphate cements (CPCs) were prepared using a porogen; that is, the gas-foaming technique. The objective was to investigate the influence of the acidic component of the porogen (acetic acid versus citric acid) on several properties of a specified CPC. In all of the cements prepared, the basic component of the porogen was the same, namely, NaHCO(3), and it was added to the powder phase of the cement, while the acidic component of the porogen was dissolved in the liquid phase of the cement.

Phase evaluation of an effervescent-added apatitic calcium phosphate bone cement.

Development of macroporosity during setting would allow fast bone ingrowth and good osteointegration of the implant. The interconnected macropores could be created in calcium phosphate cements (CPCs) through the addition of an effervescent porogen mixture to the component of the cements. But this addition could also affect other characteristics of CPCs, such as setting time, mechanical strength, extent of conversion of reactant to apatite phase, crystallinity, and chemical composition of apatite lattice.