Biocompatibility of particulate polymethylmethacrylate bone cements: a comparative study in vitro and in vivo

A biodegradable particulate composite bone cement consisting of a crosslinked gelatin matrix and tricalcium phosphate particles was implanted intraosseously in rabbits for up to 12 weeks. Cured cylindrical implants were inserted in holes drilled in the proximal tibia1 metaphysis. Sequential fluoroch

We have developed a biodegradable particulate composite bone cement and used in vitro and in vivo methods for studying its suitability for orthopaedic applications. The composite matrix consists of gelatin, water, and sodium salicylate. The particulate phase is made up of powdered and particulate (3

## Abstract An __in vitro__ study was performed to compare the effects of augmenting interlocking nails of one of two diameter (5 or 6 mm) with intramedullary polymethylmethacrylate. Subsequently, an __in vivo__ study was performed to compare the effects of augmenting the interlocking nail with fiv

## Abstract Segmented poly(urethane urea)s (PUUs) with hard segments derived only from methyl 2,6‐diisocyantohexanoate (LDI) without the use of a chain extender have previously been described. These materials, which contain hard segments with multiple urea linkages, show exceptionally high strain c

## Abstract The goal of this study was to generate porous scaffolds from the genetically engineered protein, an analogue of __Nephila clavipes__ spidroin 1 (rS1/9) and to assess the properties of new rS1/9 scaffolds essential for bioengineering. The salt leaching technique was used to make the rS1/