Early cellular responses to calcium phosphate ceramics

## Abstract In the last decades, the research on materials for bone regeneration has focused on materials that are degradable and capable of stimulating tissue regeneration. In this context, phosphate glasses offer an interesting alternative, given the wide range of solubility they present and thei

The cellular response to well-characterized Ca-P and Ti surfaces was analyzed. This study indicated that the ion-beam sputtering process could produce a hydroxyapatite-type coating. However, structural alterations such as the incorporation of CO, and the loss of the OH groups were observed. The Ti s

## Abstract Calcium silicate ceramics have been proposed as new bone repair biomaterials, since they have proved to be bioactive, degradable, and biocompatible. β‐tricalcium phosphate ceramic is a well‐known degradable material for bone repair. This study compared the effects of CaSiO~3~ (α‐, and β

## Abstract Different types of calcium phosphates [hydroxyapatite (HA), fluorapatite (FA), tricalcium phosphate (TCP), and their composites (HA + FA, HA + TCP)] were coated on a zirconia (ZrO~2~) porous scaffold using a powder slurry method. The ZrO~2~ porous scaffold was intended for a load‐bearin

## Abstract The aim of this work was to investigate __in vitro__ the biological events leading to ectopic bone formation in contact with microporous biphasic calcium phosphate (BCP) ceramics. After implantation, microparticles may arise from their degradation and induce an inflammatory response inv

## Abstract We conducted an __in vivo__ experiment to evaluate the resorption rate of a calcium phosphate cement (CPC) with macropores larger than 100 μm, using the CPC called Biocement D (Merck Biomaterial, Darmstadt, Germany), which after setting only shows pores smaller than 1 μm. The gas bubble