The effect of calcium phosphate implant coating on osteoconduction

## Abstract We sought to assess the ability of nanotopographically complex titanium surfaces to accelerate osteoconduction. For this, 130 miniature bone ingrowth chambers (called “T plants”), fabricated from either commercially pure titanium (cpTi) or titanium alloy (Ti6Al4V or Ti64), with microtop

Calcium phosphate coatings ( 50 mm thick), especially those made with hyd- xyapatite (HA), produced by the plasma-spraying process have been succe- fully used on orthopedic and dental implants to improve fixation of these implants in bone. Thin calcium phosphate coatings ( 10mm thick) formed by vari

Calcium phosphate coatings ( 50 mm thick), especially those made with hyd- xyapatite (HA), produced by the plasma-spraying process have been succe- fully used on orthopedic and dental implants to improve fixation of these implants in bone. Thin calcium phosphate coatings ( 10mm thick) formed by vari

## Abstract In this study, we examined the effect of calcium phosphate (Ca‐P) coating crystallinity and of surface roughness on growth and differentiation of osteogenic cells. Grit‐blasted titanium substrates were provided with Ca‐P coatings of different crystallinities. Rat bone marrow (RBM) cells