The clinical application of bone morphogenetic proteins (BMPs) offers solutions to many challenging problems in orthopaedics. However, a practical clinical problem is to obtain a controlled release of the BMPs. The attachment of heparin to biomaterials may result in an appropriate matrix for the binding, and sustained release of BMPs. Binding of growth factors to heparin stabilizes these growth factors, protects them from proteolytic degradation, and prolongs the half-life of BMPs in culture media 20-fold. We created a carrier based delivery system with a localized sustained release by loading a tricalciumphosphate/hydroxyapatite (TCP/HA) bone substitute coated with cross-linked collagen and heparin, with BMP-7.

TCP/HA granules (BoneSave^™, Stryker Orthopaedics) were coated with collagen, and subsequently the collagen was cross-linked in the presence (TCP/HA-Col-Hep) and absence (TCP/HA-Col) of heparin. BMP-7 was loaded onto the coated TCP/HA granules. Morphology of the coated collagen with and without heparin, and release kinetics of BMP-7 from the granules were analyzed. TCP/HA granules without coating were used as controls.

Analysis showed a highly porous collagen network on both TCP/HA-Col and TCP/HA-Col-Hep granules. Immersion of the granules in BMP-7 solution, resulted in the binding of 54±3% (62.9±5.4 ng BMP-7/mg granule) to the TCP/HA granules, 64±8% (69.0±9.6 ng BMP-7/mg granule) to the TCP/HA-Col granules, and 78±1% (92.9±4.8 ng BMP-7/mg granule) to the TCP/HA-Col-Hep granules. TCP/HA granules showed a burst release of BMP-7 within the first 4 h. TCP/HA-Col granules showed an initial burst release, followed by a more gradual release. In contrast, BMP-7 release from the TCP/HA-Col-Hep granules was sustained up to 21 days.

The sustained delivery system for BMP-7 developed in this study may provide a powerful tool for bone regeneration. This system could probably also be applied to deliver multiple growth factors that have affinities for heparin, which could for instance synergistically enhance osteogenesis by increasing vascularity.