Abstract
Currently available calcium silicate based ceramics pseudowollostonite (CaSiO3) ceramics are regarded as a potential bioactive material for bone tissue regeneration due to their osseointegration properties. A drawback of CaSiO3 ceramics is that they possess high dissolution rate, leading to a high pH value in the surrounding environment thereby affecting the biological activity of bone cells. We hypothesize that chemical modification of CaSiO3 ceramics will improve their physical and biological properties. The coordinated activities of osteoblasts (OB) and osteoclasts (OC) are critical for proper bone remodelling. Moreover, growing evidence indicate that vascular endothelial cells are involved in bone development and remodelling.
Present study aims at Chemically modifying CaSiO3 by incorporating zinc (Zn) and titanium (Ti) into their structure to develop novel materials Hardystonite (HT, Ca2ZnSi2O7) and Sphene (CaTiSiO5), respectively and to determine their effect on bone cells OB & OC and on endothelial cells.
It is well known that cell behaviour in a culture system is influenced by the physiochemical characteristics of the substrate. Human bone derived cells (HBDC) cultured on HT and Sphene supported the HBDC attachment (cells exhibited well defined cytoskeletal structure) showed characteristic features of cellular proliferation and differentiation. In addition, Zn and Ti incorporation into CaSiO3 supported the formation of mature, active and functional OC. Moreover, the modified bio-materials were found to be conducive to Human micro-vascular dermal endothelial cell growth. Our results suggest that HT and Sphene possessed an improved physical characteristics and enhanced biological activities of bone cells (OB & OC) and endothelial cells thus rendering it a potential material for bone tissue regeneration and coatings onto commonly used orthopaedic and dental implants.
Correspondence should be addressed to David Haynes, PhD, Senior Lecturer, President ANZORS, at Discipline of Pathology, School of Medical Sciences, University of Adelaide, SA, 5005, Australia