Abstract
Bone healing especially in elderly patients is a complex process with limited therapeutic options. In recent years the use of BMP2 for fracture healing is investigated extensively. However, for many applications superficial amounts of BMP2 were required for efficacy due to the absence of sustained release carriers and severe side effects have reported thereby limiting the use of BMP2. Here we present an alternative method based on the use of a combination of low molecular weight compounds, testosterone and alendronate, with established safety profiles in men. Moreover, in contrast to BMP2 which activates both osteoblasts and osteoclasts, this combination of drugs enhances osteoblast activity but simultaneously inhibits osteoclast activity resulting in a net effect of bone growth.
Human primary osteoblasts were obtained from bone of patients requiring knee prostheses and cultured in the presence of various concentrations testosterone with and without alendronate. Optimal concentrations were selected and used to stimulate 5×8 mm porcine bone biopsies for 4 weeks. Medium was exchanged regularly and ALP activity was determined. At endpoint biopsies were analyzed in a MicroCT (Bruker Skyscan 1076) to analyze bone volume (BV), trabecular thickness (Tb.Th) and tissue volume (TV). Bone strength was measured using Hounsfield (H10KT) test equipment.
The data obtained showed a significant and dose dependent increase in ALP activity of primary osteoblasts (day 7–10) indicating robust activation of osteoblast activity. Optimal and synergistic ALP activation was observed when treating cells with 15–375 nM testosterone in combination with 2 μM alendronate. Significant inhibition (75%) of osteoclast activity was observed by alendronate (2–10 μM) which was further enhanced by high testosterone levels. This concept was further tested in bovine bone biopsies cultured for 4 weeks in the presence of 75 nM testosterone and 2 μM alendronate. MicroCT analysis of the biopsies revealed a ± 40% increase in both bone volume (trabecular and cortical bone) and bone strength. Moreover bone mineral density was increased by 20% indicating increased mineralization of bone tissue.
Treatment of human primary osteoblasts or human or bovine bone explants with a combination of an androgen (testosterone) and a bisphosphonate (alendronate) significantly enhance bone growth and bone mineral density. Moreover, bone strength was increased indicating the formation of high quality bone tissue. These findings are the basis for the development of sustained release materials to be applied locally at the bone fracture site, which would allow for low amounts of the drugs and no systemic exposure. By encapsulating testosterone and alendronate in a biodegradable polymer coating, a sustained release up to 5 weeks can be achieved, and the loaded coating can be applied in combination with collagen membranes to improve bone healing or as a coating onto implants to improve osseo-integration.
