Osteogenic potential of nanostructured Cu/W/Co in Fe-Mn alloys designed for maxillofacial applications: in vivo study in dog model.

To investigate osteogenic potential of biodegradable nanostructured Cu/W/Co in Fe-Mn alloys for maxillofacial applications in an in vivo model. Nanostructured FeMn(35), FeMn(32)Cu(3), FeMn(32)W(3,) FeMn(32)Co(3) alloys were fabricated. Ten mongrel dogs were included where five mandibular defects were induced in each dog. Defects were randomly allocated into 5 groups ((M) control defects covered by bone disc, (M0) implanted by FeMn(35) alloy, (M1) implanted by FeMn(32)Cu(3) alloy, (M2) implanted by FeMn(32)W(3) alloy, (M3) implanted by FeMn(32)Co(3) alloy). Dogs were euthanized at 12 weeks for cone beam computed tomography, histologic and immunohistologic evaluation, and gene expression of osteopontin and osteocalcin. Defects implanted with metal demonstrated thicker bone trabeculae mixed with lamellar bone while control defects (M) demonestrated immature woven bone. Quantitative evaluation of bone area %, area % of mature bone and expression of osteopentin and osteocalcin bone markers revealed a statistically significant highest bone area % and maturation in group M3 compared to M2, M1, M0, and M group. A statistically significant increase in bone area % and maturation was recorded in M2 group compared to M1, M0, and M groups. A significantly increased bone area % and maturation was recorded in M1 compared to control M group and also between M0 and M group. Incorporating Cu/W/Co into Fe-Mn alloys enhanced biocompatibility and improved bone regeneration suggesting its suitability for use in various orthopedic and dental applications. Biodegradable metal alloys could improve patient outcome, reduce the need for additional surgeries to remove nonbiodegradble implants. Biodegradable metal alloys could improve patient outcome, reduce the need for additional surgeries to remove nonbiodegradble implants.