TY - JOUR
T1 - Impact of Biomimicry in the Design of Osteoinductive Bone Substitutes: Nanoscale Matters
AU - Barba, Albert
AU - Diez-Escudero, Anna
AU - Espanol, Montserrat
AU - Bonany, Mar
AU - Sadowska, Joanna Maria
AU - Guillem-Marti, Jordi
AU - Öhman-Mägi, Caroline
AU - Persson, Cecilia
AU - Manzanares, Maria Cristina
AU - Franch, Jordi
AU - Ginebra, Maria Pau
PY - 2019/3/6
Y1 - 2019/3/6
N2 - © 2019 American Chemical Society. Bone apatite consists of carbonated calcium-deficient hydroxyapatite (CDHA) nanocrystals. Biomimetic routes allow fabricating synthetic bone grafts that mimic biological apatite. In this work, we explored the role of two distinctive features of biomimetic apatites, namely, nanocrystal morphology (plate vs needle-like crystals) and carbonate content, on the bone regeneration potential of CDHA scaffolds in an in vivo canine model. Both ectopic bone formation and scaffold degradation were drastically affected by the nanocrystal morphology after intramuscular implantation. Fine-CDHA foams with needle-like nanocrystals, comparable in size to bone mineral, showed a markedly higher osteoinductive potential and a superior degradation than chemically identical coarse-CDHA foams with larger plate-shaped crystals. These findings correlated well with the superior bone-healing capacity showed by the fine-CDHA scaffolds when implanted intraosseously. Moreover, carbonate doping of CDHA, which resulted in small plate-shaped nanocrystals, accelerated both the intrinsic osteoinduction and the bone healing capacity, and significantly increased the cell-mediated resorption. These results suggest that tuning the chemical composition and the nanostructural features may allow the material to enter the physiological bone remodeling cycle, promoting a tight synchronization between scaffold degradation and bone formation.
AB - © 2019 American Chemical Society. Bone apatite consists of carbonated calcium-deficient hydroxyapatite (CDHA) nanocrystals. Biomimetic routes allow fabricating synthetic bone grafts that mimic biological apatite. In this work, we explored the role of two distinctive features of biomimetic apatites, namely, nanocrystal morphology (plate vs needle-like crystals) and carbonate content, on the bone regeneration potential of CDHA scaffolds in an in vivo canine model. Both ectopic bone formation and scaffold degradation were drastically affected by the nanocrystal morphology after intramuscular implantation. Fine-CDHA foams with needle-like nanocrystals, comparable in size to bone mineral, showed a markedly higher osteoinductive potential and a superior degradation than chemically identical coarse-CDHA foams with larger plate-shaped crystals. These findings correlated well with the superior bone-healing capacity showed by the fine-CDHA scaffolds when implanted intraosseously. Moreover, carbonate doping of CDHA, which resulted in small plate-shaped nanocrystals, accelerated both the intrinsic osteoinduction and the bone healing capacity, and significantly increased the cell-mediated resorption. These results suggest that tuning the chemical composition and the nanostructural features may allow the material to enter the physiological bone remodeling cycle, promoting a tight synchronization between scaffold degradation and bone formation.
KW - biomimetic
KW - calcium phosphate
KW - carbonated apatite
KW - foaming
KW - nanostructure
KW - osteogenesis
KW - osteoinduction
KW - Bone and Bones/diagnostic imaging
KW - X-Ray Microtomography
KW - Mesenchymal Stem Cells/cytology
KW - Osteoblasts/cytology
KW - Durapatite/chemistry
KW - Bone Substitutes/chemistry
KW - Cell Differentiation/drug effects
KW - Cell Adhesion/drug effects
KW - Cells, Cultured
KW - Rats
KW - Bone Regeneration
KW - Osteogenesis/drug effects
KW - Biomimetic Materials/chemistry
KW - Animals
KW - Dogs
KW - Nanoparticles/chemistry
KW - Tissue Scaffolds/chemistry
KW - Osteocalcin/metabolism
KW - Mesenchymal Stem Cell Transplantation
UR - http://www.mendeley.com/research/impact-biomimicry-design-osteoinductive-bone-substitutes-nanoscale-matters
U2 - 10.1021/acsami.8b20749
DO - 10.1021/acsami.8b20749
M3 - Article
C2 - 30740968
SN - 1944-8244
VL - 11
SP - 8818
EP - 8830
JO - ACS Applied Materials and Interfaces
JF - ACS Applied Materials and Interfaces
ER -