The piezoelectric effect of biological piezoelectric materials promotes bone growth. However, the material should be subjected to stress before it can produce an electric charge that promotes bone repair and reconstruction conducive to fracture healing. A novel method for in vitro experimentation of biological piezoelectric materials with physiological load is presented. A dynamic loading device that can simulate the force of human motion and provide periodic load to piezoelectric materials when co-cultured with cells was designed to obtain a realistic expression of piezoelectric effect on bone repair. Hydroxyapatite (HA)/barium titanate (BaTiO3) composite materials were fabricated by slip casting, and their piezoelectric properties were obtained by polarization. The d33 of HA/BaTiO3 piezoelectric ceramics after polarization was 1.3 pC/N to 6.8 pC/N with BaTiO3 content ranging from 80% to 100%. The in vitro biological properties of piezoelectric bioceramics with and without cycle loading were investigated. When HA/BaTiO3 piezoelectric bioceramics were affected by cycle loading, the piezoelectric effect of BaTiO3 promoted the growth of osteoblasts and interaction with HA, which was better than the effect of HA alone. The best biocompatibility and bone-inducing activity were demonstrated by the 10%HA/90%BaTiO3 piezoelectric ceramics.
Bone
defect repair at load-bearing sites is a challenging clinical
problem for orthopedists. Defect reconstruction with implants is the
most common treatment; however, it requires the implant to have good
mechanical properties and the capacity to promote bone formation.
In recent years, the piezoelectric effect, in which electrical activity
can be generated due to mechanical deformation, of native bone, which
promotes bone formation, has been increasingly valued. Therefore,
implants with piezoelectric effects have also attracted great attention
from orthopedists. In this study, we developed a bioactive composite
scaffold consisting of BaTiO3, a piezoelectric ceramic
material, coated on porous Ti6Al4V. This composite scaffold showed
not only appropriate mechanical properties, sufficient bone and blood
vessel ingrowth space, and a suitable material surface topography
but also a reconstructed electromagnetic microenvironment. The osteoconductive
and osteoinductive properties of the scaffold were reflected by the
proliferation, migration, and osteogenic differentiation of mesenchymal
stem cells. The ability of the scaffold to support vascularization
was reflected by the proliferation and migration of human umbilical
vein endothelial cells and their secretion of VEGF and PDGF-BB. A
well-established sheep spinal fusion model was used to evaluate bony
fusion in vivo. Sheep underwent implantation with different scaffolds,
and X-ray, micro-computed tomography, van Gieson staining, and elemental
energy-dispersive spectroscopy were used to analyze bone formation.
Isolated cervical angiography and visualization analysis were used
to assess angiogenesis at 4 and 8 months after transplantation. The
results of cellular and animal studies showed that the piezoelectric
effect could significantly reinforce osteogenesis and angiogenesis.
Furthermore, we also discuss the molecular mechanism by which the
piezoelectric effect promotes osteogenic differentiation and vascularization.
In summary, Ti6Al4V scaffold coated with BaTiO3 is a promising
composite biomaterial for repairing bone defects, especially at load-bearing
sites, that may have great clinical translation potential.
Ultrafine-grained pure titanium prepared by equal-channel angular pressing has favorable mechanical performance and does not contain alloy elements that are toxic to the human body. It has potential clinical value in applications such as cardiac valve prostheses, vascular stents, and hip prostheses. To overcome the material’s inherent thrombogenicity, surface-coating modification is a crucial pathway to enhancing blood compatibility. An electrolyte solution of sodium silicate + sodium polyphosphate + calcium acetate and the micro-arc oxidation (MAO) technique were employed for in situ oxidation of an ultrafine-grained pure titanium surface. A porous coating with anatase- and rutile-phase TiO2 was generated and wettability and blood compatibility were examined. The results showed that, in comparison with ultrafine-grained pure titanium substrate, the MAO coating had a rougher surface, smaller contact angles for distilled water and higher surface energy. MAO modification effectively reduced the hemolysis rate; extended the dynamic coagulation time, prothrombin time (PT), and activated partial thromboplastin time (APTT); reduced the amount of platelet adhesion and the degree of deformation; and enhanced blood compatibility. In particular, the sample with an oxidation time of 9 min possessed the highest surface energy, largest PT and APTT values, smallest hemolysis rate, less platelet adhesion, a lesser degree of deformation, and more favorable blood compatibility. The MAO method can significantly enhance the blood compatibility of ultrafine-grained pure titanium, increasing its potential for practical applications.
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