The two faces of titanium dioxide nanoparticles bio-camouflage in 3D bone spheroids.
W SouzaS G PiperniP LaviolaA L RossiMaria Isabel D RossiBráulio S ArchanjoPaulo Emílio Côrrea LeiteM H FernandesL A RochaJ M GranjeiroAna Rosa Lopes Pereira RibeiroPublished in: Scientific reports (2019)
Titanium (Ti) and its alloys are widely used in dental implants and hip-prostheses due to their excellent biocompatibility. Growing evidence support that surface degradation due to corrosion and wear processes, contribute to implant failure, since the release of metallic ions and wear particles generate local tissue reactions (peri-implant inflammatory reactions). The generated ions and wear debris (particles at the micron and nanoscale) stay, in a first moment, at the interface implant-bone. However, depending on their size, they can enter blood circulation possibly contributing to systemic reactions and toxicities. Most of the nanotoxicological studies with titanium dioxide nanoparticles (TiO2 NPs) use conventional two-dimensional cell culture monolayers to explore macrophage and monocyte activation, where limited information regarding bone cells is available. Recently three-dimensional models have been gaining prominence since they present a greater anatomical and physiological relevance. Taking this into consideration, in this work we developed a human osteoblast-like spheroid model, which closely mimics bone cell-cell interactions, providing a more realistic scenario for nanotoxicological studies. The treatment of spheroids with different concentrations of TiO2 NPs during 72 h did not change their viability significantly. Though, higher concentrations of TiO2 NPs influenced osteoblast cell cycle without interfering in their ability to differentiate and mineralize. For higher concentration of TiO2 NPs, collagen deposition and pro-inflammatory cytokine, chemokine and growth factor secretion (involved in osteolysis and bone homeostasis) increased. These results raise the possible use of this model in nanotoxicological studies of osseointegrated devices and demonstrate a possible therapeutic potential of this TiO2 NPs to prevent or reverse bone resorption.
Keyphrases
- bone mineral density
- soft tissue
- bone regeneration
- cell cycle
- quantum dots
- bone loss
- growth factor
- endothelial cells
- cell proliferation
- visible light
- postmenopausal women
- oxidative stress
- induced apoptosis
- mass spectrometry
- healthcare
- case control
- single cell
- immune response
- social media
- dendritic cells
- peripheral blood
- mesenchymal stem cells
- cell death
- health information
- combination therapy
- induced pluripotent stem cells