Hybrids, consisting of two constituents (primarily inorganic and organic phases) at the nanometer or molecular level, have recently emerged as advanced biomaterials for regenerative medicine applications. Hybrids usually show characteristics in between the two original phases or even exhibit unique physical, chemical, mechanical and biological properties. Many attempts have been dedicated to design and synthesize novel hybrid biomaterials with several concurrent features, such as favorable mechanical properties for tissue growth support, and desired biological response to favor the regeneration of damaged tissues.
The aim of the current Research Topic is to report promising, recent, and novel research in the field of hybrids for tissue regeneration applications. Hybrids are attracting increasing attention as new biomaterials and also as promising building blocks of advanced medical devices for the regeneration of various tissues (e.g. bone, skin). However, many challenges still exist, for example:
- Rational design of inorganic/organic phases toward controlled overall mechanical and biological properties
- Controlling the biodegradation of hybrids
- Modulating inflammatory response induced by hybrids
- Controlling the osteogenic, angiogenic and antimicrobial properties of hybrids
Types of manuscripts to be featured mainly include Original Research and Perspective articles. Review articles that describe the current state-of-the-art in hybrids for specific tissue regeneration (e.g. hybrids for bone regeneration and wound healing) are welcome.
Topics to be investigated in this collection may include (but are not limited to):
• Novel approaches for hybrids synthesis
• Bioactive hybrids (e.g. based on bioactive ceramics, bioactive glasses and biostable or biodegradable polymers; based on substances of natural origin) for tissue regeneration
• Hybrid nanoparticles as building blocks of scaffolds in tissue engineering
• Multifunctional hybrid coatings (e.g. antibacterial, pro-osteogenic, angiogenic, self-healing)
• Cellular response and protein interaction with hybrids
• In vivo behaviour of hybrids in animal models
Hybrids, consisting of two constituents (primarily inorganic and organic phases) at the nanometer or molecular level, have recently emerged as advanced biomaterials for regenerative medicine applications. Hybrids usually show characteristics in between the two original phases or even exhibit unique physical, chemical, mechanical and biological properties. Many attempts have been dedicated to design and synthesize novel hybrid biomaterials with several concurrent features, such as favorable mechanical properties for tissue growth support, and desired biological response to favor the regeneration of damaged tissues.
The aim of the current Research Topic is to report promising, recent, and novel research in the field of hybrids for tissue regeneration applications. Hybrids are attracting increasing attention as new biomaterials and also as promising building blocks of advanced medical devices for the regeneration of various tissues (e.g. bone, skin). However, many challenges still exist, for example:
- Rational design of inorganic/organic phases toward controlled overall mechanical and biological properties
- Controlling the biodegradation of hybrids
- Modulating inflammatory response induced by hybrids
- Controlling the osteogenic, angiogenic and antimicrobial properties of hybrids
Types of manuscripts to be featured mainly include Original Research and Perspective articles. Review articles that describe the current state-of-the-art in hybrids for specific tissue regeneration (e.g. hybrids for bone regeneration and wound healing) are welcome.
Topics to be investigated in this collection may include (but are not limited to):
• Novel approaches for hybrids synthesis
• Bioactive hybrids (e.g. based on bioactive ceramics, bioactive glasses and biostable or biodegradable polymers; based on substances of natural origin) for tissue regeneration
• Hybrid nanoparticles as building blocks of scaffolds in tissue engineering
• Multifunctional hybrid coatings (e.g. antibacterial, pro-osteogenic, angiogenic, self-healing)
• Cellular response and protein interaction with hybrids
• In vivo behaviour of hybrids in animal models
