In recent years, nanofibrous biomaterials produced by electrospinning or other advanced technologies have been extensively studied in the field of tissue engineering and regenerative medicine. They have great similarity in structure with the extracellular matrix, high porosity, and large specific surface area, which can promote cell proliferation, differentiation, and migration and thus achieve good tissue repair performance. By developing nanofiber biomaterials with well-defined topography and microstructure and incorporating bioactive reagents (growth factors, drugs, etc.), various nanofiber biomaterials have been developed to provide a suitable microenvironment for tissue growth, and they have been widely used for the regeneration of soft (skin, tendons, muscles, nerves, etc.) and hard tissue (bones, teeth) regeneration.
We invite experts to contribute to this research topic to discuss the improvements in the design and fabrication of novel nanofibrous structures and explore the potential of nanofibrous biomaterials for various biomedical applications.
The scope of research topics includes nanofibrous biomaterials for soft tissue repair, hard tissue regeneration, etc. The areas addressed in this research topic include, but are not limited to:
- New bioinks for nanofibrous fabrication.
- New techniques for the fabrication of nanofibrous biomaterials.
- Combination of electrospinning with other advanced techniques.
- Novel characterization techniques for nanofibrous structures.
- Novel nanofibrous structures and their biological effects.
- Nanofibrous biomaterials including (not limited to) nanofibrous membranes, nanofibrous aerogels, and nanofibrous materials loaded with bioactive agents.
- Cell interactions with nanofibrous biomaterials.
- Nanofibrous biomaterials for tissue repair.
- Nanofibrous biomaterials for disease diagnosis.
Clinical case reports and evidence-based medicine reports are not within the scope of this topic.
In recent years, nanofibrous biomaterials produced by electrospinning or other advanced technologies have been extensively studied in the field of tissue engineering and regenerative medicine. They have great similarity in structure with the extracellular matrix, high porosity, and large specific surface area, which can promote cell proliferation, differentiation, and migration and thus achieve good tissue repair performance. By developing nanofiber biomaterials with well-defined topography and microstructure and incorporating bioactive reagents (growth factors, drugs, etc.), various nanofiber biomaterials have been developed to provide a suitable microenvironment for tissue growth, and they have been widely used for the regeneration of soft (skin, tendons, muscles, nerves, etc.) and hard tissue (bones, teeth) regeneration.
We invite experts to contribute to this research topic to discuss the improvements in the design and fabrication of novel nanofibrous structures and explore the potential of nanofibrous biomaterials for various biomedical applications.
The scope of research topics includes nanofibrous biomaterials for soft tissue repair, hard tissue regeneration, etc. The areas addressed in this research topic include, but are not limited to:
- New bioinks for nanofibrous fabrication.
- New techniques for the fabrication of nanofibrous biomaterials.
- Combination of electrospinning with other advanced techniques.
- Novel characterization techniques for nanofibrous structures.
- Novel nanofibrous structures and their biological effects.
- Nanofibrous biomaterials including (not limited to) nanofibrous membranes, nanofibrous aerogels, and nanofibrous materials loaded with bioactive agents.
- Cell interactions with nanofibrous biomaterials.
- Nanofibrous biomaterials for tissue repair.
- Nanofibrous biomaterials for disease diagnosis.
Clinical case reports and evidence-based medicine reports are not within the scope of this topic.