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Electrospinning technology has shown great potential in the biomedical field, especially in tissue engineering. Professor Mo Xiumei of Donghua University mentioned in her research that 3D electrospinning nanofiber scaffolds are committed to more precise spatial control, giving the scaffolds sufficient porosity and a 3D environment similar to that set up in the body, and optimizing performance, including injectability, compressibility, and bioactivity. This echoes the design inspiration of biomimetic hydrogels, which enhance the interfacial interaction with biological tissues by simulating natural moisturizing factors and biomineral ions, providing effective biocompatible materials for skin anti-aging treatment.
Electrospinning technology can produce nanofibers with unique structures and functions, which have opened up countless possibilities in the fields of materials science, biomedicine, etc. Research by Professor Xie Jingwei's team at the University of Nebraska Medical Center in the United States
Summarizes the latest research progress of electrospun nanofiber materials, emphasizing their modification, unique structure, integration with other technologies, and a variety of biomedical applications. Bionic hydrogels also show multifunctionality. They not only have good water-locking ability, but also have bioprotection and biocompatibility, providing an excellent material platform for ionic skin and intelligent treatment diagnosis.
Electrospinning technology has a wide range of applications in the field of ionic skin and flexible electronics. The research of Zhang Ting's team at the Suzhou Institute of Nanotechnology, Chinese Academy of Sciences
mentioned that electrospun fiber flexible electronics have many application scenarios, including detection of human biophysical signals, biochemical signals, bioelectric signals and implantable bioelectronics for promoting cell and tissue regeneration. Bionic hydrogels also show potential in these applications. They can act as intelligent interfaces to generate electrical signals through internal flow and spatial distribution of biomineral ions, promoting information exchange between biological tissues and the external environment.
The application of electrospinning technology in non-invasive medical technology is also an important research direction. The research of Professor Seeram Ramakrishna of the National University of Singapore
discusses the application of electrospinning technology in wound dressings and tissue engineering scaffolds. Bionic hydrogels can be used as an ideal choice for non-invasive medical technology and materials due to their high transparency, ionic conductivity and multi-sensory capabilities, providing new solutions for skin anti-aging treatment.
Researchers in electrospinning technology are exploring new polymer systems to optimize the performance and application of fibers. This is consistent with the design goal of bionic hydrogels, that is, through the combination of natural moisturizing factors and biomineral ions, the water-responsive self-contraction ability and signal transmission function of the material are realized, providing innovative material options for skin anti-aging and ionic skin applications.
In summary, electrospinning technology and bionic hydrogels are closely related in skin anti-aging treatment and ionic skin applications. Both use the unique advantages of electrospinning technology to develop new materials with biocompatibility, bioprotection and multifunctionality, providing broad application prospects for future medical care and human-computer interaction.
Electrospinning Nanofibers Article Source:
https://doi.org/10.1002/adfm.202008020
