Silica aerogel8/2/2023 ![]() Leventis and MM Koebel (Springer, New York, 2011)į. Piletska et al., Biomimetic silica nanoparticles prepared by a combination of solid-phase imprinting and Ostwald ripening. Smitha et al., Effect of aging time and concentration of aging solution on the porosity characteristics of subcritically dried silica aerogels. Erkey, An emerging platform for drug delivery: aerogel based systems. Barrios et al., Nanomaterials in advanced, high-performance aerogel composites: a review. Hamidi et al., Antibacterial activity of natural polymer gels and potential applications without synthetic antibiotics. Bokov et al., Nanomaterial by sol-gel method: synthesis and application. Wan et al., Functional nanocomposites from sustainable regenerated cellulose aerogels: a review. Maleki et al., Synthesis and biomedical applications of aerogels: possibilities and challenges. Jin, Carbon aerogels based on regenerated silk proteins and graphene oxide for supercapacitors. Park, Hierarchical structured, nitrogen-incorporated graphene aerogel for high performance supercapacitor. Song, Multiple energy harvesting based on reversed temperature difference between graphene aerogel filled phase change materials. Song, Modification of graphene aerogel embedded form-stable phase change materials for high energy harvesting efficiency. Kim et al., Semi-rigid polyurethane foam and polymethylsilsesquioxane aerogel composite for thermal insulation and sound absorption. Mertah et al., Multifunctional composite aerogels-as micropollutant scavengers. Qi et al., Thermal protective performance of aerogel embedded firefighter’s protective clothing. Koebel, Aerogels Handbook (Springer, New York, 2011) Li et al., Sol–gel coating of inorganic nanostructures with resorcinol–formaldehyde resin. Pajonk, Chemistry of aerogels and their applications. ![]() Hair et al., Low-density resorcinol–formaldehyde aerogels for direct-drive laser inertial confinement fusion targets. Scherer (Taylor & Francis, United Kingdom, 1994), pp. In: Material and Manufacturing Process, vol. Klein, A review of: “Sol-Gel Science-The Physics and Chemistry of Sol-Gel Processing”. In Proceedings of the Nanocon (2014), pp. Venkataraman, et al., Acoustic properties of aerogel embedded nonwoven fabrics. Gurav et al., Silica aerogel: synthesis and applications. Kistler, Coherent expanded aerogels and jellies. Keefer, Structure of random porous materials: silica aerogel. Esquivel-Castro et al., Porous aerogel and core/shell nanoparticles for controlled drug delivery: a review. The present study focuses on the basic concepts and recent advances in silica-based aerogels in the biomedical field.īiomedical applications of silica-based aerogels Hence, this review summarizes biomedical applications of silica-based aerogels and discusses the potential toxicity induced by them. In this review, we intend to provide up-to-date information on silica-based aerogels and applications in biomedicine. Engaging with materials whose characteristics can be customized is very important in the medical field. So, it is essential to know how to design and synthesize nanoscale structures for medical and biological applications. Minimal toxicity and maximum biodegradability are two important future challenging issues related to the interaction of (nano) materials and biological systems. Some of these important issues include toxicity, bioactivity, compatibility, and so on. Many vital and key issues in the field of (nano) material applications, especially their usages in biomedicine, should be investigated before clinical applications. Recent advances in silica-based aerogels as well-known porous materials have had a great impact on extensive application in various fields mostly in high-tech science and engineering, and biomedical usages, including environmental control, tissue engineering, cancer diagnosis, cancer therapy, biomarking, and drug delivery. ![]() In addition to their prominent features, these materials are very attractive despite the possibility of changing their chemical composition according to the desired applications. From a nanotechnologist's perspective, silica aerogels will have a special place in nanotechnology because they have low density, large surface area and nanometer pores, and the size of their pores can be adjusted in different ways. Silica-based aerogels are prepared from silica gels where the liquid is drawn out of the network structure so that its three-dimensional structure is not disturbed. ![]() Silica-based aerogels are the appropriate and well-known porous materials that have become interesting in science and technology, especially in the biomedical community. ![]()
0 Comments
Leave a Reply.AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |