Artificial Skin refers to synthetic materials designed to mimic the structure and function of natural skin for medical, cosmetic, and research purposes. These materials aim to replicate the complex properties of skin, including its protective barrier, elasticity, and regenerative capabilities. One common application of artificial skin is in wound healing and burn treatments. These skin substitutes provide a temporary covering for wounds, promoting healing and minimizing infection risk. Some artificial skin products incorporate bioengineered cells to enhance the regenerative process. Researchers use artificial skin models for testing pharmaceuticals, cosmetics, and various dermatological applications. These models enable the evaluation of product safety, efficacy, and potential irritations without the need for animal or human testing. In the field of robotics, artificial skin is utilized to enhance the tactile sensitivity of robotic devices, allowing them to perceive and respond to external stimuli. This technology holds promise in creating more human-like interactions between machines and the environment. Advancements in tissue engineering have led to the development of bioengineered skin grafts, incorporating living cells to promote healing and tissue regeneration. These grafts are increasingly used in reconstructive surgery and treating extensive burns. Artificial skin is a dynamic and evolving field, with ongoing research focused on improving its functionality, biocompatibility, and integration with the human body. The development of sophisticated artificial skin holds great potential for addressing medical challenges and advancing technology in diverse fields.
Title : AI-integrated high-throughput tissue-chip for space-based biomanufacturing applications
Kunal Mitra, Florida Tech, United States
Title : Will be updated soon...
Vasiliki E Kalodimou, European University-Cyprus Ltd, Cyprus
Title : Will be updated soon...
Nagy Habib, Imperial College London, United Kingdom
Title : Will be updated soon...
Alexander Seifalian, Nanotechnology & Regenerative Medicine Commercialisation Centre, United Kingdom
Title : Advanced 3D tissue models: Pioneering tools for investigating health and disease
Lucie Bacakova, Institute of Physiology of the Czech Academy of Sciences, Czech Republic
Title : Developing iPSC-derived 3D Outer Blood-Retinal Barrier Disease Models of Choroideremia for Gene Therapy Evaluation
Aradhana Kasimsetty, National Center for Advancing Translational Sciences (NCATS), National Institutes of Health (NIH), United States