Recent advances in laser-induced-graphene-based soft skin electronics for intelligent healthcare review the development and applications of laser-induced-graphene (LIG) in soft skin electronics for healthcare. LIG is a promising material for soft skin electronics due to its lightweight, compact size, biocompatibility, and high conductivity. The review discusses the preparation methods, properties, and regulation strategies of LIG for soft skin electronics. It also covers various applications of LIG-based soft skin electronics, including biophysical and biochemical sensors, bio-actuators, and power supply systems. The review highlights the potential challenges and future directions for research and development in LIG-based soft skin electronics for intelligent healthcare. The review emphasizes the importance of LIG in advancing intelligent healthcare technologies by enabling precise and timely capture of physiological cues at the skin interface. The review also discusses the biocompatibility and antibacterial properties of LIG, which make it suitable for use in healthcare applications. The review concludes that LIG-based soft skin electronics have significant potential for advancing intelligent healthcare technologies.Recent advances in laser-induced-graphene-based soft skin electronics for intelligent healthcare review the development and applications of laser-induced-graphene (LIG) in soft skin electronics for healthcare. LIG is a promising material for soft skin electronics due to its lightweight, compact size, biocompatibility, and high conductivity. The review discusses the preparation methods, properties, and regulation strategies of LIG for soft skin electronics. It also covers various applications of LIG-based soft skin electronics, including biophysical and biochemical sensors, bio-actuators, and power supply systems. The review highlights the potential challenges and future directions for research and development in LIG-based soft skin electronics for intelligent healthcare. The review emphasizes the importance of LIG in advancing intelligent healthcare technologies by enabling precise and timely capture of physiological cues at the skin interface. The review also discusses the biocompatibility and antibacterial properties of LIG, which make it suitable for use in healthcare applications. The review concludes that LIG-based soft skin electronics have significant potential for advancing intelligent healthcare technologies.