Advancing cosmetic dermatology and wound healing: The synergy of laser therapies and artificial intelligence

Summary: Abstract Body: Recent advancements in laser therapies and artificial intelligence (AI) are innovating cosmetic dermatology and wound healing. Laser treatments such as fractional resurfacing, intense pulsed light (IPL), low-level laser therapy (LLLT), and high-intensity laser therapy (HILT) effectively promote collagen production, enhance skin texture, and accelerate wound healing. These lasers use specific wavelengths to target different stages of the wound healing process, improving cellular functions like angiogenesis, epithelialization, and collagen synthesis while modulating inflammation and boosting microcirculation. Artificial Intelligence is playing an increasingly significant role in shaping the field of cosmetic dermatology, especially in wound healing. This review explores how AI enhances treatment personalization and optimizes outcomes, complementing the advancements provided by laser therapies. By integrating AI, laser treatments can be dynamically adjusted based on real-time data, improving precision and reducing the risk of adverse effects. This synergy between laser therapies and AI opens new possibilities for personalized care, where algorithms can adapt treatments based on individual responses, ensuring more efficient and targeted results. Ongoing research is improving cosmetic dermatology and regenerative skincare, offering patients more effective, accessible, and personalized solutions. Future directions emphasize the integration of AI in cosmetic dermatology and wound healing procedures and its role in enhancing the overall patient experience. This review emphasizes the modernizing potential of combining laser therapies with AI, showcasing how their integration can advance wound healing and skin rejuvenation, offering patients more effective and efficient treatment options. Donia Javidi¹ 1. California Health Sciences University College of Osteopathic Medicine, Clovis, CA, United States. Stem Cell Biology, Tissue Regeneration and Wound Healing