research Engineered building bloks to print endogenous tissue and complex organs in vitro
New bio-ink can print complex tissues and organs.
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990-1000 / 1000+ resultsresearch Therapeutic and Diagnostic Applications of Nanotechnology in Dermatology and Cosmetics
Nanotechnology is improving skin treatments and cosmetics.
research Hyperbranched polymer dots enhance hair follicle regeneration via Wnt/β-catenin activation: A drug-free nanozyme-based approach to hair growth therapy
Hyperbranched polymer dots significantly boost hair regrowth better than minoxidil.
research Polymeric micelle mediated follicular delivery of spironolactone: Targeting the mineralocorticoid receptor to prevent glucocorticoid-induced activation and delayed cutaneous wound healing
Using polymeric micelles to deliver spironolactone topically could improve wound healing in skin affected by glucocorticoids.
research Three-dimensional microvascular organization around hair follicles as revealed by FITC-dextran injection method
research Nanoparticle systems reduce systemic toxicity in cancer treatment
Nanoparticle systems make cancer treatment less toxic.
research Novel iron oxide nanocarriers loading finasteride or dutasteride: Enhanced skin penetration for topical treatment of alopecia
Iron oxide nanoparticles improve skin penetration and drug release for hair loss treatment.
research A Randomised Controlled Single Observer Blinded Study To Determine The Efficacy Of Topical Minoxidil Plus Microneedling Versus Topical Minoxidil In The Treatment Of Androgenetic Alopecia
Combining minoxidil with microneedling leads to better hair regrowth than using minoxidil alone.
research The efficacy of topical cetirizine using microneedling in androgenetic alopecia male patients
Topical cetirizine with microneedling effectively promotes hair growth in men with androgenetic alopecia.
research Autonomous In Situ Biointerfacing Platform for Real-Time Electrophysiological Monitoring and Advanced Wound Management
The study presents the development of the TLMG hydrogel, a biointerface platform that forms in situ and adheres robustly to irregular skin wounds, offering enhanced mechanical properties and real-time signal monitoring for advanced wound management. By integrating tea polyphenols/lignin microspheres, the hydrogel combines bioelectronic and bioactive interfaces, achieving strong adhesion (200 kPa), high ionic conductivity (0.27 mS cm–1), and mechanical stability. Tested in complex animal models and human trials, the TLMG platform demonstrated intelligent wound management, dynamic signal monitoring, and improved wound healing through immunomodulatory mechanisms, highlighting its potential for wearable healthcare systems.