부산대학교 도서관

Due to the damage of scalp because of chemical dyes, increasing attention had been paid to the ecological dyeingof human hair. To address the need for ecological restoration and dyeing of human hair, herein, a novel approach has beenproposed via laccase-mediated in situ oxidation of dihydroxy phenylalanine (dopamine). As laccase can catalyze dopamineoxidation and then polymerization to produce strongly colored polymers, different biological coloration processes of humanhair based on this process were investigated: (i) Human hair was treated with laccase alone; (ii) The absorption of human hairwith dopamine, followed by further catalysis of air; (iii) The absorption of human hair with dopamine, followed by furthercatalysis of laccase; (iv) Simultaneous laccase-mediated polymerization and dyeing of human hair; and (v) Polymerization ofDopamine with laccase and then dyeing human hair. The surface properties of dyed hair were evaluated in terms of ultraviolet(UV)-protection, color fastness, Fourier transforming infrared spectrum (FT-IR), optical microscope, and scanning electronmicroscopy (SEM). The results show that best hair dyeing effect was achieved via simultaneous laccase-mediatedpolymerization and dyeing. The dyed hair obtained K/S values of 28, light fastness of level 5, and UPF of 100+. The opticalmicroscope and SEM observations show that the surface of colored hair fibers was covered with thin burrs, which can beattributed to polydopamine attached with physical adhesive force and covalent reaction. FT-IR analysis shows that functionalgroups were present on the surface of the dyed hair which can be considered as introduction of hydroxyl radical groups. Thisbiological stain technique may be widely used in dyeing of hair with black color.