Electroactive Melanin Tattoo Inks for Effectively Reducing Skin Impedances

초록

High skin impedance presents a significant challenge to the power efficiency and spatial resolution of noninvasive, wearable bioelectronics, leading to poor signal quality and unreliable data acquisition. To address this problem, various efforts have been made, ranging from surface treatments for the skin and electrolytic gels to advanced electrode materials and signal processing techniques. This research introduces an effective approach to reduce skin impedance using naturally derived melanin nanoparticles (MNPs), formulated as a penetrative conductive tattoo ink. Comparative analyses of charge transport properties were conducted among MNPs, poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) conductive polymers, and traditional nanocarbon black tattoo inks. These were assessed for their efficacy in enhancing skin conductivity using hydrogels and porcine skin models. Results from electrochemical impedance spectroscopy indicated that MNP ink notably surpassed alternative materials, showcasing a synergistic effect in electronic-ionic hybrid charge transport. The biologically sourced MNP conductive ink holds promise for transforming the integration between wearable devices and the human body, ensuring minimal signal loss through the insulating layers of skin. Consequently, this could provide wearable bioelectronics functionally parallel to implantable devices, expanding their utility in a broader spectrum of bionic applications.

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