Maho Mimuro1,Sunghoon Lee1,Tomoyuki Yokota1,Takao Someya1
The University of Tokyo1
Maho Mimuro1,Sunghoon Lee1,Tomoyuki Yokota1,Takao Someya1
The University of Tokyo1
Electrodermal activity, which is known to vary due to various factors such as psychological states like stress level [1], and environmental factors like temperature [2] and humidity [3] is one of the important biological signals for early detection of disease and preventive healthcare. Previously, ultrathin and lightweight Au-PVA nanomesh electrode which does not cause discomfort when they were attached on skin has been developed [4] and continuous measurement of skin resistance and skin impedance were achieved by using the nanomesh electrodes [5, 6]. However, these electrodes were vulnerable to water and prone to damage, requiring careful handling during attaching to the skin and being susceptible to breakage with slight movements or sweat.<br/>To address this issue, we developed nanomesh electrodes with excellent water resistance and stable measurement capabilities by mixing hydrophobic WBPU (waterborne polyurethane) with the conventional material PVA (polyvinyl alcohol). The Au-PVA/WBPU nanomesh electrodes were fabricated by following method. First, a mixture of a 15 wt% PVA aqueous solution and a 30 wt% WBPU solution in 2:1 ratio was made into a nanofiber sheet by electrospinning method. And then, a heat-press treatment was applied to the nanofiber sheet to improve the inner connect between fibers. After a heat-press treatment at 150°C for 1 minute, a 100 nm thick layer of gold was deposited by vacuum evaporation method. To check the water resistivity of the nanomesh electrode, we conducted a water immersing test. After a 1-minute stirring test in the pure water, the conventional Au-PVA nanomesh electrodes completely disappeared from the artificial skin, whereas Au-PVA/WBPU nanomesh electrodes remained more than 95% area on the artificial skin. In addition, we checked the stability of the nanomesh electrodes on the skin. After attaching the electrodes on the skin for 2 hours, the resistance of the Au-PVA/WBPU nanomesh electrodes were almost constant while that of conventional nanomesh electrodes showed a deterioration, increasing by 3 to 4 times.<br/><br/>[1] R. B. Malmo, Activation: a neurophysiological dimension.,<i> Psychol. Rev.,</i> 66, 1959<br/>[2] R. Gudivaka <i>et al., </i>Effect of skin temperature on multifrequency bioelectrical impedance analysis.,<i> Journal of Applied Physiology, </i>81(2), 1996<br/>[3] Y. Yamamoto, T. Yamamoto, Characteristics of skin admittance for dry electrodes and the measurement of skin moisturisation., <i>Med. Biol. Eng. Comput.,</i> 24, 1986<br/>[4] A. Miyamoto<i> et al.,</i> Inflammation-free, gas-permeable, lightweight, stretchable on-skin electronics with nanomeshes.,<i> Nat. Nanotech., </i>12, 2017<br/>[5] A. Miyamoto<i> et al.,</i> Highly Precise, Continuous, Long-Term Monitoring of Skin Electrical Resistance by Nanomesh Electrodes.,<i> Adv. Healthcare Mater., </i>11, 2022<br/>[6] R. Matsukawa <i>et al.,</i> Skin Impedance Measurements with Nanomesh Electrodes for Monitoring Skin Hydration.,<i> Adv. Healthcare Mater., </i>9, 2020