Skin is one of the most complex structures in the body, with many physiological functions. Skin acts as the barrier or an interface between the external environment and internal organs. Hydration within the skin is varied, known as the skin's water-loading. Perspiration occurs when watery fluid is secreted through the eccrine and apocrine glands. Flexible epidermal sensors are fabricated, which can be used to measure skin hydration and perspiration (sweat) as these sensors need to be skin-conformable. Polyimide (PI) and Polydimethylsiloxane (PDMS) are used as they are flexible and skin compliant, and the sensing layer is formed on them. The sensitivity of hydration sensors was in the range of 0.002-0.0046/%, while for sweat sensors, it was in the range of 0.092μl-1 0.116 μl-1. Stability tests indicated that external factors such as environment or physical deformation and skin curvature do not affect the performance of the as-prepared sensors. The sensitivity and stability results of the planar capacitor are highly suitable for flexible hydration and sweat-sensing applications. The proposed sensors offer an outstandingly good option for incorporation into wearable systems for physical personal health monitoring. In the future, we plan to integrate these sensors on a single substrate to create a multimodal device. 
Reduced graphene oxide (rGO) has attracted enormous interest as a promising candidate material for gas detection due to its large specific surface areas. In our work, rGO films were fabricated on a large scale using dip-coating and spin-coating methods for the detection of nitrogen dioxide (NO2) gas at room temperature. The influence of different test environments on the sensing performance, including the test atmosphere, gas flow and gas pressure was evaluated. The response time of the dip-coating method was 573 s with a long recovery period of 639 s and for the spin-coating method, the response time and recovery time was 386 s and 577 s, respectively. In addition, the spin-coated sensor exhibited high selectivity to NO2, with the response increasing by more than 20% (for 15 ppm NO2) as compared with that for HCHO, NH3, and CH4. Our results indicated that the spin coating method was more suitable for rGO-based gas sensors with higher performance.
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