Drawn-on-Skin Electronics for Multifunctional, Motion Artifact-Free Sensing and Point-of-Care Treatment
Extraction of physiological, physical, and psychological signals from human skin for health monitoring, disease prevention, and treatment is critical to sustain the wellbeing of all individuals. Through directly interfacing electronic devices with the skin, information such as the state of the heart, the condition of muscle, the impedance, and hydration of the skin, can all be extracted. Recent advances in soft wearable electronics which attach directly to the epidermal surface have suggested certain pathways. Typically, wearable bioelectronics are structured in the form of patches that are soft, flexible, and/or stretchable and thus, are beneficial to form contact with the curvilinear surfaces of the skin. However, wearable bioelectronics generally suffer from motion artifacts thus leading to misinterpretation and misdiagnoses, which is mainly due to the weak adhesion or imperfect conformability, and thus inconsistent interface between the electronics and skins. Specifically, one of the main sources of motion artifacts lies in mechanical disturbances at the electronics-skin interfaces. Here, we present the ultra-conformal, customizable, and deformable drawn-on-skin (DoS) electronics platform, which is robust to motion and can provide point-of-care therapy. Compared to existing wearable and/or printed bioelectronics fabricated based on dedicated equipment, DoS electronics has numerous advantages including: simple fabrication without dedicated equipment, ability to deposit electronic materials to dynamic surfaces, capability to construct active electronics, multifunctionality of devices and sensors, immunity to motion artifacts without the need for additional hardware or computation, which offers an unprecedented solution to the long-standing challenge in the bioelectronics field, and customizability for personalized point-of-care treatment. Specifically, DoS electronics is created by liquid functional inks drawn into stencils using ballpoint pens directly on human skin. Upon drawing, an ultra-conformal, robust, and stretchable interface that is immune to motion is formed between DoS electronics and skin. Example DoS devices, such as thin-film transistors, strain sensors, temperature sensors, heaters, skin hydration sensors, and electrophysiological (EP) sensors have been developed with qualities of skin textured surface, curvilinear shape, and mechanical deformability. A wireless electrocardiogram (ECG) monitoring system combined with DoS EP sensors demonstrates daily and clinical usages. By comparing the DoS EP sensors with hospital-grade gel electrodes, and ultrathin serpentine mesh electrodes, we found that DoS electronics has multiple advantages, such as stable performance in the presence of sweat, reliable capture of EP signals over a long duration, strong adherence to the skin, and immunity to motion artifacts during sensing. Additionally, DoS electronics combined with electrical stimulation demonstrates accelerated healing of skin wounds.
Drawn-on-Skin Electronics for Multifunctional, Motion Artifact-Free Sensing and Point-of-Care Treatment
Category
Poster Presentation
Description
Session: 17-01-01 Research Posters - On Demand
ASME Paper Number: IMECE2020-24856
Session Start Time: ,
Presenting Author: Faheem Ershad
Presenting Author Bio: Faheem Ershad is a Ph.D. candidate at the University of Houston, Houston, TX, USA. He graduated with a B.S. in biomedical engineering (B.S.B.E.) in May 2018. He began working in Dr. Yu’s group as an undergraduate student, and continued as a Ph.D. student. He has investigated various soft electronic device technologies and their applications, ranging from implantable devices on the heart to portable, on-skin electrophysiological devices. His current research interest is in the development and applications of flexible/stretchable electronics for wearable/implantable health monitoring, disease treatment, and tissue engineering.
Authors: Faheem Ershad University of Houston
Cunjiang Yu University of Houston