Imperceptible augmentation of living systems with organic bioelectronic fibres.
Wenyu WangYifei PanYuan ShuiTawfique HasanIek Man LeiStanley Gong Sheng KaThierry SavinSantiago Velasco-BosomYang CaoSusannah B P McLarenYuze CaoFengzhu XiongGeorge G MalliarasYan Yan Shery HuangPublished in: Nature electronics (2024)
The functional and sensory augmentation of living structures, such as human skin and plant epidermis, with electronics can be used to create platforms for health management and environmental monitoring. Ideally, such bioelectronic interfaces should not obstruct the inherent sensations and physiological changes of their hosts. The full life cycle of the interfaces should also be designed to minimize their environmental footprint. Here we report imperceptible augmentation of living systems through in situ tethering of organic bioelectronic fibres. Using an orbital spinning technique, substrate-free and open fibre networks-which are based on poly (3,4-ethylenedioxythiophene):polystyrene sulfonate-can be tethered to biological surfaces, including fingertips, chick embryos and plants. We use customizable fibre networks to create on-skin electrodes that can record electrocardiogram and electromyography signals, skin-gated organic electrochemical transistors and augmented touch and plant interfaces. We also show that the fibres can be used to couple prefabricated microelectronics and electronic textiles, and that the fibres can be repaired, upgraded and recycled.
Keyphrases
- life cycle
- soft tissue
- healthcare
- human health
- water soluble
- public health
- gold nanoparticles
- mental health
- high resolution
- minimally invasive
- wound healing
- solid state
- climate change
- risk assessment
- ionic liquid
- molecularly imprinted
- pseudomonas aeruginosa
- label free
- reduced graphene oxide
- cystic fibrosis
- virtual reality