A key challenge in bioelectronics is to establish and improve the interface between electronic devices and living tissues,enabling a direct assessment of biological systems.Sensors integrated with plant tissue can pro...A key challenge in bioelectronics is to establish and improve the interface between electronic devices and living tissues,enabling a direct assessment of biological systems.Sensors integrated with plant tissue can provide valuable information about the plant itself as well as the surrounding environment,including air and soil quality.An obstacle in developing interfaces to plant tissue is mitigating the formation of fibrotic tissues,which can hinder continuous and accurate sensor operation over extended timeframes.Electronic systems that utilize suitable biocompatible materials alongside appropriate fabrication techniques to establish plantelectronic interfaces could provide for enhanced environmental understanding and ecosystem management capabilities.To meet these demands,this study introduces an approach for integrating printed electronic materials with biocompatible cryogels,resulting in stable implantable hydrogel-based bioelectronic devices capable of long-term operation within plant tissue.These inkjet-printed cryogels can be customized to provide various electronic functionalities,including electrodes and organic electrochemical transistors(OECTs),that exhibit high electrical conductivity for embedded conducting polymer traces(up to 350 S/cm),transconductance for OECTs in the mS range,a capacitance of up to 4.2mF g−1 in suitable structures,high stretchability(up to 330%strain),and selfhealing properties.The biocompatible functionalized cryogel-based electrodes and transistors were successfully implanted in plant tissue,and ionic activity in tomato plant stems was collected for over two months with minimal scar tissue formation,making these cryogel-based printed electronic devices excellent candidates for continuous,in-situ monitoring of plant and environmental status and health.展开更多
基金supported by the National Science Foundation(NSF)Signals in the Soils(SitS)program(Award No.1935594)as well as an award from the Natural Environment Research Council(NERC)(reference NE/T012293/1)Microscopic analyses were performed at MIMIC,University of Colorado Boulder(RRID:SCR 019307).
文摘A key challenge in bioelectronics is to establish and improve the interface between electronic devices and living tissues,enabling a direct assessment of biological systems.Sensors integrated with plant tissue can provide valuable information about the plant itself as well as the surrounding environment,including air and soil quality.An obstacle in developing interfaces to plant tissue is mitigating the formation of fibrotic tissues,which can hinder continuous and accurate sensor operation over extended timeframes.Electronic systems that utilize suitable biocompatible materials alongside appropriate fabrication techniques to establish plantelectronic interfaces could provide for enhanced environmental understanding and ecosystem management capabilities.To meet these demands,this study introduces an approach for integrating printed electronic materials with biocompatible cryogels,resulting in stable implantable hydrogel-based bioelectronic devices capable of long-term operation within plant tissue.These inkjet-printed cryogels can be customized to provide various electronic functionalities,including electrodes and organic electrochemical transistors(OECTs),that exhibit high electrical conductivity for embedded conducting polymer traces(up to 350 S/cm),transconductance for OECTs in the mS range,a capacitance of up to 4.2mF g−1 in suitable structures,high stretchability(up to 330%strain),and selfhealing properties.The biocompatible functionalized cryogel-based electrodes and transistors were successfully implanted in plant tissue,and ionic activity in tomato plant stems was collected for over two months with minimal scar tissue formation,making these cryogel-based printed electronic devices excellent candidates for continuous,in-situ monitoring of plant and environmental status and health.
