Integrating Ion Channels with Bioelectronics for Biotic–Abiotic Systems
Precise and highly regulated flow of biomolecules and ions through complex cellular networks is crucial for communication and information processing in living systems. In contrast, human‐made electronics rely on the flow of electrons and holes through well‐defined semiconductor networks for processing. Ion channels play vital roles in regulating the flow of ions and biomolecules across the cell membrane with a complexity unmatched in any semiconductor device. To enable biotic–abiotic communication and leverage this complexity, supported lipid bilayers (SLBs) create a planar cell membrane for integration with bioelectronics. This review discusses the integration of ion channels in bioelectronic devices for biotic–abiotic communication with enhanced functionality. This review begins with an introduction of natural and artificial ion channels across SLBs, continues with a description of bioelectronic devices integrating SLBs, and concludes with examples of functional ion channel bioelectronics.
- Location
-
Deutsche Nationalbibliothek Frankfurt am Main
- Extent
-
Online-Ressource
- Language
-
Englisch
- Bibliographic citation
-
Integrating Ion Channels with Bioelectronics for Biotic–Abiotic Systems ; day:26 ; month:04 ; year:2023 ; extent:13
Advanced intelligent systems ; (26.04.2023) (gesamt 13)
- Creator
-
Park, Yunjeong
Luo, Le
Rolandi, Marco
- DOI
-
10.1002/aisy.202200312
- URN
-
urn:nbn:de:101:1-2023042715174609644662
- Rights
-
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
- Last update
-
14.08.2025, 10:58 AM CEST
Data provider
Deutsche Nationalbibliothek. If you have any questions about the object, please contact the data provider.
Associated
- Park, Yunjeong
- Luo, Le
- Rolandi, Marco
Other Objects (12)
The abiotic pattern of biotic CO2 fixation
Poplar responses to biotic and abiotic stress
Bioelectronics
How cytoskeleton senses abiotic, biotic stimuli in plant cells?
Silica nanoparticles protect rice against biotic and abiotic stresses
Strategies of plants to overcome abiotic and biotic stresses
Taking Electrons out of Bioelectronics: From Bioprotonic Transistors to Ion Channels
Organic Bioelectronics
Effects of steam sterilization on soil abiotic and biotic properties
Proteome changes following biotic and abiotic stress in forest trees
NO signaling functions in the biotic and abiotic stress responses
Abiotic and biotic processes that drive carboxylation and decarboxylation reactions
The abiotic pattern of biotic CO2 fixation
Poplar responses to biotic and abiotic stress
Bioelectronics
How cytoskeleton senses abiotic, biotic stimuli in plant cells?
Silica nanoparticles protect rice against biotic and abiotic stresses
Strategies of plants to overcome abiotic and biotic stresses
Taking Electrons out of Bioelectronics: From Bioprotonic Transistors to Ion Channels
Organic Bioelectronics
Effects of steam sterilization on soil abiotic and biotic properties
Proteome changes following biotic and abiotic stress in forest trees
NO signaling functions in the biotic and abiotic stress responses
Abiotic and biotic processes that drive carboxylation and decarboxylation reactions
The abiotic pattern of biotic CO2 fixation
Poplar responses to biotic and abiotic stress
Bioelectronics
How cytoskeleton senses abiotic, biotic stimuli in plant cells?
Silica nanoparticles protect rice against biotic and abiotic stresses
Strategies of plants to overcome abiotic and biotic stresses
Taking Electrons out of Bioelectronics: From Bioprotonic Transistors to Ion Channels
Organic Bioelectronics
Effects of steam sterilization on soil abiotic and biotic properties
Proteome changes following biotic and abiotic stress in forest trees
NO signaling functions in the biotic and abiotic stress responses