Add to ORKGBacterial flagella with their exceptional primary properties have demonstrated to be promising bio-formats and can be misused for the production of nanomaterial with high perspective proportion and surface region. Their artificially modifiable surfaces permit the flagella be changed to have electrical/electronic properties. Their phenomenal actual properties alongside the numerous opportunities for control make them ideal frameworks to read to create nanoelectronics. To start with, this article surveys the qualities of bacterial flagella and their use as organically enlivened formats. Next, the utilization of bio-layouts for electronic frameworks, for example, color sharpened sun powered cell and lithium particle battery is talked about. At...
Diatoms microalgae can be regarded as living factories producing nanostructured and mesoporous biosi...
We have developed a new biofabrication process in which the precise control of bacterial motion is u...
Microbial fuel cells and biophotovoltaics represent promising technologies for green bioelectricity ...
Flagella can be used to make magnetically-controlled microfluidic and nanoscale devices for biomedic...
The desire and need for various types of nanostructures have been met with challenges of feasibility...
Designing a new generation of energy-intensive and sustainable electrode materials for batteries to ...
Currently, the industrial application of bioelectrochemical systems (BESs) that are incubated with n...
The nexus of any bionic device can be found at the electrode-cellular interface. Overall efficiency ...
The present work describes for the first time the production of artificial bacterial flagella (ABFs)...
Currently there is a great deal of interest in micro and nano scale robotics for biomedical applicat...
The ability to produce low-cost, hierarchically-structured and nanopatterned inorganic materials cou...
hn ity Microelectronic devices and MEMS are traditionally Review TRENDS in Biotechnology Vol.22 No.1...
Various techniques were explored to develop an electronic paper prototype on bacterial cellulose. El...
In recent years, we have been observing a rapid and growing interest concerning the utilization of b...
Microbial biophotovoltaic cells exploit the ability of cyanobacteria and microalgae to convert light...
Diatoms microalgae can be regarded as living factories producing nanostructured and mesoporous biosi...
We have developed a new biofabrication process in which the precise control of bacterial motion is u...
Microbial fuel cells and biophotovoltaics represent promising technologies for green bioelectricity ...
Flagella can be used to make magnetically-controlled microfluidic and nanoscale devices for biomedic...
The desire and need for various types of nanostructures have been met with challenges of feasibility...
Designing a new generation of energy-intensive and sustainable electrode materials for batteries to ...
Currently, the industrial application of bioelectrochemical systems (BESs) that are incubated with n...
The nexus of any bionic device can be found at the electrode-cellular interface. Overall efficiency ...
The present work describes for the first time the production of artificial bacterial flagella (ABFs)...
Currently there is a great deal of interest in micro and nano scale robotics for biomedical applicat...
The ability to produce low-cost, hierarchically-structured and nanopatterned inorganic materials cou...
hn ity Microelectronic devices and MEMS are traditionally Review TRENDS in Biotechnology Vol.22 No.1...
Various techniques were explored to develop an electronic paper prototype on bacterial cellulose. El...
In recent years, we have been observing a rapid and growing interest concerning the utilization of b...
Microbial biophotovoltaic cells exploit the ability of cyanobacteria and microalgae to convert light...
Diatoms microalgae can be regarded as living factories producing nanostructured and mesoporous biosi...
We have developed a new biofabrication process in which the precise control of bacterial motion is u...
Microbial fuel cells and biophotovoltaics represent promising technologies for green bioelectricity ...