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Team:HKU-HKBU/Application
From 2009.igem.org
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# The size of the motor can be reduced to a much smaller scale. The motor are available to many applications that involve microscale manipulation. | # The size of the motor can be reduced to a much smaller scale. The motor are available to many applications that involve microscale manipulation. | ||
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# The bacteria-powered motor is genetically manipulated. | # The bacteria-powered motor is genetically manipulated. | ||
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The key is to develop a better interface between the microorganisms and the non-living device that can concentrate and forces and serves as a motion rectifier. | The key is to develop a better interface between the microorganisms and the non-living device that can concentrate and forces and serves as a motion rectifier. | ||
Revision as of 15:13, 21 October 2009
Contents |
Applications
Overview
Our version of 'Bactomotor' is only a preliminary one. But the idea of using the mechanical forces generated by microorganisms to do useful work is thrilling and will have great implications in many fields of future applications. Although forces generated by a single bacterium counts little, the concentration of forces generated by a population of bacteria can actually make a great difference. Motors powered by living organisms can have numerous advantages over the conventional electronic devices that are powered by batteries. The advantages are concluded as follows:
- The size of the motor can be reduced to a much smaller scale. The motor are available to many applications that involve microscale manipulation.
- The bacteria-powered motor is genetically manipulated.
The key is to develop a better interface between the microorganisms and the non-living device that can concentrate and forces and serves as a motion rectifier.
Clinical medicine and surgery
Genetically-engineered microorganism-powering'Bactomotor'
Zero-pollution energy source
