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<td style="border: 0px !important;"><p style="width:80%;height:100%;position:relative;top:-200px; font-size:1.5rem;font-family: 'Times New Roman' !important; color:white;">Applications and Bottlenecks of Cell-based Micro-robots<br><br>Micro-organisms has been developed as micro-robots in drug delivery, genetic and cellular therapeutics. Compared with mechanical robots, cell-based micro-robots have a more complete controlling system and a better energy conversion system. However, how to achieve precise control over them remains a great challenge to researchers. C.Reinhardtii, with its stronger motility and inborn light sensing system, has become a desired choice to make cell-based micro-robots.</p></td> | <td style="border: 0px !important;"><p style="width:80%;height:100%;position:relative;top:-200px; font-size:1.5rem;font-family: 'Times New Roman' !important; color:white;">Applications and Bottlenecks of Cell-based Micro-robots<br><br>Micro-organisms has been developed as micro-robots in drug delivery, genetic and cellular therapeutics. Compared with mechanical robots, cell-based micro-robots have a more complete controlling system and a better energy conversion system. However, how to achieve precise control over them remains a great challenge to researchers. C.Reinhardtii, with its stronger motility and inborn light sensing system, has become a desired choice to make cell-based micro-robots.</p></td> | ||
<td style="border: 0px !important;"><img src="https://static.igem.org/mediawiki/2019/a/a0/T--DUT_China_B--1.1.svg" class="img-responsive" alt=""></td> | <td style="border: 0px !important;"><img src="https://static.igem.org/mediawiki/2019/a/a0/T--DUT_China_B--1.1.svg" class="img-responsive" alt=""></td> | ||
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<td style="border: 0px !important;"><img src="https://static.igem.org/mediawiki/2019/6/66/T--DUT_China_B--1.3.svg" class="img-responsive" alt=""></td> | <td style="border: 0px !important;"><img src="https://static.igem.org/mediawiki/2019/6/66/T--DUT_China_B--1.3.svg" class="img-responsive" alt=""></td> | ||
<td style="border: 0px !important;"><p style="width:80%;height:100%;position:relative;top:-200px; font-size:1.5rem;font-family: 'Times New Roman' !important; color:white;">The Design of Molecular Light Converter<br><br>We combined optically polymeric protein with split Ranilla luciferase, realizing the recovery of complete luciferase and the activation of blue light under the control of infrared light. This molecular light converter will produce blue light inside C.Reinhardtii and thus activate the algae.(Check out our Design)</p></td> | <td style="border: 0px !important;"><p style="width:80%;height:100%;position:relative;top:-200px; font-size:1.5rem;font-family: 'Times New Roman' !important; color:white;">The Design of Molecular Light Converter<br><br>We combined optically polymeric protein with split Ranilla luciferase, realizing the recovery of complete luciferase and the activation of blue light under the control of infrared light. This molecular light converter will produce blue light inside C.Reinhardtii and thus activate the algae.(Check out our Design)</p></td> |
Revision as of 14:06, 16 October 2019
We want to achieve red light navigated movement in Chlamydomonas Reinhardtii, making it easier to function as cell micro-robots. With about 10 um size and strong motion ability, C.Reinhartii is the ideal chassis organism for operation.
Applications and Bottlenecks of Cell-based Micro-robots |
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The Design of Molecular Light Converter |
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Application & Human Practices |
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Our Achievements |