Difference between revisions of "Team:HZAU-China/Project/mrcell"

 
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   <div class="topbox">
 
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     <div class="left_topbox"><img src="https://static.igem.org/mediawiki/2015/6/6e/Team_HZAU-China_ecoli.png"/></div>
 
     <div class="left_topbox"><img src="https://static.igem.org/mediawiki/2015/6/6e/Team_HZAU-China_ecoli.png"/></div>
     <div class="middle_topbox"><h1>Mixed-Reality Cell<span>Bidirectinal coupling between real and virtual bio-oscillators</span></h1></div>
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     <div class="middle_topbox"><h1>Mixed-Reality Cell<span>Bidirectional coupling between real and virtual bio-oscillators</span></h1></div>
 
     <div class="right_topbox"><img src="https://static.igem.org/mediawiki/2015/1/12/Team_HZAU-China_brain.png"></div>
 
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       <h1></br></br>MR. Cell</h1></br>
 
       <h1></br></br>MR. Cell</h1></br>
       <p>MR. Cell, a half-real and half-virtual life form, is composed of two parts, the real part in E.coli and the virtual part in computer. These two parts interact with each other through our interface hardware and will be coupled to a unified whole, mixed-reality state.</p>
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       <p>MR. Cell, a half-real and half-virtual life form, is composed of two parts, the real part in E. coli and the virtual part in computer. These two parts interact with each other through the interface hardware and will become coupled into a unified whole, a mixed-reality state.</p>
 
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         <strong>Real part</strong></br>
 
         <strong>Real part</strong></br>
         A genetic oscillator, as a representative life activity form, was constructed in E.coli as the real part. Besides a light control system associated with the oscillator is adopted to connect the real part in computer, and we can regulate the oscillator by light through computer.
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         A genetic oscillator, representing the life activity, was constructed in E.coli as the real part. Besides, a light control system associated with the oscillator was adopted to connect the real part to computer. We can regulate the oscillator by using the light intensity controlled by computer.
         <img src="https://static.igem.org/mediawiki/2015/3/34/HZAU_p14.png" width="200px" height="150px">
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         <strong>Virtual part</strong></br>
 
         <strong>Virtual part</strong></br>
         Mixed reality states occur only when a virtual and a real system are sufficiently similar. Therefore, based on the mechanism of the genetic oscillator, we simulate an e-oscillator in a computer as the virtual counterpart. In addition, the state of e-oscillator could be modulated through the parameter adjustment.
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         Mixed-reality states occur only when a virtual and a real system are sufficiently similar. Therefore, according to the mechanism of the genetic oscillator, we simulated an e-oscillator in a computer as the virtual counterpart. In addition, the state of e-oscillator could be modulated through the parameter adjustment.
         <img src="https://static.igem.org/mediawiki/2015/2/2a/HZAU_p12.png" width="200px" height="140px">
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       <img src="https://static.igem.org/mediawiki/2015/f/fa/HZAU_p13.png"  width="400px" height="300px">
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       <strong>Interface device</strong></br>
 
       <strong>Interface device</strong></br>
       The two-way interface device is composed of Light Receiving part and Light Controlling part. For the former one, cells were cultivated on a microfluidic chip and observed by fluorescence microscope. And for the last one, light (LED beads) can be controlled by a computer through a Single Chip Micyoco.
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       The two-way interface device is composed of Light Receiving part and Light Controlling part. For the former part, cells were cultivated on a microfluidic chip and observed by fluorescence microscope; for the latter part, light (LED beads) can be controlled by a computer through a Single-Chip Microcomputer.
 
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</br></br>
<h3>The synchronous interreality system—MR.Cell</h3>
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<p><strong>The synchronous interreality system—MR.Cell</strong></p>
<p>At the beginning, the two oscillators, bio-oscillator and e-oscillator, work independently in a dual-reality state. When connected by the interface devices, the two parts begin to interact with each other. The state of bio-oscillator in E.coli cultured in a microfluidic chip would be observed through a fluorescence microscope and transmitted to the computer. The computer would analyze and process the received fluorescent data and adjust the state of e-oscillator through parameter modifications. In the meanwhile, based on its own state, the e-oscillator in computer also could regulate the state of bio-oscillator through LED intensity. The LED is controlled by a single-chip, which is linked to the computer. Following the processing cycle, the two parts interact with each other and couple eventually.</p>
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<p>At the beginning, the two bio-oscillators, genetic oscillator and e-oscillator, work independently in a dual-reality state. When connected by the interface devices, the two parts begin to interact with each other. The state of the genetic oscillator in E. coli cultured on a microfluidic chip would be observed through a fluorescence microscope and transmitted into the computer. The computer would analyze and process the received fluorescent data and adjust the state of the e-oscillator through parameter modifications. In the meanwhile, based on its own state, the e-oscillator in the computer could also regulate the state of the genetic oscillator through LED light intensity. The LED is controlled by a single-chip microcomputer that is linked to the simulating computer. Following the information processing cycle, the real and virtual parts interact with each other and become coupled eventually.</p>
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<img src="https://static.igem.org/mediawiki/2015/8/8c/Hzaupall.png" width="720px" height="430px">
 
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<p>Besides, in consideration of the complexity and difficulty of the system, we take three stages to achieve our final goal, MR.Cell. At the first stage, we simulate two e-oscillators, which are of similar characters but have different initial states. And they couple gradually. Next stage, LED lamp replaces the genetic oscillator in E.coli to interact and couple with the e-oscillator. The last stage, our ultimate ambition, is to complete the MR. Cell, the two part of which synchronize and couple strongly.</p>
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<p>Besides, considering the complexity and difficulty of the system, we took three stages to achieve our final goal, MR. Cell. At the first stage, we simulated two e-oscillators, which are of similar characteristics but have different initial states. They were successfully coupled. Next stage, an LED lamp was used to replace the genetic oscillator in E. coli to interact and couple with the e-oscillator in the computer simulation. They were successfully coupled. The final stage, our ultimate goal, is to complete the MR. Cell, the two parts of which could synchronize and couple strongly.</p>
 
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Latest revision as of 04:20, 15 November 2015

Mixed-Reality CellBidirectional coupling between real and virtual bio-oscillators



MR. Cell


MR. Cell, a half-real and half-virtual life form, is composed of two parts, the real part in E. coli and the virtual part in computer. These two parts interact with each other through the interface hardware and will become coupled into a unified whole, a mixed-reality state.


Real part
A genetic oscillator, representing the life activity, was constructed in E.coli as the real part. Besides, a light control system associated with the oscillator was adopted to connect the real part to computer. We can regulate the oscillator by using the light intensity controlled by computer.
Virtual part
Mixed-reality states occur only when a virtual and a real system are sufficiently similar. Therefore, according to the mechanism of the genetic oscillator, we simulated an e-oscillator in a computer as the virtual counterpart. In addition, the state of e-oscillator could be modulated through the parameter adjustment.

Interface device
The two-way interface device is composed of Light Receiving part and Light Controlling part. For the former part, cells were cultivated on a microfluidic chip and observed by fluorescence microscope; for the latter part, light (LED beads) can be controlled by a computer through a Single-Chip Microcomputer.


The synchronous interreality system—MR.Cell

At the beginning, the two bio-oscillators, genetic oscillator and e-oscillator, work independently in a dual-reality state. When connected by the interface devices, the two parts begin to interact with each other. The state of the genetic oscillator in E. coli cultured on a microfluidic chip would be observed through a fluorescence microscope and transmitted into the computer. The computer would analyze and process the received fluorescent data and adjust the state of the e-oscillator through parameter modifications. In the meanwhile, based on its own state, the e-oscillator in the computer could also regulate the state of the genetic oscillator through LED light intensity. The LED is controlled by a single-chip microcomputer that is linked to the simulating computer. Following the information processing cycle, the real and virtual parts interact with each other and become coupled eventually.



Besides, considering the complexity and difficulty of the system, we took three stages to achieve our final goal, MR. Cell. At the first stage, we simulated two e-oscillators, which are of similar characteristics but have different initial states. They were successfully coupled. Next stage, an LED lamp was used to replace the genetic oscillator in E. coli to interact and couple with the e-oscillator in the computer simulation. They were successfully coupled. The final stage, our ultimate goal, is to complete the MR. Cell, the two parts of which could synchronize and couple strongly.




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