Difference between revisions of "Team:Vilnius-Lithuania/Design"

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                             With this method, we effectively produce monodisperse bilayered liposomes with high throughput. It is important to note that together with the microchannel dimensions, the infusion rates of the different phases also have an impact on the size of the droplets. Additionally, the infusion rates regulate the throughput of liposome production. The already mentioned <strong><var>SynFlow</var></strong> model determines the optimized flow rates for the most stable and highest frequency synthesis. With the right dimensions and flow rates we reach the production rate that is up to 2000 Hz. The results suggest that this method could be successfully adapted for mass production of liposomes. Fig. 7 reveals the slowed down process of droplet formation.
 
                             With this method, we effectively produce monodisperse bilayered liposomes with high throughput. It is important to note that together with the microchannel dimensions, the infusion rates of the different phases also have an impact on the size of the droplets. Additionally, the infusion rates regulate the throughput of liposome production. The already mentioned <strong><var>SynFlow</var></strong> model determines the optimized flow rates for the most stable and highest frequency synthesis. With the right dimensions and flow rates we reach the production rate that is up to 2000 Hz. The results suggest that this method could be successfully adapted for mass production of liposomes. Fig. 7 reveals the slowed down process of droplet formation.
 
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                          <strong>Fig. 7</strong> High throughput formation of cell-sized liposomes. The video is 60x slowed down
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                            <img src="https://static.igem.org/mediawiki/2018/f/fc/T--Vilnius-Lithuania--Fig7_Liposomes_formation_video.mp4"/>
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                            <strong>Fig 7 </strong> High throughput formation of cell-sized liposomes. The video is 60x slowed down    
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                             A simple liposome size frequency distribution was determined with an image analysis software ImageJ. A plugin SpotCaliper was utilized to identify circular objects and measure their diameters (Fig. 8a). Gaussian distribution was fitted to the frequency histogram. Results verify that the size of the liposomes follows the Gaussian distribution (Fig. 8b). It proves that the droplets are highly homogeneous. Average diameter of a liposome (results from a single batch experiment) is around 12 µm, with standard deviation of 0.4 µm which fits our requirements very well.  
 
                             A simple liposome size frequency distribution was determined with an image analysis software ImageJ. A plugin SpotCaliper was utilized to identify circular objects and measure their diameters (Fig. 8a). Gaussian distribution was fitted to the frequency histogram. Results verify that the size of the liposomes follows the Gaussian distribution (Fig. 8b). It proves that the droplets are highly homogeneous. Average diameter of a liposome (results from a single batch experiment) is around 12 µm, with standard deviation of 0.4 µm which fits our requirements very well.  
 
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                             <strong>Fig. 8 a</strong> An automatic detection of droplets with SpotCaliper: the droplets are marked with teal colored circles and the  
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                            <img src="https://static.igem.org/mediawiki/2018/4/4e/T--Vilnius-Lithuania--Fig8_Liposomes.png"/>
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                             <strong>Fig 8 </strong> An automatic detection of droplets with SpotCaliper: the droplets are marked with teal colored circles and the  
 
                             diameter of each is measured; <strong>b</strong> size frequency distribution histogram fitted to Gaussian distribution (teal fit) proves  
 
                             diameter of each is measured; <strong>b</strong> size frequency distribution histogram fitted to Gaussian distribution (teal fit) proves  
                             the homogeneity of the liposomes; μ=11.853 >µm±0.017 >µm ; SD=0.442 µm ±0.017 µm.                                  
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                             the homogeneity of the liposomes; μ=11.853 >µm±0.017 >µm ; SD=0.442 µm ±0.017 µm.                                    
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Revision as of 00:22, 18 October 2018

Design and Results

Results

Cell-free, synthetic biology systems open new horizons in engineering biomolecular systems which feature complex, cell-like behaviors in the absence of living entities. Having no superior genetic control, user-controllable mechanisms to regulate gene expression are necessary to successfully operate these systems. We have created a small collection of synthetic RNA thermometers that enable temperature-dependent translation of membrane proteins, work well in cells and display great potential to be transferred to any in vitro protein synthesis system.

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