Difference between revisions of "Team:TUDelft/Main-Measurement"

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<h1> Measurement</h1>
 
<h1> Measurement</h1>
<p>As is more elaborately described in the detection design page, coacervates are polymer-rich regions in solutions of mutually attractive polymers. The process of mutually attractive polymers phase-separating into a polymer-rich and polymer-poor phase is known as coacervation. This process can under some circumstances be observed by the naked eye, as coacervates generally cause solutions to be more turbid. A key physical property of coacervates is that they require polymers of a certain length to form. In general, only polymers that are ‘long enough’ form coacervates. The underlying reason for this can be explained from a theoretical standpoint, which we demonstrated with <a href="https://2017.igem.org/Team:TUDelft/Model#coacervationtheory">modelling</a> and from a practical/experimental perspective, shown on the detection results page. These latter facts directly imply that (changes in) polymer length can be visualized to the naked eye, which we utilized to design a novel detection method coined <a href="https://2017.igem.org/Team:TUDelft/Design#coacervation">CINDY Seq</a>. However as we will argue in greater detail below, the method has potential to serve as a far broader method to characterize existing and future BioBricks, and the activity of many enzymes that show synthesis or degradation of any (coacervating) polymer.</p>
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<p>As is more elaborately described in the detection design page, coacervates are polymer-rich regions in solutions of mutually attractive polymers. The process of mutually attractive polymers phase-separating into a polymer-rich and polymer-poor phase is known as coacervation. This process can under some circumstances be observed by the naked eye, as coacervates generally cause solutions to be more turbid. A key physical property of coacervates is that they require polymers of a certain length to form. In general, only polymers that are ‘long enough’ form coacervates. The underlying reason for this can be explained from <a href="https://2017.igem.org/Team:TUDelft/Model#coacervation">theoretical perspective</a> and <a href="https://2017.igem.org/Team:TUDelft/Results#coacervation">experimentally</a> . These latter facts directly imply that (changes in) polymer length can be visualized to the naked eye, which we utilized to design a novel detection method coined <a href="https://2017.igem.org/Team:TUDelft/Design#coacervation">CINDY Seq</a>. However as we will argue in greater detail below, the method has potential to serve as a far broader method to characterize existing and future BioBricks, and the activity of many enzymes that show synthesis or degradation of any (coacervating) polymer.</p>
 
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<div class="collapsible-header">The coacervation method in our project</div>
 
<div class="collapsible-header">The coacervation method in our project</div>

Revision as of 09:20, 31 October 2017

Measurement

Measurement

As is more elaborately described in the detection design page, coacervates are polymer-rich regions in solutions of mutually attractive polymers. The process of mutually attractive polymers phase-separating into a polymer-rich and polymer-poor phase is known as coacervation. This process can under some circumstances be observed by the naked eye, as coacervates generally cause solutions to be more turbid. A key physical property of coacervates is that they require polymers of a certain length to form. In general, only polymers that are ‘long enough’ form coacervates. The underlying reason for this can be explained from theoretical perspective and experimentally . These latter facts directly imply that (changes in) polymer length can be visualized to the naked eye, which we utilized to design a novel detection method coined CINDY Seq. However as we will argue in greater detail below, the method has potential to serve as a far broader method to characterize existing and future BioBricks, and the activity of many enzymes that show synthesis or degradation of any (coacervating) polymer.