Team:Dundee/Project/DetectionComparison

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Latest revision as of 20:03, 23 October 2013

iGEM Dundee 2013 · ToxiMop

Detection Time

The direct method for detecting microcystin in water samples is high performance liquid chromatography (HPLC). This process takes approximately 24 hours and is expensive due to the equipment required. For this reason, the current method for regulating toxic microcystin levels in Scotland uses the indirect approach of cyanobacterial cell counts. However, this process takes even longer. Using our biological detector we hope to reduce the time and cost of microcystin detection.

First, we considered the effect that a 24 hr detection time could have on the numbers of cyanobacteria and microcystin level found in a water body. This then allowed us to determine whether faster detection methods are necessary.

Theory

Making the following assumptions:

t = 0 is the time water samples are taken
b₀ is the initial number of cyanobacteria at t=0
t is the time in hours after the water samples are taken
cyanobacteria undergo binary fission every hour
cyanobacteria growth is uninhibited
each cyanobacteria releases N microcystin molecules

We arrive at these equations:

where b(t) is the number of cyanobacteria at time t and MC(t) the number of microcystin molecules.

Since earliest result could be obtained via HPLC in 24 hours after the water samples are taken i.e. t=24, we compared this against our aim of a 1 hour detection time t=1 by evaluating equation (2).

Dividing MC(24) by MC(1) we recover an expression for MC(24) in terms of MC(1).

Results

At the detection times, t = 24 hours and t = 1 hour, the ratio for the number of microcystin molecules is 8.4 million : 1.

Than is, after 24 hours there can be up to 8.4 million times more microcystin molecules present than there is after 1 hour. Putting this ratio into perspective, this is the same as the height of the Empire State Building being compared to the combined height of 7 E. coli.

Therefore, in the time period between collection of samples and obtaining results there could potentially be a vast increase in the concentration of microcystin present in the water body. This emphasises that HPLC, or even slower alternatives, are less than optimal for toxin detection and that early detection would provide a huge advantage.

Conclusion

We conclude that faster detection methods are useful and our biological detector is worthwhile pursuing if we can reduce this detection time.

@@ Line 9: / Line 9: @@
        <!-- Title -->
        <div class="page-header">
-<h2><b>Detection Comparison</b></h2>
+<h2><b>Detection Time</b></h2>
 <div>
+<br>
 <div class="row">
 <div class="span12" style="text-align: justify">
-<h2><b>Introduction </b></h2>
-<p>The current method for regulating toxic levels of microcystin does not involve directly detecting microcystin, but instead uses cyanobacteria cell counts. One direct method for detecting microcystin is to take water samples and carry out high performance liquid chromatography (HPLC). This process takes approximately 24 hours. Using our biological detector we hope to reduce this time.
-We examine the affect that this lengthy detection time can have on the change in numbers of cyanobacteria and microcystin found in the water body that is being tested. This then allows us to determine whether faster detection methods are necessary. </p>
+<p>The  direct  method for detecting microcystin in water samples is high performance liquid chromatography (HPLC). This  process takes approximately 24 hours and is expensive due to the equipment required.  For this reason, the current method for regulating toxic microcystin levels in Scotland uses the indirect approach of cyanobacterial cell counts. However, this  process takes even longer. Using our biological detector we hope to reduce the time and cost of microcystin detection.<br><Br>
+First, we considered  the effect that a 24 hr detection time could  have on the numbers of cyanobacteria and microcystin level  found in a water body.  This then allowed us to determine whether faster detection methods are necessary.
+ </p>
 </div>
 </div>
@@ Line 23: / Line 25: @@
 <div class="row">
 <div class="span12" style="text-align: justify">
-<h2><b>Theory</b></h2>
+<h2>Theory</h2>
+</div>
+<div class="span6">
 Making the following assumptions:
 <br><br>
-<ul>
+<ul style="margin-left:50px">
 <li> t = 0 is the time water samples are taken
-<li> b0 is the initial number of cyanobacteria at t=0
+<li> b<sub>0</sub> is the initial number of cyanobacteria at t=0
 <li> t is the time in hours after the water samples are taken
 <li> cyanobacteria undergo binary fission every hour
 <li> cyanobacteria growth is uninhibited
 <li> each cyanobacteria releases N microcystin molecules
-</ul>
+</ul><br><br>
-We arrive at these equations:
 </div>
-<div class="span12" style="text-align: justify">
+<div class="span6 style="text-align: justify">
-<img src="http://placehold.it/350x150">
+<p>We arrive at these equations:</p>
+<img src="https://static.igem.org/mediawiki/2013/0/0b/Equations_Image_1.jpg"><br>
+<p>where b(t) is the number of cyanobacteria at time t and MC(t) the number of microcystin molecules.</p>
 </div>
-<div class="span12">
+<div class="span12"><br>
-<p>where b(t) is the number of cyanobacteria at time t and MC(t) the number of microcystin molecules.<br>
+<p> Since earliest result could  be obtained via  HPLC  in 24 hours after the water samples are taken i.e. t=24, we compared this against our aim of a 1 hour detection time t=1 by evaluating equation (2).  </p>
-HPLC results are obtained 24 hours after the water samples are taken i.e. t=24. We compare this against our aim of a 1 hour detection time t=1 by evaluating equation (2). </p>
 </div>
-<div class="span12" style="text-align: justify">
+<div class="span12" style="text-align: justify"><center>
-<img src="http://placehold.it/350x150">
+<img src="https://static.igem.org/mediawiki/2013/f/f2/Equations_Image_2-Dundee.jpg"></center><br>
 </div>
 <div class="span12">
-<p>Dividing MC(24) by MC(1) we recover an expression for MC(24) in terms of MC(1). <br><br></p>
+<p>Dividing MC(24) by MC(1) we recover an expression for MC(24) in terms of MC(1). <br></p>
 </div>
-<div class="span12" style="text-align: justify">
+<div class="span12" style="text-align: justify"><center>
-<img src="http://placehold.it/350x150">
+<img src="https://static.igem.org/mediawiki/2013/b/bf/Equations_Image_3.jpg"></center>
 </div>
@@ Line 63: / Line 66: @@
+<div class="row">
+  <div class="span12">
+  <h2>Results</h2>
+  </div>
+</div>
+<div class="row">
+     <div class="span12" style="text-align: justify">
+At the detection times, t = 24 hours and t = 1 hour, the ratio for the number of microcystin molecules is 8.4 million : 1.<br><Br>
+Than is,  after 24 hours there can be up to 8.4 million times more microcystin molecules present than there is after 1 hour. Putting this ratio into perspective, this is the same as the height of the Empire State Building being compared to  the combined height of 7 <i>E. coli</i>.<Br><Br>
+Therefore, in the time period between collection of samples and obtaining results there could potentially  be  a vast increase in the concentration of microcystin present in the water body. This emphasises that HPLC, or even slower alternatives,  are  less than optimal   for toxin detection and that  early detection would provide a huge advantage. <br><br>
+      </div>
+</div>
+<div class="row">
+      <div class="span6">
+        <img src="https://static.igem.org/mediawiki/2013/f/f0/Image_1.jpg" style="height:300px"><br><br>
+      </div>
+      <div class="span6">
+        <img src="https://static.igem.org/mediawiki/2013/thumb/8/82/Image_2.jpg/800px-Image_2.jpg" style="height:300px">
+      </div>
+  </div>
+  <h2>Conclusion</h2>
+We  conclude that faster detection methods are useful and our biological detector is worthwhile pursuing if we can reduce this detection time.  <br><br>
       <div id="push"></div>