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Objectives

Week 4

Day	Monday	Tuesday	Wednesday	Thursday	Friday
Objectives				Piotr, Anita and Kyasha start work on modelling.	Clearly identify all steps of the output pathway and draw out the diagram. Start with the simplest case and build up from there.
Completion				It was recognised that modelling of output amplification model would be beneficial as model could give answer to how many amplification steps would be most effective in given context. It was decided that other model to be done afterwards would involve modelling the activation of our ComD receptor and the disaply of proteins. It was concluded that the amplification model except for transcription and translation was involving just enzymatic reactions.	Tried approaching the output amplification model using Michaelis-Menten kinetics as Kyasha had already some experience in doing that. Decided to have a go on implementing the simple production equations in MatLab.

Week 5

Day	Monday	Tuesday	Wednesday	Thursday	Friday
Objectives	Attempt implementing 1 step amplifcation into Matlab. Continue developing models/equations/reactions of 2 and 3 step amplification.	Try using TinkerCell to implement the 2 and 3 step amplification systems and then export them to SimBiology MatLab interface for verfication.	Prepare short slide presentation for advisers for 12.00. Meeting with students from the Royal College of Arts later on during the day.	Keep implementing the models in MatLab. Start looking for constants needed.	Continue looking for the relevant constants. Meeting with Dr Matthieu Bultelle was arranged.
Completion	First steps in implementing even simple systems of equations into MatLab are being taken slow.	Implementing in TinkerCell was successful. However, its results need to be verified by coding in MatLab later on. We hoped to be able to generate set of equations for MatLab after creating the visual network in TinkerCell, but this functionality was not working in the program. Continue developing models/equations/reactions of 2 and 3 step amplification.	Presentation was given	We didn't manage to find many information on relveant constants. We decided to arrange meeting with advisers for next day to help us with the issue.	Matthieu explained to us that we need to look for estimates or make them ourselves based on prior knowledge. It is very rare to be able to find the exact constants that are needed without perfomring an experiment. Even performing experiments is not always giving exact numbers. During the meeting we went through of what we have so far. It was discovered that we have committed a major error. Our system does not seem to obey Michaelis-Menten kinetics. We have remake the models using just law of Mass Action.

Week 6

Day	Monday	Tuesday	Wednesday	Thursday	Friday
Objectives		Since we ended up having 14 differential equations to model 2-step output amplification, attempt implementing the model in TinkerCell as its environment seems to allow easier implementation of that situation.		Kyasha left to the wet lab team. Anita and Piotr remain in dry lab. Find constants.	Find protein production constants and TEV reaction rate constants.
Completion				We didn't manage to complete the task.	The orders of magnitude established - ready to run simulations.

Week 7

Day	Monday	Tuesday	Wednesday	Thursday	Friday
Objectives	Implementing the constant ranges in the output model. Comparing the results between the models.	Start modelling the protein display signalling to find the concentrations. Explain the oscillations that are occuring in the output amplification model.	Research stiff differential equations. Research on receptor (especially MAP kinase). Finalise results for amplification model. Prepare presentation.	During the meeting it was decided that we should test amplificiation model for its sensitivity to change of parameter values. This is to determine the key parameters to be measured in the lab.	Discuss the experiments for amplification module further. Start on modelling the protein display on cell surface.
Completion	The task is accomplished. However, unexplained oscillations are observed for some specific values.	We got rid of the oscillations in our model (by using ode15s instead of ode45).	Presentation ready. Reading on stiff equations done.	Key sensitive parameters determined. Experiments initially discussed with Chris.	Further consult on experiments for determining parameters needed for modelling with James and Wolf. Initial thought for a protein display model implemented in MatLab.

Week 8

Day	Monday	Tuesday	Wednesday	Thursday	Friday
Objectives	Test the protein display model and find to what kind of values it's sensitive to.	Define the control volume around the bacterial cell. Start on testing the model.	We realised that it would be worth adding the last step (colour production by dioxygenase) into our amplfication models.	We need to finalise testing and formulation of certain assumptions regarding the amplfication (cell death in particular). Consider helping RMIT- Australia in modelling.	Keep exploring the prospective solutions to our system going unstable. Try to implement the last bit of amplification in TinkerCell. Maybe it will deal with it well.
Completion	We couldn't reach the testing as the first model "Display 1" was simulating reactions as if the were taking place inside the bacterial cell while in reality the take place outside. Then we hit an issue of defining the size of volume around the cell. We didn't manage to resolve that problem today.	Control volume defined. Testing of model done. Protein model pretty much finalised.	The colour production almost complete, however complications were encountered regarding the cell death (colour compound slowly kills cells).	Basically we're stuck: scaling didn't help neither did trying idfferent solvers. Meeting with Matthieu gave us some prospective solutions that we can explore. Alternatively we can have a look at SimBiology or MatCont. Helping RMIT: their request is for protein engineering simulation - we cannot do that	We know how to use the ''splinetool'' in Matlab. Specifying the time span helps to reduce the simulation time. Model was implemented in TinkerCell. Increasing relative or absolute tolerance in Matlab prevents some solutions from going negative. The key point is that we are only interested in the first few minutes of the experiment as the reaction to catechol is really quick.

Week 9

Day	Monday	Tuesday	Wednesday	Thursday	Friday
Objectives	Bank Holiday	Compare Tinker Cell results against MatLab simulations (Amplficiation model). Compare SimBiology package (in Matlab) results against equations we have derived. (amplification model). See how we could explore the problem of false negatives in Protein Display model.	Discuss the protein display false positive. Prepare presentation for the meeting. Compare the catechol colour response (cells alive vs. immediate cell death). Discuss with Matthieu on the issue of negative concentrations, volume approximations made in protein display model and the idea of modelling the false positive case.	Update Modelling section of the Wiki. Update list of experiments (especially for Protein Display Model) and discuss with Chris and Wolf.	Keep modifying wiki. Keep writing little bits that were left out previously.
Completion		Tinkercell is not very good at dealing with very high or low values. SimBiology package generates same graphs as our manual simulations. The interface is quite easy to use. Decreasing absolute and relative tolerances is becoming accpeted as a solution to a negative concentrration problem.	Modelling of false positive in display protein is postponed as more research need to be done on the affinities etc. Presentation was given - feedback is to be implemented. It was deduced that we should model the cells as alife, because of the slow cell death induced by addition of catechol. Matthieu was consulted and the feedback is posted here.	Restructuring modelling wiki is now on! Experiments discussed with Wolf and all should be doable.	Wiki updating will continue next week.

Week 10

Day	Monday	Tuesday	Wednesday	Thursday	Friday
Objectives	Do the referencing of all Modelling Wiki pages. Look into using HTML and Javascript.	Make new tables for the Objectives section.	Make a jquery accordion list for the first Modelling page.	Rewrite pages into html. Update tables (Variables and Constants).	Last day!!! Finish rewriting pages into html. Meeting with the advisors at 2pm.
Completion	Referencing finished. Keep on looking into HTML.	New tables completed.	List completed.	Rewriting into html not yet completed. Tables completed.

@@ Line 96: / Line 96: @@
      </td>
      <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
+      <ul>
+        <li>Attempt implementing 1 step amplifcation into Matlab.</li>
+        <li>Continue developing models/equations/reactions of 2 and 3 step amplification.</li>
+      </ul>
      </td>
-<td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
+    <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
+       <ul>
+        <li>Try using TinkerCell to implement the 2 and 3 step amplification systems and then export them to SimBiology MatLab interface for verfication.</li>
+      </ul>
      </td>
 <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
-    </td>
+       <ul>
+        <li>Prepare short slide presentation for advisers for 12.00.</li>
+        <li>Meeting with students from the Royal College of Arts later on during the day.</li>
+      </ul>
+</td>
 <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
 <ul>
-<li>Find constants.</li>
+<li>Keep implementing the models in MatLab.</li>
+<li>Start looking for constants needed.</li>
 </ul>
      </td>
 <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
-<ul>
+       <ul>
-<li>Find protein production constants and TEV reaction rate constants.</li>
+        <li>Continue looking for the relevant constants.</li>
-</ul>
+        <li>Meeting with Dr Matthieu Bultelle was arranged.</li>
+      </ul>
      </td>
    </tr>
    <tr>
-    <td style="background-color:#FFCC66;width:100px;text-align:center;"><b>Completion</b>
+  <td style="background-color:#FFCC66;width:100px;text-align:center;"><b>Completion</b>
      </td>
      <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
+      <ul>
+        <li>First steps in implementing even simple systems of equations into MatLab are being taken slow.</li>
+      </ul>
      </td>
-<td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
+  <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
+       <ul>
+        <li>Implementing in TinkerCell was successful. However, its results need to be verified by coding in MatLab later on. We hoped to  be able to generate set of equations for MatLab after creating the visual network in TinkerCell, but this functionality was not working in the program.</li>
+        <li>Continue developing models/equations/reactions of 2 and 3 step amplification.</li>
+      </ul>
      </td>
 <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
-    </td>
+<ul>
+<li>Presentation was <a href="http://openwetware.org/wiki/Image:Presentation_04_august.pptx">given</a></li>
+</ul>
+</td>
 <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
 <ul>
-<li>We didn't manage to complete the task.</li>
+<li>We didn't manage to find many information on relveant constants. We decided to arrange meeting with advisers for next day to help us with the issue.</li>
 </ul>
      </td>
 <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
 <ul>
-<li>The orders of magnitude established - ready to run simulations.</li>
+<li>Matthieu explained to us that we need to look for estimates or make them ourselves based on prior knowledge. It is very rare to be able to find the exact constants that are needed without perfomring an experiment. Even performing experiments is not always giving exact numbers.</li>
+<li>During the meeting we went through of what we have so far. It was discovered that we have committed a major error. Our system does not seem to obey Michaelis-Menten kinetics. We have remake the models using just law of Mass Action.</li>
 </ul>
      </td>
@@ Line 162: / Line 186: @@
      </td>
 <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
-    </td>
+       <ul>
+        <li>Since we ended up having 14 differential equations to model 2-step output amplification, attempt implementing the model in TinkerCell as its environment seems to allow easier implementation of that situation.</li>
+      </ul>
+ </td>
 <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
      </td>
 <td style="background-color:#eeeeee;height:100px;width:200px;text-align:top;">
 <ul>
+<li>Kyasha left to the wet lab team. Anita and Piotr remain in dry lab.</li>
 <li>Find constants.</li>
 </ul>

IGEM:Imperial/2010/Objectives

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