Team:Evry/Modeltr1
From 2013.igem.org
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The duodenum is considered as a cylinder in which a homogeneous fluid flows. So, this model is divided into three steps: the filling of duodenum, the steady state flowing step and the emptying. <br/> | The duodenum is considered as a cylinder in which a homogeneous fluid flows. So, this model is divided into three steps: the filling of duodenum, the steady state flowing step and the emptying. <br/> | ||
This model has two variables : the iron disolved in the middle (<b><span style="color:#FF0000;">S</span></b>) and the absorbed iron (<b><span style="color:#0000FF;">A</span></b>). <br/> | This model has two variables : the iron disolved in the middle (<b><span style="color:#FF0000;">S</span></b>) and the absorbed iron (<b><span style="color:#0000FF;">A</span></b>). <br/> | ||
- | We considered the chyme arrives in the duodenum at a constant rate. <b><span style="color:#FF0000;">S</span></b> has a linear component <b>Sp</b> which represents the pulses. | + | We considered the chyme arrives in the duodenum at a constant rate. <b><span style="color:#FF0000;">S</span></b> has a linear component <b>Sp</b> which represents the pulses. The also are an emptying component and an absorption component.<br/> |
- | We | + | We assumed a linear absorption and a negative feedback regulation for A.<br/> |
- | + | Finally:<br/> | |
- | Finally : | + | |
- | + | ||
<img src="https://static.igem.org/mediawiki/2013/8/82/Healthyeq.png" width=15% /><br/> | <img src="https://static.igem.org/mediawiki/2013/8/82/Healthyeq.png" width=15% /><br/> | ||
Revision as of 09:51, 26 October 2013
Disease model
Introduction
In the very beginning of the project, we focused on the duodenum and the iron absorbed by it. In order to determine if a flush treatment strategy was viable, we first had to model the behaviour of the duodenum regarding iron absorption.
Observations
60% of iron absorption takes place in the duodenum, the last 40% in the jejunum. The duodenum is located at the upper intestines, right after the stomach, and is usually 300mm long.
A healthy person absorbs about 10% (2mg a day) of the daily iron uptake, while a hemochromatosis person's absorption varies between 50% and 100% of the daily iron uptake[1].
Goals
Our goal in this part of the model is to create a generic duodenal iron absorption model so that:
- We can have a realistic base for the Final flush treatment model
- The model can can be reused in the future
Assumptions
- Our bacteria don't settle in the duodenum
- No regulation in the patient's iron absorption
- Constant iron flow
- Homogeneous fluid
- The bacterial quantity is constant
- The bacterial natural absorption is insignificant compared to the chelation
- The patient ingests 20mg of iron per day (Guideline Daily Amounts)
Materials and methods
The duodenum is considered as a cylinder in which a homogeneous fluid flows. So, this model is divided into three steps: the filling of duodenum, the steady state flowing step and the emptying.
This model has two variables : the iron disolved in the middle (S) and the absorbed iron (A).
We considered the chyme arrives in the duodenum at a constant rate. S has a linear component Sp which represents the pulses. The also are an emptying component and an absorption component.
We assumed a linear absorption and a negative feedback regulation for A.
Finally:
α | s-1 | Duodenum absorption rate |
v | m/s | Chyme's flow average speed |
L | m | Duodenum length |
Sp | mol/s | Iron pulse |
We have
Results
Conclusion
Models and scripts