Team:UCL London/Modeling/Model1

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==Description==
==Description==
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On a larger scale, we will put cells at stress. With a selected number of stress we intend to determine how the cells react. Here we will focus on the Oxygen stress individually. At a later stage we will consider another stress independently, then build model onthis stress in order to determine characteristic parameters. Ultimately we will have a joint model for the two stresses and will come with r4ecommendation on such an environment.
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At a later stage we will consider another stress independently, then build a model on this stress in order to determine the characteristic parameters. Ultimately we will have a joint model for the two stresses and will eventually obtain a recommendation on the environment.
==Objectives==
==Objectives==
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The objectives of this model is to determine Oxygen levels at which the cells are put at a stress they can not cope with so that the size of the colony is decreasing. Therefore the ultimate objective of the model is determining the minimum level of oxygen (kept constant) at which the size of the colony is stable.
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The objectives of this model is to determine Oxygen stress levels at which the cells are put at a stress they can not cope with so that the cells begin to decrease in number. Therefore the ultimate objective is to create a model of the kinetics of the E-coli cells in relation to the oxygen stress levels; determining the minimum level of oxygen (kept constant) at which the size of the colony is stable.
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From the lab we will verify the parameters taken are the right ones. We will also define the percentage error judged admissible.
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From the lab we will verify that the parameters taken are correct. We will also define the percentage error judged admissible.
==Equations==
==Equations==
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:kd is the specific death constant
:kd is the specific death constant
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* Oxydgen uptake rate: Q(t)=Q0*x(t)
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* Oxygen uptake rate: Q(t)=Q0*x(t)
:Q0 is the specific O2 uptake rate
:Q0 is the specific O2 uptake rate
:x is the cell concentration
:x is the cell concentration
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*Rate of oxygen transfer per unit of volume of fluid: Na=kl*a*((Cal*)*Cal)
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*Rate of oxygen transfer per unit of volume of fluid: Na=kl*a*(Cal*-Cal*)
:kl is the liquid phase mass transfer coefficient
:kl is the liquid phase mass transfer coefficient
:a is the gas liquid interfacial area per unit of volume of liquid
:a is the gas liquid interfacial area per unit of volume of liquid

Latest revision as of 14:46, 15 July 2009

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Oxygen and Cell concentration model

Description

At a later stage we will consider another stress independently, then build a model on this stress in order to determine the characteristic parameters. Ultimately we will have a joint model for the two stresses and will eventually obtain a recommendation on the environment.

Objectives

The objectives of this model is to determine Oxygen stress levels at which the cells are put at a stress they can not cope with so that the cells begin to decrease in number. Therefore the ultimate objective is to create a model of the kinetics of the E-coli cells in relation to the oxygen stress levels; determining the minimum level of oxygen (kept constant) at which the size of the colony is stable.

From the lab we will verify that the parameters taken are correct. We will also define the percentage error judged admissible.

Equations

We will assume the following equations:

  • Equation of growth: x(t)=x0*exp(mu*t)
x0 is the initial concentration of E Coli
mu is the growth rate specific to the E Coli
  • Growth and decline phases: rx=mu*x(t)
rx is the volumetric rate of biomass production
  • Number of cells at a time t: N=N0*Exp(-kd*t)
kd is the specific death constant
N0 is the initial number of cells
  • Rate of cells death: rd=kd*N
N is the number of viable cells
kd is the specific death constant
  • Oxygen uptake rate: Q(t)=Q0*x(t)
Q0 is the specific O2 uptake rate
x is the cell concentration
  • Rate of oxygen transfer per unit of volume of fluid: Na=kl*a*(Cal*-Cal*)
kl is the liquid phase mass transfer coefficient
a is the gas liquid interfacial area per unit of volume of liquid
Cal* is the oxygen concentration in broth on equilibrium with gas phase
Cal oxygen concentration in broth

Parameters