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Revision as of 06:23, 21 October 2019
Predator-Prey Model
Predator-prey models can deal with the general loss-win interactions. Our group use predator-prey model to construct the relationship between two algaes, Oxyrrhis marina and Dunaliella tertiolecta.
The Lotka-Volterra Equations
explain Lotka-Volterra
Why a model?
The reason why a predator/prey model for Oxyrrhis marina and Dunaliella tertiolecta is being viewed in ASP-8A rather than F2 media (the media GSU iGEM decided to grow O. marina in) is because the team noticed than D. tertiolecta will begin to overgrow in ASP-8A media alongside the O. marina and eventually outcompete O. marina in the culture. This observation was made from June through August when the different types of media were being tested. The goal is to examine how much to feed the predator (O. marina) until the prey (D. tertiolecta) begins to overgrow.
Defining Our System
Parameters
- D.T: Concentration of Dunaliella tertiolecta
- O.M: Concentration of Oxyrrhis marina
- a: Rate D.T is added to the system
- b: D.T growth rate
- c: Predation rate
- d: O.M growth rate
- f: O.M death rate
The model satisfies the identity:
I'm the first element in the nested grid
I'm the second element in the nested grid
I'm the third element in the first grid
Determining Our Rate Constants
We start 5 different Dunaliella tertiolecta amount to feed in each 75ml flask. The start points are 0.25 ml, 0.5ml, 1.0ml, 1.5ml, 2.0ml of concentration of 792,000/ml.
The two conditions start of 0.25ml and 0.5ml D.T are seem as the ideal condition that D.T will not overgrow and O.M concentration continues to increase.