Difference between revisions of "Team:NYMU-Taipei/Project-Model"

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B. dorsalis is a major cause of annual agricultural losses due to oviposition in fruits. Here we introduce our prototype trap and M. anisopliae, our genetically engineered fungi, to address this issue. <br>
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B. dorsalis is a major cause of annual agricultural losses due to oviposition in fruits. We hereby introduce our prototype trap and M. anisopliae, our genetically engineered fungi, to address this issue. <br>
Our model aims to demonstrate that combining our prototype with the fungi can reduce B. dorsalis’ population. We selected the SEIR model, which fits the ideal assumption in epidemiology, and revised the model to make it more practical for our purpose.<br>
+
Our model aims to demonstrate that combining our prototype with the fungi can reduce the population of B. dorsalis. We selected and revised the SEIR model, which fits the ideal assumption in epidemiology, to make it more practical for our purpose.<br>
 
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Based on our assumptions, we developed a set of differential equations that characterizes the nature of epidemic in our model:<br>
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Based on our assumptions, we developed a set of differential equations that characterizes the nature of the epidemic in our model:<br>
 
dms/dt=daily_move_in-trap-death_rate*ms<br>
 
dms/dt=daily_move_in-trap-death_rate*ms<br>
 
dfs/dt=daily_move_in-death_rate*fs<br>
 
dfs/dt=daily_move_in-death_rate*fs<br>
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The graph above shows an initial growth in population due to the attraction of B. dorsalis from the environment. However, the population subsequently drops when infected by M. anisopliae. The results indicate that the use of prototype combined with the fungi yields a 70% decrease in the B. dorsalis population. Thus, we can put our product into practice a few weeks prior to the harvest to minimize crop damage.  
+
The graph above shows the initial increase in population due to the attraction of B. dorsalis from the surrounding environment. However, the population subsequently drops when infected by M. anisopliae. The results indicate that the use of prototype combined with the fungi yields a 70% decrease in the B. dorsalis population. Thus, we can put our product into practice a few weeks prior to the harvest to minimize crop damage.  
  
 
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Revision as of 16:27, 16 October 2016








Model

Simulation of gene circuits

Epidemic


B. dorsalis is a major cause of annual agricultural losses due to oviposition in fruits. We hereby introduce our prototype trap and M. anisopliae, our genetically engineered fungi, to address this issue.
Our model aims to demonstrate that combining our prototype with the fungi can reduce the population of B. dorsalis. We selected and revised the SEIR model, which fits the ideal assumption in epidemiology, to make it more practical for our purpose.

Symbol

Description

Susceptible

B. dorsalis is slightly or moderately resistant to M. anisopliae

Exposed

B. dorsalis is exposed to a low amount of M. anisopliae in our trap; disease will be spread further during mating.

Infected

M. anisopliae enters B. dorsalis’ hemolymph and initiates cell division.

Death

B. dorsalis dies from the infection of M. anisopliae.

Based on our assumptions, we developed a set of differential equations that characterizes the nature of the epidemic in our model:
dms/dt=daily_move_in-trap-death_rate*ms
dfs/dt=daily_move_in-death_rate*fs


Parameter


Parameter

Type

Name

Meaning (Value)

Reference

Constant

Mating rate

0.8635

 

daily_capture

40

 

daily_move_in

0

 

K

adult death rate (0.05)

[1]

k0

larval death rate (0.23)

[2]

Variable

ms

susceptible male

 

Fs

susceptible female

me

exposed male

Fe

exposed female

mi

infected male

Fi

infected female

D

Death

Result


The graph above shows the initial increase in population due to the attraction of B. dorsalis from the surrounding environment. However, the population subsequently drops when infected by M. anisopliae. The results indicate that the use of prototype combined with the fungi yields a 70% decrease in the B. dorsalis population. Thus, we can put our product into practice a few weeks prior to the harvest to minimize crop damage.


Reference


1.Life History and Demographic Parameters of Three Laboratory-reared Tephritids (Diptera: Tephritidae)
2.Effect of temperature on the development and survival of immature stages of the carambola fruit fly, Bactrocera carambolae, and the Asian papaya fruit fly, Bactrocera papayae, reared on guava diet