Team:Imperial College/Motility Control

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=== Results of Motility Analysis ===
=== Results of Motility Analysis ===
{{Imperial/Box1|Results|
{{Imperial/Box1|Results|
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We modelled the motility of motile ''B.subtilis'' using a mechanical model as shown above. Using experimental data from cell tracking, we were able to extract parameters which describe the model. The model and its parameters are defined [[Team:Imperial_College/Motility| '''here''']]. In summary, parameter ''A'' is the ratio of flagellum force to medium viscosity. It also represents the velocity of the cell after a sufficiently long time has elapsed, given that the flagellum force remains constant throughout its run., ''B'' is the initial velocity of the cell and alpha is the ratio of the vicosity of the medium to the cell's mass.
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We modelled the motility of motile ''B.subtilis'' using a mechanical model as shown above. Using experimental data from cell tracking, we were able to extract parameters which describe the model. The model and its parameters are defined [[Team:Imperial_College/Motility| '''here''']]. In summary, parameter ''A'' is the ratio of flagellum force to medium viscosity. It also represents the velocity of the cell after a sufficiently long time has elapsed, given that the flagellum force remains constant throughout its run. Parameter ''B'' is the initial velocity of the cell and ''alpha'' is the ratio of the vicosity of the medium to the cell's mass.
The following figure shows the results of our model fitting. We have introduced a change in flagellar force at certain points of the cell trajectory so as to achieve a better fit. A maximum of two runs were allowed for each cell trajectory.
The following figure shows the results of our model fitting. We have introduced a change in flagellar force at certain points of the cell trajectory so as to achieve a better fit. A maximum of two runs were allowed for each cell trajectory.
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The MATLAB Distribution Fitting Tool was used to model the distribution of parameter A, which is directly proportional to the flagellum force, assuming that the medium is homogenous and its viscosity is constant throughout the medium. Parameter A was the found to be exponentially distributed. The following figures describe the probability density function (PDF) and cumulative distribution function (CDF).
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The MATLAB Distribution Fitting Tool was used to model the distribution of parameter A, which is directly proportional to the flagellar force, assuming that the medium is homogenous and its viscosity is constant throughout the medium. Parameter A was found to be exponentially distributed. The following figures describe the probability density function (PDF) and cumulative distribution function (CDF).
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{{Imperial/Box2|Conclusion|
{{Imperial/Box2|Conclusion|
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We fitted the data according to the simple mechanical model we have developed. From our model fitting process, we can see that flagellum force is exponentially distributed. Our mechanical model though simple, fits the cell trajectory data extremely well as shown in the figure above. Further work which can be done would be to utilise a movable stage to track the movement of ''B. subtilis'' over its entire run so as to obtain a distribution of other motility parameters associated running and tumbling events. |}}
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We fitted the data according to the simple mechanical model we have developed. From our model fitting process, we can see that flagellar force is exponentially distributed. Our mechanical model though simple, fits the cell trajectory data extremely well as shown in the figure above. Further work which can be done would be to utilise a movable stage to track the movement of ''B. subtilis'' over its entire run so as to obtain a distribution of other motility parameters associated running and tumbling events. |}}
{{Imperial/EndPage|Major_Results|Major_Results}}
{{Imperial/EndPage|Major_Results|Major_Results}}

Latest revision as of 01:58, 30 October 2008


Results of Motility Analysis

Results
Mechanical Model.jpg
Mechanical Model of Motile B.subtilis

We modelled the motility of motile B.subtilis using a mechanical model as shown above. Using experimental data from cell tracking, we were able to extract parameters which describe the model. The model and its parameters are defined here. In summary, parameter A is the ratio of flagellum force to medium viscosity. It also represents the velocity of the cell after a sufficiently long time has elapsed, given that the flagellum force remains constant throughout its run. Parameter B is the initial velocity of the cell and alpha is the ratio of the vicosity of the medium to the cell's mass.

The following figure shows the results of our model fitting. We have introduced a change in flagellar force at certain points of the cell trajectory so as to achieve a better fit. A maximum of two runs were allowed for each cell trajectory.

Fitted Models.jpg
Fitted Models with Experimental Data from 4 Cells


The MATLAB Distribution Fitting Tool was used to model the distribution of parameter A, which is directly proportional to the flagellar force, assuming that the medium is homogenous and its viscosity is constant throughout the medium. Parameter A was found to be exponentially distributed. The following figures describe the probability density function (PDF) and cumulative distribution function (CDF).

Exponential Distribution for Parameter A PDF.jpg
Exponential Distribution for Parameter A CDF.jpg
Probability Distribution for Parameter A
Cumulative Distribution for Parameter A

Conclusion

We fitted the data according to the simple mechanical model we have developed. From our model fitting process, we can see that flagellar force is exponentially distributed. Our mechanical model though simple, fits the cell trajectory data extremely well as shown in the figure above. Further work which can be done would be to utilise a movable stage to track the movement of B. subtilis over its entire run so as to obtain a distribution of other motility parameters associated running and tumbling events.



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