A simple mechanical model was developed by taking an analogy of B. subtilis propelled by its flagellum with that of a boat propelled by its motor. As the bacteria swims in the medium, it experiences two opposing forces: the flagellar force which propels it forward and drag force provided by the viscosity of the liquid medium. The drag force is analagous to friction which opposes the forward motion of objects on solid surfaces. The mechanical model is illustrated below:
Mechanical Model of Motile B.subtilis
From the figure above, we equate the drag force and flagellar force to obtain:
Solving this first order ODE, we derive an expression for cell velocity:
, where
Solving the first order ODE for displacement, we derive an expression for cell trajectory:
Using our fitted data, we are able to determine parameters:
- Parameter A is the ratio of flagellar force to medium viscosity. It also represents the velocity of the cell after a sufficiently long time has elapsed, given that the flagellar force remains constant throughout its run.
- Parameter B is the initial cell velocity - in practice the velocity as we started to track the cell
- Parameter alpha is the ratio of the viscosity to the cell's mass.
As is widely known, the movement of bacteria is not that simple. Many bacteria have two distinct modes of movement: forward movement (swimming) and tumbling. The tumbling allows them to reorient and makes their movement a three-dimensional random walk.
But the boat-model can be used to analyze the swimming movement of bacteria with a few extra assumptions
- the medium is homogenous and the viscosity is constant throughout the medium
- The swimming movement is made of a finite number of trajectories that can be modelled with the boat-model. Such assumption corresponds to the idea that the bacterium pushes in a constant direction for a certain time and then pushes in a different direction for another time and so on.
- The movement of the bacteria is very smooth: there is continuity of the position and velocity
Given the random motion of bacteria, the outcome to such modelling will be the probability distribution of the model parameters and the time between the changes of pushes.
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