Team:University College London/Module 2/Characterisation

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(Characterisation)
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== Characterisation ==
== Characterisation ==
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'''Congo Red Assay'''
The characterisation of curli expression will be done via a Congo Red agar assay. Congo Red is a diazo dye that causes cells expressing curlis to be stained <span class="footnote" title="Curlis">red</span>. Hence, Congo Red agar provides a convenient assay to determine if the expression of curlis has been successful.
The characterisation of curli expression will be done via a Congo Red agar assay. Congo Red is a diazo dye that causes cells expressing curlis to be stained <span class="footnote" title="Curlis">red</span>. Hence, Congo Red agar provides a convenient assay to determine if the expression of curlis has been successful.
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The linear structure of the amyloid curli fibril allows the formation of hydrogen bonds with the Congo Red agar, while alternative structures are forced to form ionic bonds. These ionic bonds allow the rapid dissipation of the dye colour, resulting in the formation of pale plaques where curli negative growth occurs. The hydrogen bonds do not facilitate this removal of the dye colour, hence their growth as red colonies. This assay acts as a highly effective indicator of Curli expression. 
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'''Small Scale Shear Device'''
Besides the expression of curlis, we also want to ascertain the shear resistance of the biofilm formed by the curliated cells. As such, we will also be analysing this by determining the critical shear forces involved in the attachment and detachment of cells from plastic surfaces. We will be doing this with a device modelled on the concept of a LH Fowler Cell Adhesion Measurement Module, which creates a variable shear gradient across the surface of the biofilm, thereby allowing us to ascertain the critical shear stresses at which our cells adhere and detach from the plastic <span class="footnote" title="Shear">surfaces</span>.
Besides the expression of curlis, we also want to ascertain the shear resistance of the biofilm formed by the curliated cells. As such, we will also be analysing this by determining the critical shear forces involved in the attachment and detachment of cells from plastic surfaces. We will be doing this with a device modelled on the concept of a LH Fowler Cell Adhesion Measurement Module, which creates a variable shear gradient across the surface of the biofilm, thereby allowing us to ascertain the critical shear stresses at which our cells adhere and detach from the plastic <span class="footnote" title="Shear">surfaces</span>.

Revision as of 20:16, 26 September 2012

Description | Design | Construction | Characterisation | Shear Device | Modelling | Results | Conclusions

Characterisation

Congo Red Assay

The characterisation of curli expression will be done via a Congo Red agar assay. Congo Red is a diazo dye that causes cells expressing curlis to be stained red. Hence, Congo Red agar provides a convenient assay to determine if the expression of curlis has been successful.

The linear structure of the amyloid curli fibril allows the formation of hydrogen bonds with the Congo Red agar, while alternative structures are forced to form ionic bonds. These ionic bonds allow the rapid dissipation of the dye colour, resulting in the formation of pale plaques where curli negative growth occurs. The hydrogen bonds do not facilitate this removal of the dye colour, hence their growth as red colonies. This assay acts as a highly effective indicator of Curli expression.

Small Scale Shear Device

Besides the expression of curlis, we also want to ascertain the shear resistance of the biofilm formed by the curliated cells. As such, we will also be analysing this by determining the critical shear forces involved in the attachment and detachment of cells from plastic surfaces. We will be doing this with a device modelled on the concept of a LH Fowler Cell Adhesion Measurement Module, which creates a variable shear gradient across the surface of the biofilm, thereby allowing us to ascertain the critical shear stresses at which our cells adhere and detach from the plastic surfaces.

The following equation allows us to determine the degree of shear stress our cells are exposed to in our experimental shear device:

UniversityCollegeLondon Shear Equation.jpeg

τr = Shear stress at radius r [N.m-2]

τc = Shear stress at critical radius [N.m-2]

μ = Viscosity of fluid [N.s.m-2]

N = Rotational speed of the shear device [s-1]

r = Distance from the centre of the disc [m]

x = Distance between the top and bottom disc [m]


Hence by determining the critical shear radius at which cells begin to detach, we can determine the critical shear stress.