|
|
Line 29: |
Line 29: |
| <p class="introduction-text">The aim of the Fifth International InterLab measurement study is to determine if we can | | <p class="introduction-text">The aim of the Fifth International InterLab measurement study is to determine if we can |
| reduce lab-to-lab variability related to fluorescence measurements, by normalizing to absolute cell count or colony forming units rather than OD measurements which are highly variable between different labs. <br> | | reduce lab-to-lab variability related to fluorescence measurements, by normalizing to absolute cell count or colony forming units rather than OD measurements which are highly variable between different labs. <br> |
− | To answer this question two approaches were used. First, the absorbance of dilution of monodisperse silica microspheres were measured. These microbeads have the same size as <i>Esherichia coli</i> cells, which allows the conversion of the absorbance measurements into equivalent concentrations of beads. The second approach consisted in counting the colony forming units | + | To answer this question two approaches were used. First, the absorbance of dilution of monodisperse silica microspheres were measured as they have the same size as <i>Esherichia coli</i> cells and the second approach consisted in counting the colony forming units |
− | (CFU) in positive and negative control samples allowing the acquirement of a conversion | + | (CFU) in positive and negative control samples. </p> |
− | factor from absorbance to CFU. </p>
| + | |
| <img src="https://static.igem.org/mediawiki/2018/e/e1/T--Sorbonne_U_Paris--Frise_interlab.png" usemap="#image-map"> | | <img src="https://static.igem.org/mediawiki/2018/e/e1/T--Sorbonne_U_Paris--Frise_interlab.png" usemap="#image-map"> |
| | | |
Line 130: |
Line 129: |
| <p>Three sets of measurements calibrations were performed: </p> | | <p>Three sets of measurements calibrations were performed: </p> |
| | | |
− | <p>First, Absorbance at 600 nm of LUDOX CL-X (45% colloidal silica suspension) was measured to use it as reference in order to acquire a conversion factor which is the result of the ratio between the corrected Absorbance at 600 nm (Arith. Mean absorbance of LUDOX CL-X - Arith. Mean absorbance of water) and a reference A<sup>600</sup>. When multiplying this factor by the measured A<sup>600</sup>, comparable A<sup>600</sup> values are obtained as they take into account the variations of volumes in the different wells </p> | + | <p>First, the absorbance of LUDOX CL-X (45% colloidal silica suspension) at 600 nm was measured and used to acquire a conversion factor which is the result of the ratio between the corrected Absorbance at 600 nm (Arith. Mean absorbance of LUDOX CL-X - Arith. Mean absorbance of water) and a reference A<sup>600</sup>. When multiplying this factor by the measured A<sup>600</sup>, comparable A<sup>600</sup> values are obtained as they take into account the variations of volumes in the different wells </p> |
| | | |
| <p>The second calibration was performed through a serial dilution of “monodisperse silica microspheres”. These microspheres were used since they have similar size and optical properties as cells, and the number of particles per volume is precisely set. We obtained a standard curve for particles (<b>Figure 1</b>) allowing the conversion of the A<sup>600</sup> into an approximate number of cells. </p> | | <p>The second calibration was performed through a serial dilution of “monodisperse silica microspheres”. These microspheres were used since they have similar size and optical properties as cells, and the number of particles per volume is precisely set. We obtained a standard curve for particles (<b>Figure 1</b>) allowing the conversion of the A<sup>600</sup> into an approximate number of cells. </p> |