Difference between revisions of "Team:NUS Singapore-A/InterLab"

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<h2>Objectives</h2>
 
<h2>Objectives</h2>
 
<h3> <i> What’s the main purpose of InterLab Study </i> </h3>
 
<h3> <i> What’s the main purpose of InterLab Study </i> </h3>
<p>Synthetic biology, also called engineering biology, differentiates itself from the field of biology in general through its ability to repeat and reproduce measurements and results. This reproducibility is apparent across all other engineering disciplines as well, and aids researchers in making effective comparisons for interpreting experimental controls and debugging engineered biological constructs. Through Interlab Study, iGEM’s Measurement Committee aims to achieve such reproducibility for the green fluorescent protein (GFP) in particular by developing a robust and detailed measurement protocol that anyone can follow.
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<p> Synthetic biology, also called engineering biology, differentiates itself from the field of biology in general through its ability to repeat and reproduce measurements and results. This reproducibility is apparent across all other engineering disciplines as well, and aids researchers in making effective comparisons for interpreting experimental controls and debugging engineered biological constructs. Through Interlab Study, iGEM’s Measurement Committee aims to achieve such reproducibility for the green fluorescent protein (GFP) in particular by developing a robust and detailed measurement protocol that anyone can follow.
 
</p>
 
</p>
 
<h3> <i> What is the purpose of 2018’s InterLab Study? </i> </h3>
 
<h3> <i> What is the purpose of 2018’s InterLab Study? </i> </h3>

Revision as of 15:31, 19 June 2018

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Interlab Study

Objectives

What’s the main purpose of InterLab Study

Synthetic biology, also called engineering biology, differentiates itself from the field of biology in general through its ability to repeat and reproduce measurements and results. This reproducibility is apparent across all other engineering disciplines as well, and aids researchers in making effective comparisons for interpreting experimental controls and debugging engineered biological constructs. Through Interlab Study, iGEM’s Measurement Committee aims to achieve such reproducibility for the green fluorescent protein (GFP) in particular by developing a robust and detailed measurement protocol that anyone can follow.

What is the purpose of 2018’s InterLab Study?

In Interlab 2018, iGEM aims to examine if it is possible to reduce lab-to-lab variability in fluorescence measurements by normalizing to absolute cell count or colony-forming units (CFUs) instead of OD. For this, we were required to measure the cell density of Escherichia coli DH5⍺ cells using two methods: by converting between absorbance of cells to the absorbance of a known concentration of beads, and by counting colony-forming units (CFUs) from the sample. In the first method, silica beads modelled after (roughly the same shape and size of) a typical E. coli cell are used to estimate the actual amount of E. coli cells during the fluorescence measurement of the cells.

Methods

In the first method, silica beads are used to estimate the actual amount of cells during fluorescence measurement. These beads are modelled after a typical E. coli cell, and are thus expected to scatter light in a similar way to E. Coli cells. As a sample of these silica beads give a consistent and known absorbance measurement at 600 nm, absorbance measurements from a sample’s cell density can be converted into an “equivalent concentration of beads” measurement that should be more universal and comparable between different labs.

In the second method, cell concentration is approximated is by plating a known volume of the sample and letting bacterial colonies grow. As each bacterial colony is assumed to represent a single cell (for cells that do not stick together), the cell concentration in the sample is then directly proportional to the number of CFUs. Using a scaling factor computed from negative and positive control CFUs, a conversion factor from absorbance to CFU can be computed.

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Results

Plate Reader Setup

Fluorescence
Plate Reader
  1. BioTek Synergy H1

Abs 600
  1. Wavelength: 600 nm
  2. Read Speed: Normal
  3. Delay: 100 ms
 Fluorescence
  1. Excitation 485 nm
  2. Emission: 525 nm
  3. Optics: Top
  4. Gain: 50
  5. Light Source: Xenon Flash
  6. Lamp Energy: High
  7. Read Speed: Normal
  8. Delay: 100 ms
  9. Read Height: 7 mm
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BIG HEADER BLAH

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Discussion

Conclusion

★ ALERT!

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InterLab

Bronze Medal Criterion #4

Standard Tracks: Participate in the Interlab Measurement Study and/or obtain new, high quality experimental characterization data for an existing BioBrick Part or Device and enter this information on that part's Main Page in the Registry. The part that you are characterizing must NOT be from a 2018 part number range.

For teams participating in the InterLab study, all work must be shown on this page.