Team:Calgary/Notebook/Calendar/Week1

From 2011.igem.org

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<span id="bodytitle"><h1>Week One</h1></span>
<span id="bodytitle"><h1>Week One</h1></span>
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<p> This week we mainly worked on defining the scope and objectives of the iGEM project.  As a group, we had already decided that we wanted to focus on an issue concerning tailing ponds; our discussion of tailing ponds centered around environmental reclamation and three central issues around it: fine particles, naphthenic acids, and problematic byproducts of microbial respiration. </p>
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<h2>Monday (May 2)</h2>  
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<p> Fine particles are small, lightweight particles (such as silt) which take on the order of hundreds of years to settle fully within tailing ponds.  Fine particles matter because tailing ponds can only be reclaimed by the environment after enough material has "packed" to the bottom of the pond, meaning that reclamation is indefinitely postponed by fine particles. </p>
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After introducing ourselves to each other, we began brainstorming project concepts. Four main ideas surfaced: Using a biofilm to filter out fine particulate matter, developing a biosensor to detect naphthenic acids, developing a method to clump fine particulate matter, and promoting sulphur-reducing bacteria. We split ourselves up into groups to examine the feasibility of each idea.
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<p>Naphthenic acids, on the other hand, are a largely inclusive group of acids which contribute to the toxicity of nearby soil and groundwater; naphthenic acids are toxic to aquatic and terrestrial wildlife, and postpone the development of healthy ecosystems after reclamation.</p>
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<h2>Tuesday (May 3)</h2>
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<p>Lastly, the tailing ponds are home to a variety of aerobic and anaerobic organisms, the latter of which consists of methanogens and sulfur-reducing bacteria. Potentially, both bacteria produce greenhouse gases; immprovements could be made to the ratio of bacteria (they are competive species), and on whether they can contribute to naphthenic acid degradation. </p>
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The initial findings of our research were completed and we narrowed our focus towards the biosensor idea. The requirements for developing a biosensor specific to naphthenic acids were discussed, and a list of areas for further research was developed. The group was split into separate teams once again, to determine the extent of prior research in the area.
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<p>Four ideas bubbled up from our discussion of solving these two issues. To handle densification, we considered building a biofilm for filtration purposes, and engineering a bacteria to assist in particle-densification itself. To handle naphthenic acids, we considered naphthenic acid degradation and sensing.</p>
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<h2>Wednesday (May 4)</h2>
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<h2>Thursday (May 5)</h2>
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<h2>Friday (May 6)</h2>
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<p>The group unanimously settled on building a biosensor for naphthenic acids, and started to read previous literature on the field.  Also, we wrote a research proposal for the Oil Sands Leadership Initiative.</p>
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Revision as of 23:41, 25 May 2011

Week One

This week we mainly worked on defining the scope and objectives of the iGEM project. As a group, we had already decided that we wanted to focus on an issue concerning tailing ponds; our discussion of tailing ponds centered around environmental reclamation and three central issues around it: fine particles, naphthenic acids, and problematic byproducts of microbial respiration.

Fine particles are small, lightweight particles (such as silt) which take on the order of hundreds of years to settle fully within tailing ponds. Fine particles matter because tailing ponds can only be reclaimed by the environment after enough material has "packed" to the bottom of the pond, meaning that reclamation is indefinitely postponed by fine particles.

Naphthenic acids, on the other hand, are a largely inclusive group of acids which contribute to the toxicity of nearby soil and groundwater; naphthenic acids are toxic to aquatic and terrestrial wildlife, and postpone the development of healthy ecosystems after reclamation.

Lastly, the tailing ponds are home to a variety of aerobic and anaerobic organisms, the latter of which consists of methanogens and sulfur-reducing bacteria. Potentially, both bacteria produce greenhouse gases; immprovements could be made to the ratio of bacteria (they are competive species), and on whether they can contribute to naphthenic acid degradation.

Four ideas bubbled up from our discussion of solving these two issues. To handle densification, we considered building a biofilm for filtration purposes, and engineering a bacteria to assist in particle-densification itself. To handle naphthenic acids, we considered naphthenic acid degradation and sensing.

The group unanimously settled on building a biosensor for naphthenic acids, and started to read previous literature on the field. Also, we wrote a research proposal for the Oil Sands Leadership Initiative.