Difference between revisions of "Team:UC Davis/Safety"

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<b>In the Laboratory</b><br>
 
<b>In the Laboratory</b><br>
Inside the lab the risks our project posed were the handling of the various small molecule substrates. The actions we took to reduce those risks were to work with those substrates in the fume hood, wearing eye protection, and wearing rubber gloves. One of the potential substrates, crotonaldehyde, was extremely toxic, and so the most logical action to reduce our risk from using that molecule was to simply not use it. <br>
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At the beginning of summer everyone on our team took the online UC Fundamentals of Laboratory Safety course. This course described correct use of personal protective equipment and engineering safety controls within the lab to reduce risks associated with each lab space. The course also covered methods involved in chemical safety including the identification of chemical hazards through the use of Material Safety and Data Sheets (MSDS) and pictograms as well as proper chemical storage and disposal. In addition to this general safety course, we were also trained on the laboratory specific hazards by the lab managers of the three spaces that we worked in. <br><br>
Something about the FabI genes especially the one that we got emailed about
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Since our project involved use of some proteins found in known pathogens, we decided to synthesize the genes we were interested in through IDT to express in laboratory E. coli. These safety precautions ensured that we 1. did not culture pathogenic organisms in the laboratory and 2. the proteins we expressed were not toxic or pathogenic. To ensure that our engineered strains did not exit the lab, we killed all of our cultures with 10% (v/v) bleach before disposal. We also did not transport any engineered strains outside of the lab, reducing the risk of release. <br><br>
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Our project involved the use of an array of small molecules. To ensure safety, we followed recommendations in the MSDS for each of the chemicals that we used. When ordering our library of alternate FabI substrates, we made sure not to order chemicals that were acutely toxic. For the chemicals we tested, we followed the MSDS recommendations for proper use of personal protective equipment including, wearing eye protection, lab coats, and wearing rubbing gloves, and engineering controls such as a working in the fume hood to eliminate the risk of chemical exposure.<br><br>
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Since the inhibitor we are detecting, triclosan, is toxic, we created a triclosan waste container to avoid dumping triclosan down the drain. The proper way to dispose of this container is to give it to <a href = “http://safetyservices.ucdavis.edu/quick-links/hazardous-waste-disposal-request”>UC Davis’s Environmental Health and Safety Services </a>
  
  

Revision as of 10:42, 18 September 2015



In the Laboratory
At the beginning of summer everyone on our team took the online UC Fundamentals of Laboratory Safety course. This course described correct use of personal protective equipment and engineering safety controls within the lab to reduce risks associated with each lab space. The course also covered methods involved in chemical safety including the identification of chemical hazards through the use of Material Safety and Data Sheets (MSDS) and pictograms as well as proper chemical storage and disposal. In addition to this general safety course, we were also trained on the laboratory specific hazards by the lab managers of the three spaces that we worked in.

Since our project involved use of some proteins found in known pathogens, we decided to synthesize the genes we were interested in through IDT to express in laboratory E. coli. These safety precautions ensured that we 1. did not culture pathogenic organisms in the laboratory and 2. the proteins we expressed were not toxic or pathogenic. To ensure that our engineered strains did not exit the lab, we killed all of our cultures with 10% (v/v) bleach before disposal. We also did not transport any engineered strains outside of the lab, reducing the risk of release.

Our project involved the use of an array of small molecules. To ensure safety, we followed recommendations in the MSDS for each of the chemicals that we used. When ordering our library of alternate FabI substrates, we made sure not to order chemicals that were acutely toxic. For the chemicals we tested, we followed the MSDS recommendations for proper use of personal protective equipment including, wearing eye protection, lab coats, and wearing rubbing gloves, and engineering controls such as a working in the fume hood to eliminate the risk of chemical exposure.

Since the inhibitor we are detecting, triclosan, is toxic, we created a triclosan waste container to avoid dumping triclosan down the drain. The proper way to dispose of this container is to give it to UC Davis’s Environmental Health and Safety Services

In the Real World
The risk our project might pose in the real world is the handling of hazardous substrates. We've discovered non natural substrates to use on our enzyme sensor, but the molecules we've found are somewhat hazardous. As a product, if all of the reagents would need to be self contained and never in direct contact with the user. To reduce such risk, we might want to screen for other less hazardous substrates.

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