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<h3>Gold Medal Criterion #1</h3>
 
<h3>Gold Medal Criterion #1</h3>
<p>Expand on your silver medal activity by demonstrating how you have integrated the investigated issues into the design and/or execution of your project.</p>
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<li><p><font size="3"> We went to Hangzhou Zhongmei Huadong Pharmaceutical Co., Ltd. introducing our project to their director of Macromolecular Laboratory and asking for the possibility that if our blue-light-controlled self-lysis system could fit their production in the middle of our experiments. But our system was consisted of two plasmids (one for light-controlled part and one for FixK2 promoter and lysin) at that time. Therefore the director told us only if we could solve the problem of multi-plasmids pressure in cells then could our project be used in fermentation industry. We had spent a long time connecting the light-controlled system and the functional gene so that they can be put in the same one plasmid. In some ways we solved the problem of multi-plasmids pressure by reducing one plasmid in the system. And we may work on making one kind of plasmid vector with our blue-light-controlled self-lysis system which can be directly used by fermentation factories for genetically engineered producing strains in the future. </p></li>
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<li> Eggs </li>
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<p><font size="3"> We went to Hangzhou Zhongmei Huadong Pharmaceutical Co., Ltd. introducing our project to their director of Macromolecular Laboratory and asking for the possibility that if our blue-light-controlled self-lysis system could fit their production in the middle of our experiments. But our system was consisted of two plasmids (one for light-controlled part and one for FixK2 promoter and lysin) at that time. Therefore the director told us only if we could solve the problem of multi-plasmids pressure in cells then could our project be used in fermentation industry. We had spent a long time connecting the light-controlled system and the functional gene so that they can be put in the same one plasmid. In some ways we solved the problem of multi-plasmids pressure by reducing one plasmid in the system. And we may work on making one kind of plasmid vector with our blue-light-controlled self-lysis system which can be directly used by fermentation factories for genetically engineered producing strains in the future. </p>
  
 
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<h3>Best Integrated Human Practices Special Prize</h3>
 
<h3>Best Integrated Human Practices Special Prize</h3>
  

Revision as of 18:32, 1 November 2017

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ZJUT-China

Gold Medal and Integrated Human Practices

Gold Medal Criterion #1

  1. We went to Hangzhou Zhongmei Huadong Pharmaceutical Co., Ltd. introducing our project to their director of Macromolecular Laboratory and asking for the possibility that if our blue-light-controlled self-lysis system could fit their production in the middle of our experiments. But our system was consisted of two plasmids (one for light-controlled part and one for FixK2 promoter and lysin) at that time. Therefore the director told us only if we could solve the problem of multi-plasmids pressure in cells then could our project be used in fermentation industry. We had spent a long time connecting the light-controlled system and the functional gene so that they can be put in the same one plasmid. In some ways we solved the problem of multi-plasmids pressure by reducing one plasmid in the system. And we may work on making one kind of plasmid vector with our blue-light-controlled self-lysis system which can be directly used by fermentation factories for genetically engineered producing strains in the future.

  2. Eggs

We went to Hangzhou Zhongmei Huadong Pharmaceutical Co., Ltd. introducing our project to their director of Macromolecular Laboratory and asking for the possibility that if our blue-light-controlled self-lysis system could fit their production in the middle of our experiments. But our system was consisted of two plasmids (one for light-controlled part and one for FixK2 promoter and lysin) at that time. Therefore the director told us only if we could solve the problem of multi-plasmids pressure in cells then could our project be used in fermentation industry. We had spent a long time connecting the light-controlled system and the functional gene so that they can be put in the same one plasmid. In some ways we solved the problem of multi-plasmids pressure by reducing one plasmid in the system. And we may work on making one kind of plasmid vector with our blue-light-controlled self-lysis system which can be directly used by fermentation factories for genetically engineered producing strains in the future.

Best Integrated Human Practices Special Prize

To compete for the Best Integrated Human Practices prize, please describe your work on this page and also fill out the description on the judging form.

You must also delete the message box on the top of this page to be eligible for this prize.

Inspiration

Here are a few examples of excellent Integrated Human Practices work: