Difference between revisions of "Team:NUS Singapore/Overview"

Line 164: Line 164:
 
<body>
 
<body>
 
         <h1>Overview</h1>
 
         <h1>Overview</h1>
 
+
        <h2>Methodology</h2>
 
<div class="columnleft">
 
<div class="columnleft">
 
<p>With the advancement in the field of synthetic biology, scientists have successfully engineered microbes to combat challenges in various fields such as medicine, energy, and environment. These genetically engineered microbes are however not commercialized due to the risk of bacteria escaping from the targeted host into the environment. To address this issue, we develop the NUSgem Kill-switch Toolkit that enables users to build customized and effective kill-switches for different applications. This toolkit consists of a library of characterized sensors, logic gates, and killing systems. </p>
 
<p>With the advancement in the field of synthetic biology, scientists have successfully engineered microbes to combat challenges in various fields such as medicine, energy, and environment. These genetically engineered microbes are however not commercialized due to the risk of bacteria escaping from the targeted host into the environment. To address this issue, we develop the NUSgem Kill-switch Toolkit that enables users to build customized and effective kill-switches for different applications. This toolkit consists of a library of characterized sensors, logic gates, and killing systems. </p>
Line 174: Line 174:
  
 
<div class="clear"></div>
 
<div class="clear"></div>
 +
      <h2>Kill-switch for probiotics</h2>
 
<div class="columnleft">
 
<div class="columnleft">
 
<p>With the advancement in the field of synthetic biology, scientists have successfully engineered microbes to combat challenges in various fields such as medicine, energy, and environment. These genetically engineered microbes are however not commercialized due to the risk of bacteria escaping from the targeted host into the environment. To address this issue, we develop the NUSgem Kill-switch Toolkit that enables users to build customized and effective kill-switches for different applications. This toolkit consists of a library of characterized sensors, logic gates, and killing systems. </p>
 
<p>With the advancement in the field of synthetic biology, scientists have successfully engineered microbes to combat challenges in various fields such as medicine, energy, and environment. These genetically engineered microbes are however not commercialized due to the risk of bacteria escaping from the targeted host into the environment. To address this issue, we develop the NUSgem Kill-switch Toolkit that enables users to build customized and effective kill-switches for different applications. This toolkit consists of a library of characterized sensors, logic gates, and killing systems. </p>
Line 185: Line 186:
  
 
<div class="columnleft">
 
<div class="columnleft">
 +
        <h2>Kill-switch for BeeT</h2>
 
<p>With the advancement in the field of synthetic biology, scientists have successfully engineered microbes to combat challenges in various fields such as medicine, energy, and environment. These genetically engineered microbes are however not commercialized due to the risk of bacteria escaping from the targeted host into the environment. To address this issue, we develop the NUSgem Kill-switch Toolkit that enables users to build customized and effective kill-switches for different applications. This toolkit consists of a library of characterized sensors, logic gates, and killing systems. </p>
 
<p>With the advancement in the field of synthetic biology, scientists have successfully engineered microbes to combat challenges in various fields such as medicine, energy, and environment. These genetically engineered microbes are however not commercialized due to the risk of bacteria escaping from the targeted host into the environment. To address this issue, we develop the NUSgem Kill-switch Toolkit that enables users to build customized and effective kill-switches for different applications. This toolkit consists of a library of characterized sensors, logic gates, and killing systems. </p>
 
</div>
 
</div>

Revision as of 03:26, 29 October 2017

Overview

Methodology

With the advancement in the field of synthetic biology, scientists have successfully engineered microbes to combat challenges in various fields such as medicine, energy, and environment. These genetically engineered microbes are however not commercialized due to the risk of bacteria escaping from the targeted host into the environment. To address this issue, we develop the NUSgem Kill-switch Toolkit that enables users to build customized and effective kill-switches for different applications. This toolkit consists of a library of characterized sensors, logic gates, and killing systems.

Kill-switch for probiotics

With the advancement in the field of synthetic biology, scientists have successfully engineered microbes to combat challenges in various fields such as medicine, energy, and environment. These genetically engineered microbes are however not commercialized due to the risk of bacteria escaping from the targeted host into the environment. To address this issue, we develop the NUSgem Kill-switch Toolkit that enables users to build customized and effective kill-switches for different applications. This toolkit consists of a library of characterized sensors, logic gates, and killing systems.

Kill-switch for BeeT

With the advancement in the field of synthetic biology, scientists have successfully engineered microbes to combat challenges in various fields such as medicine, energy, and environment. These genetically engineered microbes are however not commercialized due to the risk of bacteria escaping from the targeted host into the environment. To address this issue, we develop the NUSgem Kill-switch Toolkit that enables users to build customized and effective kill-switches for different applications. This toolkit consists of a library of characterized sensors, logic gates, and killing systems.