Team:Virginia/Project Overview

From 2013.igem.org

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                 <p><a href="https://2013.igem.org/Team:Virginia/Results">Results</a></p>
                 <p><a href="https://2013.igem.org/Team:Virginia/Results">Results</a></p>
                 <p><a href="https://2013.igem.org/Team:Virginia/Modeling">Modeling</a></p>
                 <p><a href="https://2013.igem.org/Team:Virginia/Modeling">Modeling</a></p>
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                 <p><a href="https://2013.igem.org/Team:Virginia/Applications">Applications</a></p></span>
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                 <p><a href="https://2013.igem.org/Team:Virginia/Software">Software</a></p>
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                <p><a href="https://2013.igem.org/Team:Virginia/Chassis_Improvements">Chassis Improvements</a></p></span>
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                <span class="title">Human Practices</span>
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                 <p><a href="https://2013.igem.org/Team:Virginia/Human_Practices_Overview">Overview</a></p>
                 <p><a href="https://2013.igem.org/Team:Virginia/Human_Practices_Overview">Overview</a></p>
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                 <p><a href="https://2013.igem.org/Team:Virginia/Public_Perception">Public Perception</a></p>
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                 <p><a href="https://2013.igem.org/Team:Virginia/Safety Considerations">Safety Considerations</a></p>
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                 <p><a href="https://2013.igem.org/Team:Virginia/Relevance">Relevance</a></p>
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                 <p><a href="https://2013.igem.org/Team:Virginia/High_School_Education_Series">High School Education Series</a></p>
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          <p><a href="https://2013.igem.org/Team:Virginia/Outreach">Outreach</a></p></span>
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                <p><a href="https://2013.igem.org/Team:Virginia/Documentary">Documentary</a></p>
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                <p><a href="https://2013.igem.org/Team:Virginia/Media_Coverage">Media Coverage</a></p>
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<p> <p style="text-indent: 5em;">Even a miracle drug that cures all cancers, bacteria that clear plaque from coronary arteries and viruses that amend errors in the human genome mean nothing if they cannot be administered in a safe and non-toxic manner. Because of this concern, it is imperative for ambitious synthetic biologists and IGEM teams to first address this issue of safety. Many promising treatments fall short when put to the test in vivo due to one or more issues with any of the following: toxicity, poor pharmacokinetics and ineffective delivery. For these reasons, there is a significant need for versatile delivery vehicles capable of carrying therapies to select targets while minimizing adverse side effects. Such vectors could render those common hindrances inconsequential, offering new hope to a myriad of abandoned drugs and improving the efficacy of future ones. </p>
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<span><u>Project Overview</u></span>
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<p><p style="text-indent: 5em;">This year, Team Virginia sought to develop a safe and modular E. coli delivery-chassis that could be easily incorporated into a variety of other projects, making the many advantages listed above widely available. Our initial investigation led us to a forgotten discovery from the 1950’s—the bacterial minicell. Originally looked into for their potential as safer vaccines, minicell research dwindled over time due to lagging microbiological and genetic technology. While largely neglected for decades, minicells are only now resurfacing, in the wake of the recent, explosive growth of the modern biotechnology industry. As an intermediate between artificially constructed liposomes and live bacteria,a minicell captures the best qualities of both existing platforms, while lacking many of their worst features. Without a doubt, minicells are poised to become a game-changing vehicle for novel therapies.</p>  
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<p><u> Opportunity: Synthesizing a Better Drug Delivery Vector </u></p>
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<p> <p style="text-indent: 5em;">Every freely administered drug causes side effects. Cancer is a classic example. Because of off-target toxicity, many cancer patients have to hope that their chemotherapy kills their cancer before it kills them.  </p>
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<p style="text-indent: 5em;"> Many drug delivery nano-vectors have been developed to address this issue. However, most have severely limiting disadvantages. For example, liposomes, the vector projected to have the largest market share in the next ten years, are often expensive to produce and leaky in functionality. </p>
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<p><p style="text-indent: 5em;">Bacteria have several properties that would make them an interesting alternative drug delivery vectors.
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<ul><li>Their surface membranes can be modified for targeting </li>
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<li>Biological and can accommodate Biobricks </li>
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<li>Easily grown and manufactured, unlike many other drug delivery vectors. </li>
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<p style="text-indent: 5em;"> Unfortunately, as in the case of many potential synthetic biology applications, the utility of bacteria as vectors is limited by safety concerns. Our initial investigation on this problem led us to a forgotten discovery from the 1950’s—the bacterial minicell. </p>
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<p style="text-indent: 5em;"> Minicells are small, achromosomal products of aberrant cell division. Because they lack chromosomes , they cannot replicate, mutate, or express virulent bacteria genes. However, they still express transfected plasmids, which means that minicells remain fully compatible with standardized biobrick parts. While largely neglected for decades, minicells are only now resurfacing, in the wake of the recent, explosive growth of the modern biotechnology industry. This past summer, we engineered the bacterial minicell into a safe, alternative chassis for drug delivery applications. </p>
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Latest revision as of 01:54, 29 October 2013

VGEM Welcomes You!

Project Overview

Opportunity: Synthesizing a Better Drug Delivery Vector

Every freely administered drug causes side effects. Cancer is a classic example. Because of off-target toxicity, many cancer patients have to hope that their chemotherapy kills their cancer before it kills them.

Many drug delivery nano-vectors have been developed to address this issue. However, most have severely limiting disadvantages. For example, liposomes, the vector projected to have the largest market share in the next ten years, are often expensive to produce and leaky in functionality.

Bacteria have several properties that would make them an interesting alternative drug delivery vectors.

  • Their surface membranes can be modified for targeting
  • Biological and can accommodate Biobricks
  • Easily grown and manufactured, unlike many other drug delivery vectors.


Unfortunately, as in the case of many potential synthetic biology applications, the utility of bacteria as vectors is limited by safety concerns. Our initial investigation on this problem led us to a forgotten discovery from the 1950’s—the bacterial minicell.

Minicells are small, achromosomal products of aberrant cell division. Because they lack chromosomes , they cannot replicate, mutate, or express virulent bacteria genes. However, they still express transfected plasmids, which means that minicells remain fully compatible with standardized biobrick parts. While largely neglected for decades, minicells are only now resurfacing, in the wake of the recent, explosive growth of the modern biotechnology industry. This past summer, we engineered the bacterial minicell into a safe, alternative chassis for drug delivery applications.