Difference between revisions of "Team:Uppsala/Description"

 
(9 intermediate revisions by 4 users not shown)
Line 11: Line 11:
 
     <div class="container">
 
     <div class="container">
 
         <div class="row">
 
         <div class="row">
            <div class="col-lg-8" style="margin:auto; float:none;">
+
<!--
                <h3> Table of contents </h3>
+
<nav class="navbar nav-left hidden-print hidden-sm hidden-xs affix">
 
+
<ul class="nav bs-docs-sidenav">
                <ul>
+
                     <li> <a href="#summary"> Summary</a></li>
                     <li> <a href="#summary"> Summary </a></li>
+
 
                     <li> <a href="#origin"> Project origins </a></li>
 
                     <li> <a href="#origin"> Project origins </a></li>
 +
</ul>
 +
</nav>
 +
--!>
 +
            <div class="col-lg-8 text">
 +
                <h3 id="summary"> Summary </h3>
  
                </ul>
+
<p>With our project we wanted to make microfluidic chips easier and more available for iGEM teams and other small labs. Microfluidic chips can and have been used to carry out many laboratory procedures in a micro-scale, effectively downscaling and streamlining laboratory work. The smaller volumes and workload have the potential to lower the cost of bench-top procedures and this is one of the larger advantages that microfluidics brings to research. </p>
 
+
<p>Fabrication methods for microfluidic chips have become faster and easier, making prototyping a rapid task. Despite the advances in fabrication methods the cost of making microfluidic chips is still high and the equipment needed is expensive. This can be exemplified by the fact that a clean room is needed for the regular photolithography/soft lithography method. We wanted to change this. That is why we created a 3D-printing based fabrication method that does not require expensive specialized equipment. A mold for the chip can be 3D printed once and therefore the lab does not need its own 3D printer. Our method eliminates the need for a clean room by replacing the photolithography mold fabrication with a 3D-printing alternative. This is combined with soft lithography. With our fabrication method, one can make microfluidic chips with practically any features. </p>
 
+
<p>We chose to make a microfluidic platform that could transform <i>Escherichia coli</i> competent cells. Transformations are carried out daily in many labs, including iGEM projects. We wanted to make the process easier and more automated. During the course of the summer we developed a successful transformation chip. Countless heat-shock transformations were carried out on our microfluidic platform and this really proves that our fabrication method is easy and effective. </p>
                <h3 id="summary"> Project overview <small>What we are aiming for</small> </h3>
+
  
 +
<p>Our initial plan was to create a microfluidic platform for genome editing by means of the CRISPR/CPF1 system. We wanted to insert the gene for the newly discovered fluorescent protein UnaG. Therefore, we worked with these molecular tools parallel to our chip and we added both Cpf1 and UnaG to the registry. In the future our microfluidic chip could be used to carry out genome editing with CPF1 and insert UnaG to work as a marker. For now, we created the tools needed to work with the CRISPR/CPF1 system and UnaG but were not able to combine them on the chip.</p>
  
                 <p>
+
<p>We hope that our project has made microfluidics less intimidating and easier for iGEM teams and other small, low-budget labs. In the near future we hope that microfluidic chips are viewed as common laboratory tools rather than a field of research! </p>
 +
                 <!--OLD DESCRIPTION<p>
 
                     We are developing a method to make CRISPR and microfluidics more available to iGEM teams and researchers. The technique will be used to fuse a fluorescent protein called UnaG to a genomic protein in both prokaryotes and eukaryotes. We are including state of the art research involving the CRISPR associated protein CPF1 and microfluidic methods. </p>
 
                     We are developing a method to make CRISPR and microfluidics more available to iGEM teams and researchers. The technique will be used to fuse a fluorescent protein called UnaG to a genomic protein in both prokaryotes and eukaryotes. We are including state of the art research involving the CRISPR associated protein CPF1 and microfluidic methods. </p>
  
Line 33: Line 38:
 
                 <p> To facilitate the insertion of the genomic material we will design a microfluidic chip capable of transformation. This will be done through soft lithography by 3D printing a mold and baking a PDMS chip on it. A microfluidic chip will reduce the amount of reagents needed to perform a transformation, which could potentially reduce the cost and workload of a conventional transformation. The chip methods are not size-dependent, therefore it will be possible to do any given plasmid insertion with the same device. </p>
 
                 <p> To facilitate the insertion of the genomic material we will design a microfluidic chip capable of transformation. This will be done through soft lithography by 3D printing a mold and baking a PDMS chip on it. A microfluidic chip will reduce the amount of reagents needed to perform a transformation, which could potentially reduce the cost and workload of a conventional transformation. The chip methods are not size-dependent, therefore it will be possible to do any given plasmid insertion with the same device. </p>
  
                 <p> By using this chip, cell transformation becomes simpler and cheaper to do for other iGEM teams and small laboratories. In our project we will use it along with CRISPR to fuse UnaG with a genomic protein in yeast, but a microfluidic chip could potentially be used for any transformation technique. </p>
+
                 <p> By using this chip, cell transformation becomes simpler and cheaper to do for other iGEM teams and small laboratories. In our project we will use it along with CRISPR to fuse UnaG with a genomic protein in yeast, but a microfluidic chip could potentially be used for any transformation technique. </p>-->
  
  
Line 48: Line 53:
 
                 <div class="container">
 
                 <div class="container">
 
                     <div class="row">
 
                     <div class="row">
                        <div class="col-lg-offset-2">
 
 
                             <div class="col-lg-10">
 
                             <div class="col-lg-10">
  
Line 55: Line 59:
 
                                 </video>
 
                                 </video>
 
                             </div>
 
                             </div>
                        </div>
 
 
                     </div>
 
                     </div>
 
                 </div>
 
                 </div>

Latest revision as of 14:53, 18 October 2016

Summary

With our project we wanted to make microfluidic chips easier and more available for iGEM teams and other small labs. Microfluidic chips can and have been used to carry out many laboratory procedures in a micro-scale, effectively downscaling and streamlining laboratory work. The smaller volumes and workload have the potential to lower the cost of bench-top procedures and this is one of the larger advantages that microfluidics brings to research.

Fabrication methods for microfluidic chips have become faster and easier, making prototyping a rapid task. Despite the advances in fabrication methods the cost of making microfluidic chips is still high and the equipment needed is expensive. This can be exemplified by the fact that a clean room is needed for the regular photolithography/soft lithography method. We wanted to change this. That is why we created a 3D-printing based fabrication method that does not require expensive specialized equipment. A mold for the chip can be 3D printed once and therefore the lab does not need its own 3D printer. Our method eliminates the need for a clean room by replacing the photolithography mold fabrication with a 3D-printing alternative. This is combined with soft lithography. With our fabrication method, one can make microfluidic chips with practically any features.

We chose to make a microfluidic platform that could transform Escherichia coli competent cells. Transformations are carried out daily in many labs, including iGEM projects. We wanted to make the process easier and more automated. During the course of the summer we developed a successful transformation chip. Countless heat-shock transformations were carried out on our microfluidic platform and this really proves that our fabrication method is easy and effective.

Our initial plan was to create a microfluidic platform for genome editing by means of the CRISPR/CPF1 system. We wanted to insert the gene for the newly discovered fluorescent protein UnaG. Therefore, we worked with these molecular tools parallel to our chip and we added both Cpf1 and UnaG to the registry. In the future our microfluidic chip could be used to carry out genome editing with CPF1 and insert UnaG to work as a marker. For now, we created the tools needed to work with the CRISPR/CPF1 system and UnaG but were not able to combine them on the chip.

We hope that our project has made microfluidics less intimidating and easier for iGEM teams and other small, low-budget labs. In the near future we hope that microfluidic chips are viewed as common laboratory tools rather than a field of research!

Project origins

The Uppsala team was started up in January with introductory meetings and brainstorming of project ideas. The iGEM Uppsala association recruited two project leaders from earlier iGEM Uppsala teams. These project leaders were then in charge of recruiting and leading the team itself. Anyone interested in iGEM were welcome to the introductory meeting and to help with the brainstorming. The potential projects were researched further to decide on the viability of each idea as an iGEM project. Researchers and university staff that have been involved in the iGEM Uppsala project earlier years were invited to give input on the ideas. With their feedback and questions in mind, further research was done.

Day of Decision

The 7th of April was decided as the day of Decision, when we would irrefutably chose a project . During the weeks before Decision day, projects with low interest were abandoned to allow more research on other potential ideas. As the day of Decision was upon us, only four projects remained. The team decided to choose project by majority decision, where the chosen project has to have more than 50% of the votes. Only team members voted in a closed poll, and as the project leaders held the selection process they decided to exclude themselves from the decision. After the first round, two of the project ideas differed by only one vote. The other two projects received one and no votes respectively. These two were removed from the next round of voting. The votes were read up one by one, which led to much excitement. The projects took turns of being in the lead, but when all votes had been read, one project was chosen with nine votes against seven. This project, CRISPR on a Chip, was what would fill our days and dreams the following months. Obviously the decision was celebrated by the team going out together for dinner at one of Uppsalas student pubs.

The months leading up to the summer

With only one project to focus on, the research picked up a new pace. Taking a lesson from what was learnt by last years team, the first round of gene synthesis was planned for the middle of May. This would hopefully allow us to have what we need when we received access to a lab. Having 18 students in the team required good organization and smaller working groups. With this in mind, three lab groups were put together by mixing biology, biotechnology and chemistry students in each group. Further research were done in these lab groups, though research came to a halt right before lab start due to exams. At the 7th of June we stepped into the course lab that we were assigned, as the 6th of June is a national holiday in Sweden. While making buffers and preparing competent cells, a complete plan for the summer was set up.