Template:ETHZ Basel10 Teaser

From 2010.igem.org

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Revision as of 15:00, 26 October 2010

Motivation & Project Idea

E. lemming is the 2010 iGEM project of ETH Zurich. We intend to control movement of a single E. coli bacterium by hijacking chemotaxis. Position and direction of the bacterium is monitored by image processing algorithms, which are linked to a controller device. Find out more about our motivation and project idea!

E. lemming - The Movie

Watch a short animation of the project idea!

We created a short animation about the project idea and general concept of E. lemming. Find out, how we combine biology and information processing to create E. lemming.

Biology & Wet Laboratory

How is it implemented?

By coupling proteins of the chemotaxis pathway to a light-sensitive spatial localization system, the chemotaxis activity can be controlled reversibly. To find out more about our project on the molecular level biological implementation visit this section.

Mathematical Modeling

How does modeling help?

Mathematical modeling supports analysis of biological systems since the advent of synthetic biology. Find out, how this supported wet laboratory experiments by providing time and effort alleviating network structure and experimental design selection. The combined model was a perfect test bench for information processing.

Information Processing

How is it controlled?

Implementation of a comprehensive information processing workflow for controlling E. lemming was achieved by combination of microscopy, image processing, cell detection and a controller. Find out more about how this not only created E. lemming, but also created a new application for synthetic biology: Gaming!

Achievements

What was achieved?

In addition to the main goal of E. lemming

Find out what we achieved! We created for E. lemming a BioBrick and a Matlab Toolkit, which can be used for similar projects. Learn more about our comprehensive systems design and systems implementation approaches, which were necessary for the success of E. lemming.

Team

Who is behind E. lemming?

Find out who created E. lemming and learn about the different backgrounds of the people who tried to achieve these common goals: Having a great experience and going crazy with E. lemming!

Motivation & Project Idea
What is E. lemming?
E. lemming - The Movie
Watch a short animation!
Biology & Wet Laboratory
How is it implemented?
Mathematical Modeling
How does modeling help?
Information Processing
How is it controlled?
Achievements
What was achieved?
Team
Who is behind E. lemming?

@@ Line 177: / Line 177: @@
 							<small>How is it implemented?</small>
-							<p>By coupling proteins of the chemotaxis pathway to a light-sensitive spatial localization system, the chemotactic activity can be controlled reversibly. To find out more about our project on the molecular level biological implementation visit this section.</p>
+							<p>By coupling proteins of the chemotaxis pathway to a light-sensitive spatial localization system, the chemotaxis activity can be controlled reversibly. To find out more about our project on the molecular level biological implementation visit this section.</p>
 					</div>
 				</div>
@@ Line 190: / Line 190: @@
 							<small>How does modeling help?</small>
-							<p>Mathematical modeling supports analysis of biological systems since the advent of synthetic biology. Find out, how this not only supported wet laboratory experiments by providing time and effort alleviating network structure and experimental design selection, but also provided a test bench for the information processing part.</p>
+							<p>Mathematical modeling supports analysis of biological systems since the advent of synthetic biology. Find out, how this supported wet laboratory experiments by providing time and effort alleviating network structure and experimental design selection. The combined model was a perfect test bench for information processing.</p>
 					</div>
 				</div>
@@ Line 203: / Line 203: @@
 							<small>How is it controlled?</small>
-							<p>Implementation of a comprehensive information processing workflow for controlling E. lemming was achieved by combination of microscopy, image processing, cell detection and a controller. Find out more about how this not only created E. lemming but also created a new application for synthetic biology: Gaming!</p>
+							<p>Implementation of a comprehensive information processing workflow for controlling E. lemming was achieved by combination of microscopy, image processing, cell detection and a controller. Find out more about how this not only created E. lemming, but also created a new application for synthetic biology: Gaming!</p>
 					</div>
 				</div>
@@ Line 215: / Line 215: @@
 							<h2>Achievements</h2>
 							<small>What was achieved?</small>
+							<p>In addition to the main goal of E. lemming</p>
-							<p>We created for E. lemming a BioBrick and a Matlab Toolkit. Find out, how this tools can be used for similar projects and learn more about our comprehensive systems design and systems implementation approaches, which were necessary for the success of E. lemming.</p>
+							<p>Find out what we achieved! We created for E. lemming a BioBrick and a Matlab Toolkit, which can be used for similar projects. Learn more about our comprehensive systems design and systems implementation approaches, which were necessary for the success of E. lemming.</p>
 					</div>
 				</div>
@@ Line 229: / Line 229: @@
 							<small>Who is behind E. lemming?</small>
-							<p>Find out who created E. lemming and learn about the different backgrounds of the people who tried to achieve one common goal: Having a great experience and going crazy with E. lemming!</p>
+							<p>Find out who created E. lemming and learn about the different backgrounds of the people who tried to achieve these common goals: Having a great experience and going crazy with E. lemming!</p>
 					</div>
 				</div>