University of Arizona 2006

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*View under a microscope
*View under a microscope
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==Other Issues==
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==Placing the inducer(s)==
After the challenges of the first aspect of the project are overcome, more mechanical challenges still exist. For example: How to place the inducers?, or What scale should the image be?, or Are any optical techniques needed to fully visualize the image?
After the challenges of the first aspect of the project are overcome, more mechanical challenges still exist. For example: How to place the inducers?, or What scale should the image be?, or Are any optical techniques needed to fully visualize the image?
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===Rapid Prototyping Mold===
===Rapid Prototyping Mold===
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Digital images could be parsed into its three separate colors. The area were there is color is then cut into a block (not in actuality, it is RP'ed in one step). The block is then used to cast a PDMS mold that will be used as a stamp to place the inducers on the plate of cells.
===PDMS Mold===
===PDMS Mold===
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 +
Similar to the above idea, a PDMS mold with microfluidic channels is made so that a liquid (a solution of inducer) is able to be selectively placed on the plate of cells.
==Photos==
==Photos==
Team photo shown above, more to come.
Team photo shown above, more to come.

Revision as of 21:41, 27 September 2006

University of Arizona 2006

UA iGEM 2006.JPG

Contents

Team members

Member Contact Role
Joan Curry curry@ag.arizona.edu Faculty Advisor
Mark Riley riley@ag.arizona.edu Faculty Advisor
Patrick Hollinger dogmod@email.arizona.edu Lab Lead / Design
Josh Kittleson jkittles@email.arizona.edu Lab work, Design
Tim Spriggs tims@u.arizona.edu Project Manager / Documentation
Tyler Brown tylerb@email.arizona.edu Documentation
Dan Reavis danman1@email.arizona.edu
Kevin MacDow macdow@email.arizona.edu
Brian Heinze heinze@email.arizona.edu

Meetings

Lab Work: All week in morning, afternoon

Next Meeting: Mon 7/24 in Shantz 440 at 4:00 pm

Resources

Local Resources

  • [http://igem.engr.arizona.edu/phpBB2/ Team Forum]

Articles and References

Related Projects and Links


Projects

Our project ideas are still under development but for progress you may visit our Project Ideas.

We also maintain a forum for internal team communication. This is available at our [http://igem.engr.arizona.edu/phpBB2/ Team Forum].

The "Water Color" project (we don't have an official name yet) is the current project that we will be building. As of now, we will be focusing our attention on building this design. We want to start with a system that is not complex and that is straightforward to build. So that we can learn while we build. We want to add complexity later, after we have made what is already designed.

Project Details

The current name of our project is "Water Color." It is a system that selectively expresses one of three florescence proteins. Each of the three florescence proteins will be expressed in the presence of a unique inducer. Each florescent protein will be controlled by a unique repressed promoter.

The idea of our project is to have a media with these cells on it so that each cell will be individually activated to shown a certain "color" (in actuallity, express one florescent protein, which may or may not look unique). Thus the media is able to dispaly an image. A further idea, to be implemented later, is to have the ability to "erase" the image. This would be accomplished by repressing all three promoters.

All the requisite parts have been identified from the registry, and will be built together. (More detail on the specific part numbers and a diagram will be added later)

A flowchart of the parts construction is completed at Parts Schedule

We are currently in Phase III of the construction (much to our plesant surprise). This has not taken too long to reach this far, therefore, we will have time to add improvements to the design.

Visualization

One hurdle to overcome is how should we visualize the image. We know that two of the flourescent proteins look very similar by the naked eye, even though they produce light of different wavelengths. Ideas that we have to better visualize the image include:

  • Making three plates (each one color) for each image and digitally adding color
  • Use light filters to distinguish the proteins
  • View under a microscope

Placing the inducer(s)

After the challenges of the first aspect of the project are overcome, more mechanical challenges still exist. For example: How to place the inducers?, or What scale should the image be?, or Are any optical techniques needed to fully visualize the image?

Inkjet Printer

The first idea to place the inducers on the media is to use an injet printer. The printer could print solutions of inducers on a thin sheet which can be placed onto the media to put the inducers in contact with the cells. Issues that arrise are:

  • The size of molecules and the aperature of the jet
  • The fluid properties of the solution (e.g. viscosity) should match ink
  • The sheet needs to effectively transfer the solutions to the media without mixing of regions

Rapid Prototyping Mold

Digital images could be parsed into its three separate colors. The area were there is color is then cut into a block (not in actuality, it is RP'ed in one step). The block is then used to cast a PDMS mold that will be used as a stamp to place the inducers on the plate of cells.

PDMS Mold

Similar to the above idea, a PDMS mold with microfluidic channels is made so that a liquid (a solution of inducer) is able to be selectively placed on the plate of cells.

Photos

Team photo shown above, more to come.

Personal tools
Past/present/future years