Sortostat

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Revision as of 16:11, 12 November 2005 by Jason R. Kelly (Talk | contribs)
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Contents

Purpose

A microfluidic chemostat integrated with a cell sorter, which we call a "sort-o-stat", will enable more complicated selections to be applied to a population of cells in continuous culture. In particular, time varying selective pressures as well as very specific selection strengths can be applied. We will evaluate whether or not these more sophisticated selective pressures will be of practical use in service of evolving engineered biological systems. Selection can be based on any characteristic that can be reliably measured via microscopy. Lastly, since this is a physical selection (rather than a chemical one), it may be more difficult for cells to find unexpected methods to evade selection.


Design

Optimal sorting cutoffs

Sortostat:Chip schematic

Protocols

Setting up a new chip

Operate Microfluidic Chemostat

Microfluidic chemostat labview program

Known Issues

This section describes common failure points to help in debugging.

  1. Apply too high of a dilution rate too quickly
    • usually a good idea to grow the cells with a very low dilution rate (e.g. D=0.05) for ~10hrs in order to ensure that the cells are growing well and that there are no problems with the chip. If the cells grow well then you can increase the dilution rate.
  2. Cells escaping from the sorting chamber
    • This can happen as a result of closing both the CW and CCW valves, resulting in a pressure build up in the chambers between push-UP valves. It is not clear how pervasive a problem this is, but I have made changes to the Microfluidic chemostat labview program to close the CW and CCW sequentially to help the problem.
  3. Cells stop producing fluorescent proteins

Experimental Results

SortoStat experiments

Researchers

Jason Kelly, Josh Michener

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