Difference between revisions of "Microoxen: Microorganisms to Move Microscale Loads."

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algae, phototaxis, photochemistry, beast of burden
 
algae, phototaxis, photochemistry, beast of burden
  
[[Image:Weibel-1.jpg|250px|thumb|right|Figure 1.  asdfsdf]]
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[[Image:Weibel-1.jpg|250px|thumb|right|Figure 1.  Transport system used in this experiment.  (A) Power (1-7) and recovery (8-11) strokes of algae.  (B)  Structure of the peptide used to attach beads to cells.  (C)  Reaction used to produce peptide-coated beads.  (D) Micrograph of bead attached to algae cell.  The bead is attached to the cell slightly above the current focal plane and so appears slightly out of focus.]]
[[Image:Weibel-2.jpg|250px|thumb|right|Figure 2.  asdfsdf]]
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[[Image:Weibel-2.jpg|250px|thumb|right|Figure 2.  (A)&(B) Schematics of LED/microfluidic channels used to steer the algae.  (C) Image of bead attached to algae cell.  (D)-(O) Series of frames showing a cell carrying a bead being steered back and forth in the microfluidic channel using positive phototaxis (cell is attracted to the LED that is on).]]
[[Image:Weibel-3.jpg|250px|thumb|right|Figure 3.  asdfsdf]]
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[[Image:Weibel-3.jpg|250px|thumb|right|Figure 3.  (A) Photo reaction that will cleave beads from algae cells.  (B)-(M) Time series showing release of a bead from a cell carrying two beads.  The cell was illuminated with UV light for 20 seconds before frame (B) and the time between frames is 2 seconds.]]
  
 
== Summary ==
 
== Summary ==

Revision as of 12:42, 22 April 2009

"Microoxen: Microorganisms to Move Microscale Loads"
Douglas B. Weibel, Piotr Garstecki, Declan Ryan, Willow R. DiLuzio, Michael Mayer, Jennifer E. Seto, & George M. Whitesides
PNAS 102(34) 11963-11967 (2005)


Soft Matter Keywords

algae, phototaxis, photochemistry, beast of burden

Figure 1. Transport system used in this experiment. (A) Power (1-7) and recovery (8-11) strokes of algae. (B) Structure of the peptide used to attach beads to cells. (C) Reaction used to produce peptide-coated beads. (D) Micrograph of bead attached to algae cell. The bead is attached to the cell slightly above the current focal plane and so appears slightly out of focus.
Figure 2. (A)&(B) Schematics of LED/microfluidic channels used to steer the algae. (C) Image of bead attached to algae cell. (D)-(O) Series of frames showing a cell carrying a bead being steered back and forth in the microfluidic channel using positive phototaxis (cell is attracted to the LED that is on).
Figure 3. (A) Photo reaction that will cleave beads from algae cells. (B)-(M) Time series showing release of a bead from a cell carrying two beads. The cell was illuminated with UV light for 20 seconds before frame (B) and the time between frames is 2 seconds.

Summary

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Practical Application of Research

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Moving Loads with Tiny Oxen

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written by Donald Aubrecht