Biomod/2012/UT/Nanowranglers/References

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# Barish, R. D., Rothemund, P. W. K., & Winfree, E. (2005). Two computational primitives for algorithmic self-assembly: copying and counting. Nano letters, 5(12), 2586–92. doi:10.1021/nl052038l
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# Barish, R. D., Rothemund, P. W. K. & Winfree, E. Two computational primitives for algorithmic self-assembly: copying and counting. Nano letters 5, 2586–92 (2005).
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# Bath, J., Green, S. J., & Turberfield, A. J. (2005). A Free-Running DNA Motor Powered by a Nicking Enzyme. Angewandte Chemie, 117(28), 4432–4435. doi:10.1002/ange.200501262
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# Bath, J., Green, S. J., Allen, K. E. & Turberfield, A. J. Mechanism for a directional, processive, and reversible DNA motor. Small (Weinheim an der Bergstrasse, Germany) 5, 1513–6 (2009).
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# Birac, J. J., Sherman, W. B., Kopatsch, J., Constantinou, P. E. & Seeman, N. C. Architecture with GIDEON, a program for design in structural DNA nanotechnology. Journal of molecular graphics & modelling 25, 470–80 (2006).
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Revision as of 13:00, 22 October 2012


Undergraduate DNA nanotechnology research group from the University of Texas at Austin



References

Note to NanoWranglers - to cite any of the below references, please say [Cite NAME, YEAR]. 
Note to Ben - Before wiki freeze, replace all [Cite NAME, YEAR] with their appropriate numbers and delete
all uncited sources.
  1. Barish, R. D., Rothemund, P. W. K. & Winfree, E. Two computational primitives for algorithmic self-assembly: copying and counting. Nano letters 5, 2586–92 (2005).
  2. Bath, J., Green, S. J. & Turberfield, A. J. A Free-Running DNA Motor Powered by a Nicking Enzyme. Angewandte Chemie 117, 4432–4435 (2005).
  3. Bath, J., Green, S. J., Allen, K. E. & Turberfield, A. J. Mechanism for a directional, processive, and reversible DNA motor. Small (Weinheim an der Bergstrasse, Germany) 5, 1513–6 (2009).
  4. Birac, J. J., Sherman, W. B., Kopatsch, J., Constantinou, P. E. & Seeman, N. C. Architecture with GIDEON, a program for design in structural DNA nanotechnology. Journal of molecular graphics & modelling 25, 470–80 (2006).
  5. Block, S., Blair, D. & Berg, H. Compliance of bacterial flagella measured with optical tweezers. Nature 338, 514 (1989).
  6. Brun, Y. Solving NP-complete problems in the tile assembly model. Theoretical Computer Science 395, 31–46 (2008).
  7. Carter, A. et al. Structure and Functional Role of Dynein’s Microtubule-Binding Domain. Science 322, 1691–1695 (2008).
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