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9. R. A. Freitas, Jr. Nanodentistry. The Journal of the American Dental Association, 131:
pp 1559-1566, Nov 2000; http://www.rfreitas.com/Nano/Nanodentistry.htm.
10. R. A. Freitas Jr. Pharmacytes: An ideal vehicle for targeted drug delivery. Journal
of Nanoscience and Nanotechnology, 6: pp 2769-2775, Sep-Oct 2006; http://www.
nanomedicine.com/Papers/JNNPharm06.pdf.
11. Nanofactory Collaboration website. Accessed Jan 2007. http://www.Molecular
Assembler.com/Nanofactory.
12. K. E. Drexler. Nanosystems: Molecular Machinery, Manufacturing, and Computation.
New York: Wiley, 1992; (a) Chapter 10, (b) Chapter 11, (c) 13.4, (d) Chapter 12,
(e) 16.3.2, (f) 12.4, (g) 6.7.2.
13. R. A. Freitas Jr. and R. C. Merkle. Kinematic Self-Replicating Machines. Georgetown,
TX: Landes Bioscience, 2004; http://www.molecularassembler.com/KSRM.htm.
14. K. Ishiyama, M. Sendoh, and K. I. Arai. Magnetic micromachines for medical appli-
cations. Journal of Magnetism and Magnetic Materials, 242-245: pp 1163-1165, 2002.
15. D. D. Chrusch, B. W. Podaima, and R. Gordon. Cytobots: intracellular robotic
micromanipulators. In: W. Kinsner, A. Sebak, editors. Conference Proceedings, 2002
IEEE Canadian Conference on Electrical and Computer Engineering. Winnipeg,
Canada: 2002.
16. J. B. Mathieu, S. Martel, L. Yahia, G. Soulez, and G. Beaudoin. MRI systems as a
mean of propulsion for a microdevice in blood vessels. Biomedical Materials and
Engineering, 15: pp 367, 2005.
17. K. B. Yesin, P. Exner, K. Vollmers, and B. J. Nelson. Biomedical micro-robotic
system. 8th International Conference on Medical Image Computing and Computer
Assisted Intervention (MICCAI 2005), Palm Springs, California, Oct 26-29, 2005;
www.miccai2005.org; p 819.
18. Micro-robots take off as ARC announces funding. Monash University, Oct 11, 2006;
http://www.monash.edu.au/news/newsline/story/1038.
19. Committee to Review the National Nanotechnology Initiative, National Materials
Advisory Board (NMAB), National Research Council (NRC). A Matter of Size:
Triennial Review of the National Nanotechnology Initiative. Washington DC: The
National Academies Press, 2006; http://www.nap.edu/catalog/11752.html#toc.
20. R. C. Merkle and R. A. Freitas Jr. Theoretical analysis of a carbon-carbon dimer
placement tool for diamond mechanosynthesis. Journal of Nanoscience and Nano-
technology, 3: pp 319-324, Aug 2003; http://www.rfreitas.com/Nano/JNNDimerTool.
pdf.
21. R. A. Freitas Jr., inventor. A simple tool for positional diamond mechanosynthesis, and
its method of manufacture. U.S. Provisional Patent Application No. 60/543,802, filed
Feb 11, 2004; U.S. Patent Pending, Feb 11, 2005; http://www.MolecularAssembler.com/
Papers/DMSToolbuildProvPat.htm.
22. J. Peng, R. A. Freitas Jr., R. C. Merkle, J. R. Von Ehr, J. N. Randall, and G. D.
Skidmore. Theoretical analysis of diamond mechanosynthesis. Part III. Positional C2
deposition on diamond C(110) surface using Si/Ge/Sn-based dimer placement tools.
Journal of Computational and Theoretical Nanoscience, 3: pp 28-41, Feb 2006; http://
www.MolecularAssembler.com/Papers/JCTNPengFeb06.pdf.
23. B. Temelso, C. D. Sherrill, R. C. Merkle, and R. A. Freitas Jr. High-level ab initio studies
of hydrogen abstraction from prototype hydrocarbon systems. Journal of Physical
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