Investigation and modification of molecular structures with the nanoManipulator

• Published in: Journal of molecular graphics & modelling Vol. 17; no. 3; pp. 187 - 197
• Main Authors: Guthold, M, Falvo, M, Matthews, W.G, Paulson, S, Mullin, J, Lord, S, Erie, D, Washburn, S, Superfine, R, Brooks, F.P, Taylor, R.M
• Format: Journal Article
• Language: English
• Published: United States Elsevier Inc 01.06.1999
• Subjects: Adenoviridae - ultrastructure; adenovirus; atomic force microscope; carbon nanotubes; Computer Graphics; DNA; DNA - chemistry; fibrin; Fibrin - chemistry; friction; haptic; Image Processing, Computer-Assisted; mechanical properties; Microscopy, Atomic Force - methods; Models, Molecular; Models, Structural; nanoManipulator; rupture; tobacco mosaic virus; Tobacco Mosaic Virus - ultrastructure; User-Computer Interface; computer graphics; tobacco mosaic virus; haptic; carbon nanotubes; DNA; adenovirus; atomic force microscope; fibrin; friction; mechanical properties; nanoManipulator; rupture
• ISSN: 1093-3263; 1873-4243
• DOI: 10.1016/S1093-3263(99)00030-3

The nanoManipulator system adds a virtual reality interface to an atomic force microscope (AFM), thus providing a tool that enables the user not only to image but also to manipulate nanometer-sized molecular structures. As the AFM tip scans the surface of these structures, the tip–sample interaction forces are monitored, which in turn provide information about the frictional, mechanical, and topological properties of the sample. Computer graphics are used to reconstruct the surface for the user, with color or contours overlaid to indicate additional data sets. Moreover, by means of a force-feedback pen, which is connected to the scanning tip via software, the user can touch the surface under investigation to feel it and to manipulate objects on it. This system has been used to investigate carbon nanotubes, fibrin, DNA, adenovirus, and tobacco mosaic virus. Nanotubes have been bent, translated, and rotated to understand their mechanical properties and to investigate friction on the molecular level. AFM lithography is being combined with the nanoManipulator to investigate the electromechanical properties of carbon nanotubes. The rupture forces of fibrin and DNA have been measured. This article discusses how some of the graphics and interface features of the nanoManipulator made these novel investigations possible. Visitors have used the system to examine chromosomes, bacterial pili fibers, and nanochain aggregates (NCAs). Investigators are invited to apply to use the system as described on the web at http://www.cs.unc.edu/Research/nano/doc/biovisit.html.