Force microscopy imaging of individual protein molecules with sub‐pico Newton force sensitivity

Citations Over TimeTop 10% of 2007 papers

Abstract

The capability of atomic force microscopes (AFM) to generate atomic or nanoscale resolution images of surfaces has deeply transformed the study of materials. However, high resolution imaging of biological systems has proved more difficult than obtaining atomic resolution images of crystalline surfaces. In many cases, the forces exerted by the tip on the molecules (1-10 nN) either displace them laterally or break the noncovalent bonds that hold the biomolecules together. Here, we apply a force microscope concept based on the simultaneous excitation of the first two flexural modes of the cantilever. The coupling of the modes generated by the tip-molecule forces enables imaging under the application of forces ( approximately 35 pN) which are smaller than those needed to break noncovalent bonds. With this instrument we have resolved the intramolecular structure of antibodies in monomer and pentameric forms. Furthermore, the instrument has a force sensitivity of 0.2 pN which enables the identification of compositional changes along the protein fragments.

Related Papers

• → Atomic force microscopy: A forceful way with single molecules(1999)98 cited
• → Susceptibility of atomic force microscope cantilevers to lateral forces(2003)78 cited
• → Susceptibility of atomic force microscope cantilevers to lateral forces: Experimental verification(2003)34 cited
• → MODEL OF THE CANTILEVER USED AS A WEAK FORCE SENSOR IN ATOMIC FORCE MICROSCOPY(2005)3 cited
• Application of image alignment and time averaging methods in AFM detection for single DNA molecules(2010)