Sullan, Ruby May Arana
[UCL]
Churnside, Allison B.
[University of Colorado]
Nguyen, Duc M.
[University of Colorado]
Bull, Matthew S.
[University of Colorado]
Perkins, Thomas T.
[University of Colorado]
Atomic force microscopy (AFM) is widely used in the biological sciences. Despite 25. years of technical developments, two popular modes of bioAFM, imaging and single molecule force spectroscopy, remain hindered by relatively poor force precision and stability. Recently, we achieved both sub-pN force precision and stability under biologically useful conditions (in liquid at room temperature). Importantly, this sub-pN level of performance is routinely accessible using a commercial cantilever on a commercial instrument. The two critical results are that (. i) force precision and stability were limited by the gold coating on the cantilevers, and (. ii) smaller yet stiffer cantilevers did not lead to better force precision on time scales longer than 25. ms. These new findings complement our previous work that addressed tip-sample stability. In this review, we detail the methods needed to achieve this sub-pN force stability and demonstrate improvements in force spectroscopy and imaging when using uncoated cantilevers. With this improved cantilever performance, the widespread use of nonspecific biomolecular attachments becomes a limiting factor in high-precision studies. Thus, we conclude by briefly reviewing site-specific covalent-immobilization protocols for linking a biomolecule to the substrate and to the AFM tip. © 2013.
Bibliographic reference |
Sullan, Ruby May Arana ; Churnside, Allison B. ; Nguyen, Duc M. ; Bull, Matthew S. ; Perkins, Thomas T.. Atomic force microscopy with sub-picoNewton force stability for biological applications. In: Methods, Vol. 60, no. 2, p. 131-141 (2013) |
Permanent URL |
http://hdl.handle.net/2078.1/160668 |