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DOI: 10.1201/9781003336433-6
6
Forces
Methods that Measure and/or Manipulate
Biological Forces or Use Forces in
Their Principal Mode of Operation on
Biological Matter
What would happen if we could arrange the atoms one by one the way we want them?
—Richard Feynman, Physicist (1959)
General Idea: Several biophysical methods can both measure and manipulate biological forces
across a range of length and time scales. These include methods that characterize forces in
whole tissues, down through to single cells and to structures inside cells, right down to the
single-molecule level. The force fields that are generated to probe the biological forces originate
from various sources including hydrodynamic drag effects, solution pressure gradients, elec
trical attraction and repulsion, molecular forces, magnetism, optical forces, and mechanical
forces. All of which are explored in this chapter.
6.1 �INTRODUCTION
All experimental biophysical techniques clearly involve measurement and application of
forces in some form or another. However, there is a subset of methods that are designed
specifically to either measure the forces generated in biological systems, or to control and
manipulate them. Similarly, there are tools that do not characterize biological forces directly,
but which primarily utilize force methods in their mode of operation, for example, in using
pressure gradients to purify biomolecular components.
There now exist several methods that permit both highly controlled measurement and
manipulation of the forces experienced by single biomolecules. These various tools all come
under the banner of force transduction devices; they convert the mechanical molecular
forces into some form of amplified, measurable signal. Many of these single-molecule force
techniques share several common features, for example, single molecules are not in general
manipulated directly but are in effect physically conjugated, usually via one or more chemical
links, to some form of adapter that is the real force transduction element in the system. The
principal forces that are used to manipulate the relevant adapter include optical, magnetic,
electrical, and mechanical. These are all coupled into an environment of complex feedback
electronics and stable, noise-minimizing microscope stages, both for purposes of measure
ment and for manipulation.
Single-molecule biophysics methods extend beyond just force tools, which we explore
here, encompassing also a range of advanced imaging techniques that we explored previously