208 6.2 Rheology and Hydrodynamics Tools
length scales of a few tens of microns, and different channels can be connected to generate a
complex flow-based device. These systems are discussed fully in Chapter 7.
6.2.3 �TOOLS THAT UTILIZE OSMOTIC FORCES
Dialysis, or ultrafiltration, has similar operating principles to chromatography in that the
sample mobility is characterized by similar factors, but the solvated sample is on one side of a
dialysis membrane that has a predefined pore size. This sets an upper molecular weight limit
for whether molecules can diffuse across the membrane.
This selectively permeable membrane (also referred to as a semipermeable mem
brane) results in an osmotic force driven by entropy. On either side of the membrane,
there is a concentration gradient, that is, the concentration of solvated molecules on
one side of the membrane is different from that on the other side. The water molecules
in the solution that has a higher concentration have more overall order since there are
a greater relative number of available solute molecules to which they bond, usually
via electrostatic and/or hydrogen bonding. This entropy difference between the two
solutions either side of the membrane is manifested as a statistical/entropic driving
force when averaged over time scales are much larger than the individual water mol
ecule collision time, which acts in a direction to force a net flux of water molecules
from the low-to high-concentration solutions (note that this is also the physical basis of
Raoult’s law, which states that the partial vapor pressure of each component of an ideal
mixture of liquids is equal to the vapor pressure of the pure component multiplied by
its mole fraction in that mixture; in other words, the components act independently of
each other). This process can be used to separate different populations of biomolecules
of the basis of molecular weight, often facilitated by a pressure gradient. The use of mul
tiple dialysis stages using membranes with different pore sizes can be used to purify a
complex mix of different molecules.
Osmotic pressure can also be used in the study of live cells. Lipid membranes of cells and
subcellular cell organelles are selectively permeable. Although some ions undergo passage
diffusion through pores in the membrane, in general the passage of water, ions, and various
biomolecules is highly selective and often tightly regulated. Enclosure of solutes inside a cell
membrane, therefore, results in a strong osmotic pressure on cells, exerted from the inside of
the cell onto the membrane toward the outside.
As discussed previously (see Chapter 2), there are various mechanisms to prevent cells
from exploding due to this osmotic pressure depending on the cell type, for example, cell
walls in bacteria and plant cells, and/or regulation of ion and water pumps that are especially
important in eukaryotic cells that in general have no stiff cell wall barrier. These mechanisms
can be explored in an osmotic chamber. This is a device that allows cells to be visualized using
light microscopy in their normal aqueous environment but allowing the external pressure
exerted through the liquid environment to be carefully controlled, up to pressures or sev
eral tens of atmospheres. Combining cellular pressure control with fluorescence micros
copy to probe cell wall proteins and ion channel components has proved informative in our
understanding of cellular osmoregulatory mechanisms.
6.2.4 �DEFORMING BIOLOGICAL MATTER WITH FLOW
The scientific study of flow and deformation of matter is known as rheology. It addresses
the interesting observation that all ultimately matter “flows” and deforms under mechanical
stress, but the time scales over which this occurs, and how the matter responds after the
driving force is removed, varies widely across different materials, and this can tell us a great
deal about the underpinning physical properties of that material which are often more com
plex than just considering how single molecules behave, but rather how molecules behave
when they cooperate together in a so-called emergent way. This is particularly true for the soft
matter that makes up biological systems, which can have highly diverse rheological properties,