Nanobiomechanics
It seems pretty obvious that diseased cells are going to differ in various ways from diseased ones. We tend to think of peering through a microscope to spot the difference between health and disease.
Medical researchers have long known that diseases can cause -- or be
caused by -- physical changes in individual cells. For instance,
invading parasites can distort or degrade blood cells, and heart
failure can occur as muscle cells lose their ability to contract in the
wake of a heart attack.
Research at MIT is looking at mechanical effects at the cell interface to get physical about this.
Knowing the effect of forces as small as a piconewton -- a trillionth of a newton -- on a cell seems to give researchers a much finer view of the ways in which diseased cells differ from healthy ones.
Subra Suresh has spent much of his career making nanoscale measurements of materials such as the thin films used in microelectronic components. But since 2003, Suresh's laboratory has spent more and more time applying nanomeasurement techniques to living cells.
One of Suresh's recent studies measured mechanical differences between healthy red blood cells and cells infected with malaria parasites. Suresh and his collaborators knew that infected blood cells become more rigid, losing the ability to reduce their width from eight micrometers down to two or three micrometers, which they need to do to slip through capillaries.
Rigid cells, on the other hand, can clog capillaries and cause cerebral hemorrhages. Though others had tried to determine exactly how rigid malarial cells become, Suresh's instruments were able to bring greater accuracy to the measurements.
Using optical tweezers, which employ intensely focused laser light to exert a tiny force on objects attached to cells, Suresh and his collaborators showed that red blood cells infected with malaria become 10 times stiffer than healthy cells -- three to four times stiffer than was previously estimated.
Eduard Arzt, director of materials research at the Max Planck Institute in Stuttgart, Germany, says that Suresh's work is important because cell flexibility is a vital characteristic not only of malarial cells but also of metastasizing cancer cells. "Many of the mechanical concepts we've been using for a long time, like strength and elasticity, are also very important in biology," says Arzt.
Based on news from MIT
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