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Individual Fibrin Fibers Distribute Strain Across A Network

April 20, 2010

A new study shows that when it comes to networks of protein fibers, individual fibers play a substantial role in effectively strengthening an entire network of fibers. The research, published by Cell Press in the April 20th issue of the Biophysical Journal, describes a mechanism that explains how individual fibrin fibers subjected to significant strain can respond by stiffening to resist stretch and helping to equitably distribute the strain load across the network.

Fibrin is a fibrous protein that assembles into a remarkably strong mesh-like network and forms the structural framework of a blood clot. Failure of a clot can have fatal consequences. For example, if a portion of the clot breaks away and is carried downstream by the flowing blood, it can cause a stroke or heart attack. Although previous research has characterized the mechanical properties and behavior of fibrin networks on a macroscopic level, much less is known about the behavior of individual fibrin fibers and the distribution of strain from one fiber to the next.

“We know that network strength is determined in part by the maximum strain individual fibers can withstand, so it is of particular interest to determine how the high strain and failure characteristics of single fibrin fibers affect the overall strength of the network,” says senior study author Dr. Michael R. Falvo from the Department of Physics and Astronomy at the University of North Carolina at Chapel Hill. “Further, determining how strain is shared among the constituent fiber segments in a network under imposed stress is crucial to understanding failure modes of networks and their strength.”

Dr. Falvo and colleagues used a combined fluorescence/atomic force microscope nanomanipulation system to stretch two dimensional fibrin networks to the point of failure while recording the strain of individual fibers. “Specifically, we observed that as fibers were stretched, they became stiffer than the surrounding fibers at lower strains; this allowed the more strained, stiffer fibers, to distribute the strain load to the less strained fibers and reduce strain concentrations,” explains Dr. Falvo. “So in effect, strain stiffening in the individual fibers acts to distribute strain equitably throughout the network and thereby strengthen it.”

The strain concentration reduction effect described in this study may be part of an important physiological mechanism to strengthen blood clots under high shear conditions in the blood stream. The authors note that along with this physiological insight, their findings bring about a better understanding of this remarkable strengthening mechanism and may help to guide new design strategies for engineered materials.

Researchers include Nathan E. Hudson, University of North Carolina at Chapel Hill, Chapel Hill, NC; John R. Houser, University of North Carolina at Chapel Hill, Chapel Hill, NC; E. Timothy O’Brien, University of North Carolina at Chapel Hill, Chapel Hill, NC; Russell M. Taylor Jr., University of North Carolina at Chapel Hill, Chapel Hill, NC; Richard Superfine, University of North Carolina at Chapel Hill, Chapel Hill, NC; Susan T. Lord, University of North Carolina at Chapel Hill, Chapel Hill, NC; and Michael R. Falvo, University of North Carolina at Chapel Hill, Chapel Hill, NC.

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