Fibrin fibers have extraordinary extensibility and elasticity
Science, 2006•science.org
Blood clots perform an essential mechanical task, yet the mechanical behavior of fibrin
fibers, which form the structural framework of a clot, is largely unknown. By using combined
atomic force‐fluorescence microscopy, we determined the elastic limit and extensibility of
individual fibers. Fibrin fibers can be strained 180%(2.8-fold extension) without sustaining
permanent lengthening, and they can be strained up to 525%(average 330%) before
rupturing. This is the largest extensibility observed for protein fibers. The data imply that …
fibers, which form the structural framework of a clot, is largely unknown. By using combined
atomic force‐fluorescence microscopy, we determined the elastic limit and extensibility of
individual fibers. Fibrin fibers can be strained 180%(2.8-fold extension) without sustaining
permanent lengthening, and they can be strained up to 525%(average 330%) before
rupturing. This is the largest extensibility observed for protein fibers. The data imply that …
Blood clots perform an essential mechanical task, yet the mechanical behavior of fibrin fibers, which form the structural framework of a clot, is largely unknown. By using combined atomic force‐fluorescence microscopy, we determined the elastic limit and extensibility of individual fibers. Fibrin fibers can be strained 180% (2.8-fold extension) without sustaining permanent lengthening, and they can be strained up to 525% (average 330%) before rupturing. This is the largest extensibility observed for protein fibers. The data imply that fibrin monomers must be able to undergo sizeable, reversible structural changes and that deformations in clots can be accommodated by individual fiber stretching.
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