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Literature DB >> 20483337

Structural hierarchy governs fibrin gel mechanics.

Izabela K Piechocka¹, Rommel G Bacabac, Max Potters, Fred C Mackintosh, Gijsje H Koenderink.

Abstract

Fibrin gels are responsible for the mechanical strength of blood clots, which are among the most resilient protein materials in nature. Here we investigate the physical origin of this mechanical behavior by performing rheology measurements on reconstituted fibrin gels. We find that increasing levels of shear strain induce a succession of distinct elastic responses that reflect stretching processes on different length scales. We present a theoretical model that explains these observations in terms of the unique hierarchical architecture of the fibers. The fibers are bundles of semiflexible protofibrils that are loosely connected by flexible linker chains. This architecture makes the fibers 100-fold more flexible to bending than anticipated based on their large diameter. Moreover, in contrast with other biopolymers, fibrin fibers intrinsically stiffen when stretched. The resulting hierarchy of elastic regimes explains the incredible resilience of fibrin clots against large deformations. Copyright 2010 Biophysical Society. Published by Elsevier Inc. All rights reserved.

Entities: Disease

Mesh：

Substances：
Gels
Fibrin

Year: 2010 PMID： 20483337 PMCID： PMC2872216 DOI： 10.1016/j.bpj.2010.01.040

Source DB: PubMed Journal: Biophys J ISSN： 0006-3495 Impact factor: 4.033

53 in total

1. Force-Extension Relation and Plateau Modulus for Wormlike Chains.

Authors:
Journal: Phys Rev Lett Date: 1996-07-08 Impact factor: 9.161

2. Effect of microgravity, temperature, and concentration on fibrin and collagen assembly.

Authors: C R Nunes; M T Roedersheimer; S J Simske; M W Luttges
Journal: Microgravity Sci Technol Date: 1995-08 Impact factor: 1.982

3. Effects of calcium ion and covalent crosslinking on formation and elasticity of fibrin cells.

Authors: L L Shen; J Hermans; J McDonagh; R P McDonagh; M Carr
Journal: Thromb Res Date: 1975-03 Impact factor: 3.944

4. Functional analysis of fibrin {gamma}-chain cross-linking by activated factor XIII: determination of a cross-linking pattern that maximizes clot stiffness.

Authors: Kristina F Standeven; Angela M Carter; Peter J Grant; John W Weisel; Irina Chernysh; Leona Masova; Susan T Lord; Robert A S Ariëns
Journal: Blood Date: 2007-04-13 Impact factor: 22.113

5. Molecular basis of fibrin clot elasticity.

Authors: Bernard B C Lim; Eric H Lee; Marcos Sotomayor; Klaus Schulten
Journal: Structure Date: 2008-02-21 Impact factor: 5.006

6. Complexity of "A-a" knob-hole fibrin interaction revealed by atomic force spectroscopy.

Authors: Laurel E Averett; Carri B Geer; Ryan R Fuierer; Boris B Akhremitchev; Oleg V Gorkun; Mark H Schoenfisch
Journal: Langmuir Date: 2008-03-20 Impact factor: 3.882

7. Cross-linked networks of stiff filaments exhibit negative normal stress.

Authors: Enrico Conti; Fred C Mackintosh
Journal: Phys Rev Lett Date: 2009-02-26 Impact factor: 9.161

Review 8. Fibrin structure and wound healing.

Authors: N Laurens; P Koolwijk; M P M de Maat
Journal: J Thromb Haemost Date: 2006-05 Impact factor: 5.824

9. Concentration of protein in fibrin fibers and fibrinogen polymers determined by refractive index matching.

Authors: W A Voter; C Lucaveche; H P Erickson
Journal: Biopolymers Date: 1986-12 Impact factor: 2.505

10. Length of tandem repeats in fibrin's alphaC region correlates with fiber extensibility.

Authors: M R Falvo; D Millard; E T O'Brien; R Superfine; S T Lord
Journal: J Thromb Haemost Date: 2008-08-28 Impact factor: 5.824

67 in total

1. Spatiotemporal control of micromechanics and microstructure in acoustically-responsive scaffolds using acoustic droplet vaporization.

Authors: Mitra Aliabouzar; Christopher D Davidson; William Y Wang; Oliver D Kripfgans; Renny T Franceschi; Andrew J Putnam; J Brian Fowlkes; Brendon M Baker; Mario L Fabiilli
Journal: Soft Matter Date: 2020-07-22 Impact factor: 3.679

Structural hierarchy governs fibrin gel mechanics.

1. Force-Extension Relation and Plateau Modulus for Wormlike Chains.

2. Effect of microgravity, temperature, and concentration on fibrin and collagen assembly.

3. Effects of calcium ion and covalent crosslinking on formation and elasticity of fibrin cells.

4. Functional analysis of fibrin {gamma}-chain cross-linking by activated factor XIII: determination of a cross-linking pattern that maximizes clot stiffness.

5. Molecular basis of fibrin clot elasticity.

6. Complexity of "A-a" knob-hole fibrin interaction revealed by atomic force spectroscopy.

7. Cross-linked networks of stiff filaments exhibit negative normal stress.

Review 8. Fibrin structure and wound healing.

9. Concentration of protein in fibrin fibers and fibrinogen polymers determined by refractive index matching.

10. Length of tandem repeats in fibrin's alphaC region correlates with fiber extensibility.

1. Spatiotemporal control of micromechanics and microstructure in acoustically-responsive scaffolds using acoustic droplet vaporization.

2. Mechanism of fibrin(ogen) forced unfolding.

3. α-α Cross-links increase fibrin fiber elasticity and stiffness.

4. Evidence that αC region is origin of low modulus, high extensibility, and strain stiffening in fibrin fibers.

5. Submillisecond elastic recoil reveals molecular origins of fibrin fiber mechanics.

6. Adaptation of fibrous biopolymers to recurring increasing strains.

7. Cells actively stiffen fibrin networks by generating contractile stress.

8. Estimating the 3D pore size distribution of biopolymer networks from directionally biased data.

9. Microbuckling of fibrin provides a mechanism for cell mechanosensing.

10. Compression-induced structural and mechanical changes of fibrin-collagen composites.