Foam-like compression behavior of fibrin networks

Biomechanics and Modeling in Mechanobiology

Volumn 15, Issue 1, 2016, Pages 213-228

  Kim, Oleg V ^a   Liang, Xiaojun ^b   Litvinov, Rustem I ^c   Weisel, John W ^c   Alber, Mark S ^a,d   Purohit, Prashant K ^b  

^a UNIVERSITY OF NOTRE DAME   (United States)

^b UNIVERSITY OF PENNSYLVANIA   (United States)

^c UNIVERSITY OF PENNSYLVANIA   (United States)

^d INDIANA UNIVERSITY SCHOOL OF MEDICINE   (United States)

Author keywords

Compression; Fibrin networks; Foams; Non affine deformation; Phase transition

Indexed keywords

CONTINUUM MECHANICS; DEFORMATION; DIGITAL STORAGE;

COMPRESSION; COMPRESSION BEHAVIOURS; COMPRESSIVE BEHAVIOR; FIBRIN NETWORK; NON-AFFINE DEFORMATION; RHEOLOGICAL PROPERTY; SHEAR RESPONSE; STORAGE AND LOSS MODULUS; TENSILE RESPONSE; TWO PHASE;

FIBERS;

FIBRIN;

ARTICLE; COMPRESSION; FIBER; FOAM; PRIORITY JOURNAL; PROTEIN STRUCTURE; STRESS STRAIN RELATIONSHIP; VISCOELASTICITY; BIOMECHANICS; COMPRESSIVE STRENGTH; HUMAN; METABOLISM; NONLINEAR SYSTEM; YOUNG MODULUS;

BIOMECHANICAL PHENOMENA; COMPRESSIVE STRENGTH; ELASTIC MODULUS; FIBRIN; HUMANS; NONLINEAR DYNAMICS;

EID: 84959509068     PISSN: 16177959     EISSN: 16177940     Source Type: Journal    
DOI: 10.1007/s10237-015-0683-z     Document Type: Article

References (45)

1. Abeyaratne R, Knowles JK (2006) Evolution of phase transitions: a continuum theory. Cambridge University Press, New York
2. Ahmed TA, Dare EV, Hincke M (2008) Fibrin: a versatile scaffold for tissue engineering applications. Tissue Eng Part B: Rev 14(2):199–215
3. Arruda EM, Boyce MC (1993) A three-dimensional constitutive model for the large stretch behavior of rubber elastic materials. J Mech Phys Solids 41(2):389–412
4. Bouaziz O, Masse JP, Allain S, Orgas L, Latil P (2013) Compression of crumpled aluminum thin foils and comparison with other cellular materials. Mater Sci Eng: A 570:1–7
5. Broedersz CP, Sheinman M, MacKintosh FC (2012) Filament-length-controlled elasticity in 3D fiber networks. Phys Rev Lett 108(7):078102
6. Brown AE, Litvinov RI, Discher DE, Purohit PK, Weisel JW (2009) Multiscale mechanics of fibrin polymer: gel stretching with protein unfolding and loss of water. Science 325(5941):741–744
7. Chen J, Kim OV, Litvinov RI, Weisel JW, Alber MS, Chen DZ (2014) An automated approach for fibrin network segmentation and structure identification in 3D confocal microscopy images. 2014 IEEE 27th international symposium on the computer-based medical systems (CBMS), (pp. 173–178)
8. Choong LT, Mannarino MM, Basu S, Rutledge GC (2013) Compressibility of electrospun fiber mats. J Mater Sci 48(22):7827–7836
9. Collet JP, Shuman H, Ledger RE, Lee S, Weisel JW (2005) The elasticity of an individual fibrin fiber in a clot. Proc Natl Acad Sci USA 102(26):9133–9137
10. Falvo MR, Gorkun OV, Lord ST (2010) The molecular origins of the mechanical properties of fibrin. Biophys Chem 152(1):15–20
11. Ferry JD (1980) Viscoelastic properties of polymers. Wiley, Hoboken
12. Flory PJ (1953) Principles of polymer chemistry. Cornell University Press, Ithaca
13. Fung YC (1965) Foundations of solid mechanics. Prentice-Hall: Englewood Cliffs
14. Gaitanaros S, Kyriakides S, Kraynik AM (2012) On the crushing response of random open-cell foams. Int J Solids Struct 49(19):2733–2743
15. Gibson LJ, Ashby MF (1999) Cellular solids: structure and properties. Cambridge University Press, Cambridge
16. αC region is origin of low modulus, high extensibility, and strain stiffening in fibrin fibers. Biophys J 99(9):3038–3047
17. Howard J (2001) Mechanics of motor proteins and the cytoskeleton. Sinauer Associates: Sunderland
18. Hudson NE, Houser JR, O’Brien ET III, Taylor RM II, Superfine R, Lord ST, Falvo MR (2010) Stiffening of individual fibrin fibers equitably distributes strain and strengthens networks. Biophys J 98(8):1632–1640
19. Hudson NE, Ding F, Bucay I, OBrien ET III, Gorkun OV, Superfine R, Falvo MR (2013) Submillisecond elastic recoil reveals molecular origins of fibrin fiber mechanics. Biophys J 104(12):2671–2680
20. Hutchens SB, Needleman A, Greer JR (2011) Analysis of uniaxial compression of vertically aligned carbon nanotubes. J Mech Phys Solids 59(10):2227–2237
21. Jahnel M, Waigh TA, Lu JR (2008) Thermal fluctuations of fibrin fibres at short time scales. Soft Matter 4(7):1438–1442
22. Jang WY, Kyriakides S (2009) On the crushing of aluminum open-cell foams: part I. Experiments. Int J Solids Struct 46(3):617–634
23. Janmey PA, Euteneuer U, Traub P, Schliwa M (1991) Viscoelastic properties of vimentin compared with other filamentous biopolymer networks. J Cell Biol 113(1):155–160
24. Kang H, Wen Q, Janmey PA, Tang JX, Conti E, MacKintosh FC (2009) Nonlinear elasticity of stiff filament networks: strain stiffening, negative normal stress, and filament alignment in fibrin gels. J Phys Chem B 113(12):3799–3805
25. Kim OV, Xu Z, Rosen ED, Alber MS (2013) Fibrin networks regulate protein transport during thrombus development. PLoS Comput Biol 9(6):e1003095
26. Kim OV, Litvinov RI, Weisel JW, Alber MS (2014) Structural basis for the nonlinear mechanics of fibrin networks under compression. Biomaterials 35(25):6739–6749
27. Landau LD, Lifshitz EM, Pitaevskii LP (1984) Statistical Physics. Butterworth-Heinemann: Oxford
28. Litvinov RI, Faizullin DA, Zuev YF, Weisel JW (2012) The alpha-helix to beta-sheet transition in stretched and compressed hydrated fibrin clots. Biophys J 103(5):1020–1027
29. Liu WJLM, Jawerth LM, Sparks EA, Falvo M, Hantgan RR, Superfine R, Guthold M (2006) Fibrin fibers have extraordinary extensibility and elasticity. Science 313(5787):634–634
30. Masse JP, Poquillon D (2013) Mechanical behavior of entangled materials with or without cross-linked fibers. Scr Mater 68(1):39–43
31. Mezeix L, Bouvet C, Huez J, Poquillon D (2009) Mechanical behavior of entangled fibers and entangled cross-linked fibers during compression. J Mater Sci 44(14):3652–3661
32. Onck PR, Koeman T, Van Dillen T, Van der Giessen E (2005) Alternative explanation of stiffening in cross-linked semiflexible networks. Phys Rev Lett 95(17):178102
33. Piechocka IK, Bacabac RG, Potters M, MacKintosh FC, Koenderink GH (2010) Structural hierarchy governs fibrin gel mechanics. Biophys J 98(10):2281–2289
34. Purohit PK, Litvinov RI, Brown AE, Discher DE, Weisel JW (2011) Protein unfolding accounts for the unusual mechanical behavior of fibrin networks. Acta Biomater 7(6):2374–2383
35. Raj R, Purohit PK (2011) Phase boundaries as agents of structural change in macromolecules. J Mech Phys Solids 59(10):2044–2069
36. Ryan EA, Mockros LF, Weisel JW, Lorand L (1999) Structural origins of fibrin clot rheology. Biophys J 77(5):2813–2826
37. Shahsavari A, Picu RC (2012) Model selection for athermal cross-linked fiber networks. Phys Rev E 86(1):011923
38. Sharma RC, Papagiannopoulos A, Waigh TA (2008) Optical coherence tomography picorheology of biopolymer solutions. Appl Phys Lett 92(17):173903
39. Storm C, Pastore JJ, MacKintosh FC, Lubensky TC, Janmey PA (2005) Nonlinear elasticity in biological gels. Nature 435(7039):191–194
40. Toll S (1998) Packing mechanics of fiber reinforcements. Polym Eng Sci 38(8):1337–1350
41. Van Wyk CM (1946) Note on the compressibility of wool. J Text Inst Trans 37(12):T285–T292
42. Weisel JW (2004) The mechanical properties of fibrin for basic scientists and clinicians. Biophys chem 112(2):267–276
43. Weisel JW, Litvinov RI (2013) Mechanisms of fibrin polymerization and clinical implications. Blood 121(10):1712–1719
44. Wen Q, Basu A, Winer JP, Yodh A, Janmey PA (2007) Local and global deformations in a strain-stiffening fibrin gel. New J Phys 9(11):428
45. Yang Y, Bai M, Klug WS, Levine AJ, Valentine MT (2013) Microrheology of highly crosslinked microtubule networks is dominated by force-induced crosslinker unbinding. Soft Matter 9(2):383–393