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Experimental Mechanics
Erschienen in: Experimental Mechanics 4/2014

01.04.2014

Experimental Methods for Determining Residual Stresses and Strains in Various Biological Structures

verfasst von: D. Nelson

Erschienen in: Experimental Mechanics | Ausgabe 4/2014

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Abstract

Over the years, an assortment of methods for determining residual stresses has been developed in the field of experimental mechanics. Adaptations of those methods to study residual strains and stresses in various biological structures found in humans, other mammals, viruses and an insect are reviewed. Methods considered include deflections from release of residual stresses, hole drilling and ring coring, strains upon dissection, the contour method, slitting (crack compliance), X-ray diffraction, photoelasticity, and membrane and shell displacements. Sources of residual stresses and strains are summarized and examples of their physiological role noted.
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Literatur
1.
Taber L (1995) Biomechanics of growth, remodeling and morphogenesis. Appl Mech Rev 48(8):487–545
2.
Taber L (2001) Biomechanics of cardiovascular development. Annu Rev Biomed Eng 3:1–2
3.
Rodriguez E, Hoger A, McCulloch A (1994) Stress-dependent finite growth in soft elastic tissues. J Biomech 27:455–467
4.
Skalak R, Zargaryan S, Jain R, Netti P, Hoger A (1996) Compatibility and the genesis of residual stress by volumetric growth. J Math Biol 34:889–914MATH
5.
Vandiver R, Goriely A (2009) Differential growth and residual stress in cylindrical elastic structures. Phil Trans R Soc A 367:3607–3630MATHMathSciNet
6.
Olsson T, Klarbring A (2008) Residual stresses in soft tissue as a consequence of growth and remodeling: an application to an arterial geometry. Eur J Mech A-Solid 27:959–974MATHMathSciNet
7.
Wells S, Walter E (2010) Changes in the mechanical properties and residual strain of elastic tissue in the developing fetal aorta. Ann Biomed Eng 38:345–356
8.
Ambrosi D, Guillou A, DiMartino E (2008) Stress-modulated remodeling of a non-homogeneous body. Biomech Model Mechanobiol 7:63–76
9.
Yeni Y, Schaffler M, Gibson G, Fyhrie D (2002) Prestress due to dimensional changes caused by demineralization: a potential mechanisms for microcracking in bone. Ann Biomed Eng 30:217–225
10.
Volokh K, Lev Y (2005) Growth, anisotropy and residual stresses in arteries. Mech Chem Biosyst 2:27–40
11.
Karsaj I, Humphrey J (2012) A multilayered wall model of arterial growth and remodeling. Mech Mater 44:110–119
12.
Rachev A (1997) Theoretical study of the effect of stress-dependent remodeling on arterial geometry under hypertensive conditions. J Biomech 30:819–827
13.
Taber L, Humphrey J (2001) Stress-modulated growth, residual stress and heterogeneity. J Biomech Eng 123:528–535
14.
Archer R (1987) Growth stresses and strains in trees. Springer, Berlin
15.
Cardamone L, Valentin A, Eberth J, Humphrey J (2009) Origin of axial prestretch and residual stress in arteries. Biomech Model Mechanobiol 8:431–446
16.
Araujo R, McElwain D (2005) A mixture theory for the genesis of residual stresses in growing tissues I: a general formulation. SIAM J Appl Math 65:1261–1284MATHMathSciNet
17.
Ateshian G, Ricken T (2010) Multigenerational interstitial growth of biological tissues. Biomech Model Mechanobiol 9:689–702
18.
Lanir Y (2012) Osmotic swelling and residual stress in cardiovascular tissues. J Biomech 45:780–789
19.
Azeloglu E, Albro M, Thimmappa V, Ateshian G, Cosat K (2007) Heterogeneous transmural proteoglycan distribution provides a mechanism for regulating residual stresses in the aorta. Am J Physiol Heart Circ Physiol 294:H1197–H1205
20.
Cowin S (2004) Tissue growth and remodeling. Ann Rev Biomed Eng 6:77–107
21.
Carter D, Beaupre G (2001) Skeletal function and form. Cambridge University Press, Cambridge
22.
Currey J (2002) Bones. Princeton University Press, Princeton
23.
Taber L, Eggers D (1996) Theoretical study of stress-modulated growth in the aorta. J Theor Biol 180:343–357
24.
Ambrosi D, Ateshian G, Arruda E, Cowin S, Dumais J, Goriely A, Holzapfel G, Humphrey J, Kemkemer R, Kuhl E, Olberding J, Taber L, Garikipati K (2011) Perspectives on biological growth and remodeling. J Mech Phys Solids 59:863–883MATHMathSciNet
25.
Gonzalez-Torres L, Gomez-Benito M, Garcia-Aznar J (2011) Evaluation of residual stresses due to bone callus growth: a computational study. J Biomech 44:1782–1787
26.
Taber L, Hu N, Pexeider T, Clark E, Keller B (1993) Residual strain in the ventricle of the stage 16-24 chick embryo. Circ Res 72:455–462
27.
Henderson CD (2002) Mechanical induction in limb morphogenesis: the role of growth-generated strains and pressures. Bone 11:645–653
28.
Fung Y (1991) What are the residual stresses doing in our blood vessels? Ann Biomed Eng 19:237–249MathSciNet
29.
Rachev A, Greenwald S (2003) Residual strains in conduit arteries. J Biomech 36:661–670
30.
Destrade M, Liu Y, Murphy J, Kassab G (2012) Uniform transmural strain in pre-stresses arteries occurs at physiological pressure. J Theor Biol 303:93–97MathSciNet
31.
Delfino A, Stergiopulos N, Moore J, Meister J (1997) Residual strain effects on the stress field in a thick wall finite element model of the human carotid bifurcation. J Biomech 30:777–786
32.
Volokh K (2008) Prediction of arterial failure based on microstructural bi-layer fiber-matrix model with softening. J Biomech 41:447–453
33.
Ohayon J, Dubreuil O, Tracqui P, LeFloc’h S, Rioufol G, Chalabreysse L, Thivolet F, Pettigrew R, Finet G (2007) Influence of residual stress/strain on the biomechanical stability of vulnerable coronary plaques: potential impact for evaluating the risk of plaque rupture. Am J Physiol Heart Circ Physiol 293:H1987–H1996
34.
Wang C, Kassab G (2009) Increase in opening angle in hypertension off-loads the intimal stress: a simulation study. J Biomech Eng 131:114502. doi:10.​1115/​1.​4000085
35.
Fung Y, Liu S (1991) Change in zero-stress state of rat pulmonary arteries in hypoxic hypertension. J Appl Physiol 70:2455–2470
36.
Horny L, Adamek T, Zitny R (2013) Age-related changes in longitudinal prestress in human abdominal aorta. Arch Appl Mech 83:875–888
37.
Cacho F, Doblare M, Holzapfel G (2007) A procedure to simulate coronary artery bypass graft surgery. Med Biol Eng Comput 45:819–827
38.
Zhao X, Liu Y, Zhang W, Wang C, Kassab G (2011) A novel arterial constitutive model in a commercial finite element package: application to balloon angioplasty. J Theor Biol 286:92–99MathSciNet
39.
Gurtner G, Dauskardt R, Wong V, Bhatt K, Wu K, Vial I, Padois K, Korman J, Longacker M (2011) Improving Cutaneous scar formation by controlling the mechanical environment. Ann Surg 254:217–225
40.
Capek L, Jacquet E, Dzan L, Simunek A (2012) The analysis of forces needed for the suturing of elliptical skin wounds. Med Biol Eng Comput 50:193–198
41.
ASTM Standard E1928, 2007, Standard practice for estimating the approximate residual circumferential stress in straight thin-walled tubing, ASTM International, West Conshohocken, PA. doi:10.​1520/​E1928-07
42.
Fung Y (1984) Biodynamics: circulation. Springer, New York, pp 54–60
43.
Vishnav R, Vossoughi, J (1983) Estimation of residual strains in aortic segments. In: Hall C (ed) Biomedical engineering II, recent developments pp 330-333
44.
Choung C, Fung Y (1986) On residual stresses in arteries. J Biomech Eng 108:189–192
45.
Raghavan M, Trivedi S, Nagaraj A, McPherson D, Chandran K (2004) Three-dimensional finite element analysis of residual stresses in arteries. Ann Biomed Eng 32:257–263
46.
Zhang W, Herrera C, Atluri S, Kassab G (2005) The effect of longitudinal pre-stress and radial constraint on the stress distribution in the vessel wall: a new hypothesis. Mol Cell Biomech 2:41–52
47.
Humphrey J (2002) Cardiovascular solid mechanics: cells, tissues and organs. Springer, New York
48.
Holzapfel G, Gasser T, Ogden R (2000) A new constitutive framework for arterial wall mechanics and a comparative study of material models. J Elast 61:1–48MATHMathSciNet
49.
Alastrue V, Martinez M, Doblare M (2008) Modeling adaptive volumetric finite growth in patient-specific residually stresses arteries. J Biomech 41:1773–1781
50.
Alford P, Humphrey J, Taber L (2008) Growth and remodeling in a thick-walled artery model: effects of spatial variations in wall constituents. Biomech Model Mechanbiol 7:245–262
51.
Hollander Y, Durban D, Lu X, Kassab G, Lanir R (2011) Constitutive modeling of coronary arterial media-comparison of three model cases. J Biomech Eng 133:061008-1–061008-12
52.
Stylianopoulos T, Barocas V (2007) Multiscale, structure-based modeling for the elastic mechanical behavior of arterial walls. J Biomech Eng 129:611–618
53.
Greenwald S et al (1997) Experimental investigation of the distribution of residual strains in the artery wall. J Biomech Eng 119:438–444
54.
Van Dyke T, Hoger A (2002) A new method for predicting the opening angle for soft tissues. J Biomech Eng 124:347–354
55.
Olsson T, Satlhand J, Klarbring A (2006) Modeling initial strain distribution in soft tissues with applications to arteries. Biomech Model Mechanobiol 5:27–38
56.
Ohanyon et al (2007) Influence of residual stress/strain on the biomechanical stability of vulnerable coronary plaques: potential impact for evaluating the risk of plaque rupture. Am J Physiol Heart Circ Physiol 293:H1987–H1996
57.
Balzani D, Schroder J, Gross D (2007) Numerical simulation of residual stresses in arterial walls. Comput Mater Sci 39:117–123
58.
Broisat A et al (2011) Assessing low levels of mechanical stress in aortic atherosclerotic lesions from apolipoprtoetin E-/- mice – brief report. Arterioscler Thromb Vasc Biol 31:1007–1010
59.
Cilla M, Pena E, Martinez M (2012) 3D computational parametric analysis of eccentric atherorma plaque: influence of axial and circumferential residual stress. Biomech Model Mechanobiol 11:1001–1013
60.
Xie J et al (1991) The zero-stress state of rat veins. J Biomech Eng 113:36–41
61.
Gregersen H, Lee T, Chien S, Skalak R, Fung Y (1999) Strain distribution in the layered wall of the esophagus. J Biomech Eng 121:442–448
62.
Laio D, Fan Y, Zeng G, Gregersen H (2003) Stress distribution in the layered wall of the rat oesophagus. Med Eng Phys 25:731–738
63.
Zhao J et al (2007) Opening angle and residual strain in a three-layered model of pig oesophagus. J Biomech 40:3187–3192
64.
Sokolis D (2010) Strain-energy function and three-dimensional stress distribution in esophageal biomechanics. J Biomech 43:2753–2764
65.
Gao C, Gregersen H (2000) Biomechanical and morphological properties in rat large intestine. J Biomech 33:1089–1097
66.
67.
Omens J, Fung Y (1990) Residual strain in rat left ventricle. Circ Res 66:37–45
68.
Summerour S, Emery J, Fazell B, Omesn J, McCulloch A (1998) Residual strain in ischemic ventricular myocardium. J Biomech Eng 120:710–714
69.
Omens J, McCulloch A, Crisicone J (2003) Complex distribution of residual stress and strain in the mouse left ventricle: experimental and theoretical models. Biomech Model Mechanobiol 1:267–277
70.
Lee E, Kim D, Azeloglu E, Costa K (2007) Engineered cardiac organoid chambers: toward functional biological model ventricle. Tissue Eng A 14:215–225
71.
Han H, Fung Y (1991) Residual strains in porcine and canine trachea. J Biomech 24:307–315
72.
McKay K et al (2002) Zero-stress state of intra- and extraparenchymal airways from human, pig, rabbit and sheep lungs. J Appl Physiol 92:1261–1266
73.
Xu G, Bayly P, Taber L (2009) Residual stress in the adult mouse brain. Biomech Model Mechanobiol 8:253–262
74.
Michalek A, Gardner-Morse M, Iatridis J (2012) Large residual strains are present in the intervertebral disc annulus fibrosus in the unloaded state. J Biomech 45:1227–1231
75.
Sachs G, Espey G (1942) A new method for determination of stress distribution in thin-walled tube. Trans Am Inst Min Metall Eng 147:348–360
76.
Vossoughi J (1992) Longitudinal residual strains in arteries. In: Digest of papers, Eleventh Southern Biomedical Engineering Conference, Memphis State University, Memphis, TN, pp. 17–19
77.
Wang L, Gleasson R (2010) A mechanical analysis of conduit arteries accounting for longitudinal residual strains. Ann Biomed Eng 38:1377–1387
78.
Holzapfel G et al (2007) Layer-specific 3D residual deformation of human aortas with non-atherosclerotic intimal thickening. Ann Biomed Eng 35:530–545
79.
Holzapfel G, Ogden R (2010) Modeling the layer-specific three-dimensional residual stresses in arteries, with an application to the human aorta. J R Soc Interface 7:787–799
80.
Zhao J, Liao D, Gregersen H (2005) Tension and stress in the rat and rabbit stomach are location- and direction-dependent. Neurogastroenterol Motil 17:388–398
81.
Setton L, Tohyama H, Mow V (1998) Swelling and curling behaviors of articular cartilage. J Biomech Eng 120:355–361
82.
Wan L, Guo X, Mow V (2010) A triphasic orthotropic laminate model for cartilage curling behavior: fixed charge density versus mechanical property inhomogeneity. J Biomech Eng 132:024504-1–024504-5
83.
Matsumoto T, Ikuta N, Mori M, Nagayam K (2010) Mechanics of wrinkle formation: micromechanical analysis of skin deformation during wrinkle formation in ultraviolet-irradiated mice. Skin Res Technol 16:179–189
84.
Hizal A, Sadasivam B, Arola D (2008) Residual stress in bone: a parametric study. In: Proc. 2008 ASME International Mechanical Engineering Congress and Exposition, paper no. IMECE2008-68944, American Society of Mechanical Engineers, New York
85.
Ascenzi M (1999) A first estimation of prestress in so-called circularly fibered osteonic lamellae. J Biomech 32:935–942
86.
ASTM Standard E837, 2008e2, Standard test method for determining residual stresses by the hole-drilling strain-gage method, ASTM International, West Conshohocken, PA. doi:10.​1520/​E0837-08E02
87.
Schajer G, Whitehead P (2013) Hole drilling and ring coring (chapter 2). In: Schajer G (ed) Practical residual stress measurement methods. Wiley, Chichester, pp 29–64
88.
Wright T, Barnett D, Hayes W (1977) Residual stress in bone. In: Chang T (ed) Recent advances in engineering science, vol 8, part III of Proc Tenth Anniversary Meeting of Soc Eng Sci (held in 1973). Scientific Publishers, Boston, pp 25–32
89.
Varner V, Taber L (2010) On measuring stress distributions in epithelia. In: Garikiptai K, Arruda E (eds) IUTAM symposium on cellular, molecular and tissue mechanics, IUTAM bookseries 16. Springer, New York, pp 45–54
90.
91.
Hutson M et al (2009) Combining laser microsurgery and finite element modeling to assess cell-level epithelial mechanics. Biophys J 97:3075–3085
92.
Langer K (1978) On the anatomy and physiology of the skin. II. Skin tension. Br J Plast Surg 31:93–106 (translation of an 1862 article)
93.
Reishner R, Balogh B, Menzel E (1995) Two-dimensional elastic properties of human skin in terms of an incremental model at the in-vivo configuration. Med Eng Phys 17:304–313
94.
Bush J, Ferguson M, Mason T, McGrouther D (2008) Skin tension or skin compression? Small circular wounds are likely to shrink, not gape. J Plast Reconstr Aesthet 61:529–534
95.
Ruud C (2002) Measurement of residual stresses. In: Totten G, Howes M, Inoue T (eds) Handbook of residual stress and deformation in steel. ASM International, Materials Park, pp 99–117
96.
Tanaka M, Adachi T (1994) Preliminary study on mechanical bone remodeling permitting residual stress. JSME Int J A-Mech M 37:87–95
97.
Adachi T, Tanaka M, Tomita Y (1998) Uniform stress state in bone structure with residual stress. J Biomech Eng 120:342–347
98.
Costa K, May-Newman K, Farr D, O’Dell W, McCulloch A, Omens J (1997) Three-dimensional residual strains in midanterior canine left ventricle. Am J Physiol (Heart Circ Physiol) 273:H1968–H1976
99.
Stella J, Sacks M (2007) On the biaxial mechanical properties of the layers of the aortic valve leaflet. J Biomech Eng 129:757–766
100.
Amini R et al (2012) On the in vivo deformation of the mitral valve anterior leaflet: effects of annular geometry and referential configuration. Ann Biomed Eng 40:1455–1467
101.
Prime M (1999) Residual stress measurement by successive extension of a slot: the crack compliance method. Appl Mech Rev 52:75–96
102.
Cheng F, Finnie I (2007) Residual stress measurement and the slitting method. Springer, New York
103.
Hill M (2013) Slitting. (chapter 4). In: Schajer G (ed) Practical residual stress measurement methods. Wiley, Chichester, pp 89–108
104.
Stanwyck T, Fischer R, Pope M, Seligson D (1982) Studies on prestress in bone. Biorheol 19:301–306
105.
Jones M, Pouchak M, Mikelsons R (1987) A method for measuring skin tension. In: Biomedical sciences instrumentation, vol. 23, Instrument Society of America, Research Triangle Park, NC, pp. 199–205.
106.
Chen J, Zhao B, Longaker M, Helms J, Carter D (2008) Periosteal biaxial residual strains correlate with bone specific growth rates in check embryos. Comput Method Biomech 11:453–461
107.
Henderson J, Nacamuli R, Zhao B, Longaker M, Carter D (2005) Age-dependent residual tensile strains are present in the dura mater of rats. J R Soc Interface 2:159–167
108.
Prime M, DeWald A (2013) Contour method (chapter 5). In: Schajer G (ed) Practical residual stress measurement methods. Wiley, Chichester, pp 109–138
109.
Matsumoto T, Goto T, Furukawa T, Sato M (2004) Residual stress and strain in the lamellar unit of the porcine aorta: experimental analysis. J Biomech 37:807–815
110.
Badel P, Genovese K, Avril S (2012) 3D residual stress field in arteries: novel inverse method based on optic full-field measurement. Strain 48:528–538
111.
Noyan I, Cohen J (1987) Residual stress: measurement by diffraction and interpretation. Springer, New York
112.
Noyan C, Murray C (2013) X-ray diffraction (chapter 6). In: Schajer G (ed) Practical residual stress measurement methods. Wiley, Chichester, pp 139–161
113.
Todoh M, Tadano S, Shibano J, Ukai T (2000) Polychromatic X-ray measurements of anisotropic residual stress in bone femoral bone. JSME Int J C - Mech Syst 43:795–801
114.
Tadano S, Okoshi T (2006) Residual stress in bone structure and tissue of rabbi’s tibiofibula. Bio-Med Mater Eng 16:11–21
115.
Yamada S, Tadano S (2010) Residual stress around the cortical surface in bovine femoral diaphysis. J Biomech Eng 132:044503-1–044503-4
116.
Withers P (2013) Synchrotron diffraction (chapter 7). In: Schajer G (ed) Practical residual stress measurement methods. Wiley, Chichester, pp 163–184
117.
Yamada S, Tadano S, Todoh M, Fujisaki K (2011) Residual stress distribution in the bovine femoral diaphysis measured by synchrotron. J Biomech Sci Eng 6:114–124
118.
Almer J, Stock S (2005) Internal strains and stresses measured in cortical bone via high-energy X-ray diffraction. J Struct Biol 152:14–27
119.
Almer J, Stock S (2007) Micromechanical response of mineral and collagen phases in bone. J Struct Biol 157:365–370
120.
ASTM Standard D 4093-95 (2010) Standard test method for photoelastic measurements of birefringence and residual strains in transparent or translucent plastic materials, ASTM International, West Conshohocken, PA. doi:10.​1520/​D4093-95R10
121.
Nienhaus U, Aegeter-Wilmsen T, Aegeter C (2009) Determination of mechanical stress distribution in Drosophila wing discs using photoelasticity. Mech Dev 126:942–949
122.
Schluck T, Aegeter C (2010) Photo-elastic properties of the wing imaginal disc of drosophila. Eur Phys J E33:111–115
123.
Crowe K, Smith R (1989) A new technique for determination of tensile stress in thin films. J Electrochem Soc 136:1566–1568
124.
Hong T et al (1990) Measuring stiffnesses and residual stresses of silicon nitride thin films. J Electron Mater 19:903–909
125.
Alexander H, Cook T (1977) Accounting for natural tension in the mechanical testing of human skin. J Investig Dermatol 69:310–314
126.
Dirdollou S et al (2000) Sex- and site-dependent variations in the thickness and mechanical properties of human skin in vivo. Int J Cosmet Sci 22:421–435
127.
Zamir E, Taber L (2004) On the effects of residual stress in microindentation tests of soft tissue structures. J Biomech Eng 126:276–283
128.
Zamir E, Taber L (2004) Material properties and residual stress in the stage 12 chick heart during cardiac looping. J Biomech Eng 126:823–830
129.
Carrasco C et al (2011) Built-in mechanical stress in viral shells. Biophys J 100:1100–1108
130.
Baclayon M et al (2011) Prestress strengthens the shell of norwalk virus nanoparticles. Nano Lett 11:4865–4869
131.
Klug W, Roos W, Wuite G (2012) Unlocking internal prestress from protein nanoshells. Phys Rev Lett 109:168104-1–168104-5
132.
Stamenovic D (2012) Cytoskeletal prestress as a determinant of deformability and rheology of adherent cells. In: Obradovi B (ed) Cell and tissue engineering. Springer, Berlin, pp 92–118
133.
Park C, Tambe D, Alencar A, Trepat X, Zhou E, Millet E, Butler J, Fredberg J (2010) Mapping the cytoskeletal prestress. Am J Physiol 298:C1245–C1252
134.
Matsumoto T, Tsuchida M, Sato M (1996) Change in intramural strain distribution in rat aorta due to smooth muscle contraction and relaxation. Am J Physiol 271:H1711–H1716
135.
Rachev A, Hayashi K (1999) Theoretical study of the effects of vascular smooth muscle contraction on strain and stress distributions in arteries. Ann Biomed Eng 27:459–468
136.
Fung Y, Liu S (1992) Strain distribution in small blood vessels with zero-stress state taken into consideration. Am J Physiol 262:H544–H552
137.
Zeller P, Skalak T (1998) Contributions of individual structural components in determining the zero-stress state in small arteries. J Vasc Res 35:8–17
138.
Yamada H, Shinoda T, Tanaka E, Yamamoto S (1999) Finite element modeling and numerical simulation of the artery in active state. JSME Int J C - Mech Syst 42:501–507
139.
Withers P, Bhadeshia H (2001) Residual stress. Part I – measurement techniques. Mater Sci Technol 17:355–365
140.
Wang Y, Meng F, Sachs F (2011) Genetically encoded force sensors for measuring mechanical forces in proteins. Commun Integr Biol 4:385–390
Metadaten
Titel
Experimental Methods for Determining Residual Stresses and Strains in Various Biological Structures
verfasst von
D. Nelson
Publikationsdatum
01.04.2014
Verlag
Springer US
Erschienen in
Experimental Mechanics / Ausgabe 4/2014
Print ISSN: 0014-4851
Elektronische ISSN: 1741-2765
DOI
https://doi.org/10.1007/s11340-013-9806-6

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