Soft tissue
In anatomy, soft tissue includes the tissues that connect, support, or surround other structures and organs of the body, not being hard tissue such as bone. Soft tissue includes tendons, ligaments, fascia, skin, fibrous tissues, fat, and synovial membranes (which are connective tissue), and muscles, nerves and blood vessels (which are not connective tissue).[1]
It is sometimes defined by what it is not. Soft tissue has been defined as "nonepithelial, extraskeletal mesenchyme exclusive of the reticuloendothelial system and glia".[2]
Composition
The characteristic substances inside the extracellular matrix of this kind of tissue are the collagen, elastin and ground substance. Normally the soft tissue is very hydrated because of the ground substance. The fibroblasts are the most common cell responsible for the production of soft tissues' fibers and ground substance. Variations of fibroblasts, like chondroblasts, may also produce these substances.[3]
Mechanical characteristics
At small strains, elastin confers stiffness to the tissue and stores most of the strain energy. The collagen fibers are comparatively inextensible and are usually loose (wavy, crimped). With increasing tissue deformation the collagen is gradually stretched in the direction of deformation. When taut, these fibers produce a strong growth in tissue stiffness. The composite behavior is analogous to a nylon stocking, whose rubber band does the role of elastin as the nylon does the role of collagen. In soft tissues, the collagen limits the deformation and protects the tissues from injury.
Human soft tissue is highly deformable, and its mechanical properties vary significantly from one person to another. Impact testing results showed that the stiffness and the damping resistance of a test subject’s tissue are correlated with the mass, velocity, and size of the striking object. Such properties may be useful for forensics investigation when contusions were induced.[4] When a solid object impacts a human soft tissue, the energy of the impact will be absorbed by the tissues to reduce the effect of the impact or the pain level; subjects with more soft tissue thickness tended to absorb the impacts with less aversion.[5]
Soft tissues have the potential to undergo large deformations and still return to the initial configuration when unloaded, i.e. they are hyperelastic materials, and their stress-strain curve is nonlinear. The soft tissues are also viscoelastic, incompressible and usually anisotropic. Some viscoelastic properties observable in soft tissues are: relaxation, creep and hysteresis.[6][7] In order to describe the mechanical response of soft tissues, several methods have been used. These methods include: hyperelastic macroscopic models based on strain energy, mathematical fits where nonlinear constitutive equations are used, and structurally based models where the response of a linear elastic material is modified by its geometric characteristics.[8]
Pseudoelasticity
Even though soft tissues have viscoelastic properties, i.e. stress as function of strain rate, it can be approximated by a hyperelastic model after precondition to a load pattern. After some cycles of loading and unloading the material, the mechanical response becomes independent of strain rate.
Despite the independence of strain rate, preconditioned soft tissues still present hysteresis, so the mechanical response can be modeled as hyperelastic with different material constants at loading and unloading. By this method the elasticity theory is used to model an inelastic material. Fung has called this model as pseudoelastic to point out that the material is not truly elastic.[7]
Residual stress
In physiological state soft tissues usually present residual stress that may be released when the tissue is excised. Physiologists and histologists must be aware of this fact to avoid mistakes when analyzing excised tissues. This retraction usually causes a visual artifact.[7]
Fung-elastic material
Fung developed a constitutive equation for preconditioned soft tissues which is
with
quadratic forms of Green-Lagrange strains and , and material constants.[7] is the strain energy function per volume unit, which is the mechanical strain energy for a given temperature.
Isotropic simplification
The Fung-model, simplified with isotropic hypothesis (same mechanical properties in all directions). This written in respect of the principal stretches ():
- ,
where a, b and c are constants.
Simplification for small and big stretches
For small strains, the exponential term is very small, thus negligible.
On the other hand, the linear term is negligible when the analysis rely only on big strains.
Gent-elastic material
where is the shear modulus for infinitesimal strains and is a stiffening parameter, associated with limiting chain extensibility.[9] This constitutive model cannot be stretched in uni-axial tension beyond a maximal stretch , which is the positive root of
Remodeling and growth
Soft tissues have the potential to grow and remodel reacting to chemical and mechanical long term changes. The rate the fibroblasts produce tropocollagen is proportional to these stimuli. Diseases, injuries and changes in the level of mechanical load may induce remodeling. An example of this phenomenon is the thickening of farmer's hands. The remodeling of connective tissues is well known in bones by the Wolff's law (bone remodeling). Mechanobiology is the science that study the relation between stress and growth at cellular level.[6]
Growth and remodeling have a major role in the cause of some common soft tissue diseases, like arterial stenosis and aneurisms [10][11] and any soft tissue fibrosis. Other instance of tissue remodeling is the thickening of the cardiac muscle in response to the growth of blood pressure detected by the arterial wall.
Imaging techniques
There are certain issues that have to be kept in mind when choosing an imaging technique for visualizing soft tissue ECM components. The accuracy of the image analysis relies on the properties and the quality of the raw data and, therefore, the choice of the imaging technique must be based upon issues such as:
- Having an optimal resolution for the components of interest;
- Achieving high contrast of those components;
- Keeping the artifact count low;
- Having the option of volume data acquisition;
- Keeping the data volume low;
- Establishing an easy and reproducible setup for tissue analysis.
The collagen fibers are approximately 1-2 μm thick. Thus, the resolution of the imaging technique needs to be approximately 0.5 μm. Some techniques allow the direct acquisition of volume data while other need the slicing of the specimen. In both cases, the volume that is extracted must be able to follow the fiber bundles across the volume. High contrast makes segmentation easier, especially when color information is available. In addition, the need for fixation must also be addressed. It has been shown that soft tissue fixation in formalin causes shrinkage, altering the structure of the original tissue. Some typical values of contraction for different fixation are: formalin (5% - 10%), alcohol (10%), bouin (<5%).[12]
Imaging methods used in ECM visualization and their properties.[12][13]
Transmission Light |
Confocal |
Multi-Photon Excitation Fluorescence |
Second Harmonic Generation |
Optical Coherence Tomography | |
Resolution |
0.25 μm |
Axial: 0.25-0.5 μm Lateral: 1 μm |
Axial: 0.5 μm Lateral: 1 μm |
Axial: 0.5 μm Lateral: 1 μm |
Axial: 3-15 μm Lateral: 1-15 μm |
Contrast |
Very High |
Low |
High |
High |
Moderate |
Penetration |
N/A |
10 μm-300 μm |
100-1000 μm |
100-1000 μm |
Up to 2–3 mm |
Image stack cost |
High |
Low |
Low |
Low |
Low |
Fixation |
Required |
Required |
Not required |
Not required |
Not required |
Embedding |
Required |
Required |
Not required |
Not required |
Not required |
Staining |
Required |
Not required |
Not required |
Not required |
Not required |
Cost |
Low |
Moderate to high |
High |
High |
Moderate |
See also
References
- ^ Definition at National Cancer Institute
- ^ Skinner, Harry B. (2006). Current diagnosis & treatment in orthopedics. Stamford, Conn: Lange Medical Books/McGraw Hill. p. 346. ISBN 0-07-143833-5.
- ^ Junqueira, L.C.U.; Carneiro, J.; Gratzl, M. (2005). Histologie. Heidelberg: Springer Medizin Verlag. p. 479. ISBN 3-540-21965-X.
- ^ Amar, M., Alkhaledi, K., and Cochran, D., (2014). Estimation of mechanical properties of soft tissue subjected to dynamic impact. Journal of Eng. Research Vol. 2 (4), pp. 87-101
- ^ Alkhaledi, K., Cochran, D., Riley, M., Bashford, G., and Meyer, G. (2011). The psychophysical effects of physical impact to human soft tissue. ECCE '11 Proceedings of the 29th Annual European Conference on Cognitive Ergonomics Pages 269-270
- ^ a b Humphrey, Jay D. (2003). The Royal Society (ed.). "Continuum biomechanics of soft biological tissues" (PDF). Proceedings of the Royal Society of London A. 459 (2029): 3–46. Bibcode:2003RSPSA.459....3H. doi:10.1098/rspa.2002.1060.
- ^ a b c d Fung, Y.-C. (1993). Biomechanics: Mechanical Properties of Living Tissues. New York: Springer-Verlag. p. 568. ISBN 0-387-97947-6.
- ^ Sherman, Vincent R. (2015). "The materials science of collagen". Journal of the Mechanical Behavior of Biomedical Materials. 52: 22–50. doi:10.1016/j.jmbbm.2015.05.023. PMID 26144973.
- ^ Gent, A. N. (1996). "A new constitutive relation for rubber". Rub. Chem. Tech. 69: 59–61. doi:10.5254/1.3538357.
- ^ Humphrey, Jay D. (2008). Springer-Verlag (ed.). "Vascular adaptation and mechanical homeostasis at tissue, cellular, and sub-cellular levels". Cell Biochemistry and Biophysics. 50 (2): 53–78. doi:10.1007/s12013-007-9002-3. PMID 18209957.
- ^ Holzapfel, G.A.; Ogden, R.W. (2010). The Royal Society (ed.). "Constitutive modelling of arteries". Proceedings of the Royal Society of London A. 466 (2118): 1551–1597. Bibcode:2010RSPSA.466.1551H. doi:10.1098/rspa.2010.0058.
- ^ a b Elbischger, P. J; Bischof, H; Holzapfel, G. A; Regitnig, P (2005). "Computer vision analysis of collagen fiber bundles in the adventitia of human blood vessels". Studies in Health Technology and Informatics. 113: 97–129. PMID 15923739.
- ^ Georgakoudi, I; Rice, W. L; Hronik-Tupaj, M; Kaplan, D. L (2008). "Optical Spectroscopy and Imaging for the Noninvasive Evaluation of Engineered Tissues". Tissue Engineering Part B: Reviews. 14 (4): 321–340. doi:10.1089/ten.teb.2008.0248. PMC 2817652. PMID 18844604.