Abstract
In this chapter, stretching is defined with reference made to various stretching techniques. An understanding of how force (generated by stretching) affects soft and connective tissue is looked at both macroscopically (muscle, tendon, myotendon junction) and microscopically (sarcomere, myofibrillar proteins, ECM). By referring to these levels, an appreciation is gained of how the magnitude and rate of force generated during stretching affects the body as a whole. In order to elucidate this further, reference is made to inflammation and exercise, both non-damaging and damaging. With stretching considered as a load on tissue, a comprehensive overview is focused on damaging exercise, neutrophils, macrophages, and cytokines and their importance with regard to acute inflammation. The idea is proposed that stretching intensity be considered as a mechanotransduction mechanism. Mechanotransduction refers to the process by which the cells and tissues of the body respond to their environment, with the conversion of a mechanical energy into biochemical signals. Tensegrity is the main tenant of mechanotransduction, concerned with the essential maintenance of mechanical stability, which may be influenced by stretching intensity. Depending on the stretching intensity, this may or may not prompt an inflammatory response.
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Further Readings
A. Molecular Structure of Muscle
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Campbell, I. D., & Humphries, M. J. (2011). Integrin structure, activation, and interactions. Cold Spring Harbor Perspectives in Biology, 2011, 1–14.
Clark, K. A., Mcelhinny, A. S., Beckerle, M. C., & Gregorio, C. C. (2002). Striated muscle cytoarchitecture: An intricate web of form and function. Annual Review of Cell and Developmental Biology, 18, 637–706.
Craig, R. W., & Padron, R. (2004). Molecular structure of the sarcomere. In A. C. Engel & C. Franzini-Armstrong (Eds.), Myology (3rd ed.). New York: McGraw-Hill.
Geeves, M. A., & Holmes, K. C. (2005). The molecular mechanism of muscle contraction. Advances in Protein Chemistry, 71, 161–193.
Green, L. J., Mould, P., & Humphries, M. J. (1998). The integrin b subunit. The International Journal of Biochemistry & Cell Biology, 30, 179–184.
Holmberg, J., & Durbeej, M. (2013). Laminin-211 in skeletal muscle function. Cell Adhesion & Migration, 7, 111–121.
Kontrogianni-Konstantopoulos, A., Ackermann, M. A., Bowman, A. L., Yap, S. V., & Bloch, R. J. (2009). Muscle giants: Molecular scaffolds in sarcomeregenesis. Physiological Reviews, 89, 1217–1267.
Mayer, U. (2003). Integrins: Redundant or important players in skeletal muscle. JBC, 278, 14587–14590.
Plow, E. F., Haas, T. A., Zhang, L., Loftus, J., & Smith, J. W. (2000). Ligand binding to integrins. JBC, 275, 21785–21788.
Squire, J. M., Al-Khayat, H. A., Knupp, C., & Luther, P. K. (2005). Molecular architecture in muscle contractile assemblies. Advances in Protein Chemistry, 71, 17–87.
B. Myotendon Unit
Charvet, B., Ruggiero, F., & Le Guellec, D. (2012). The development of the myotendinous junction. A review. Muscles, Ligaments, and Tendons Journal, 2, 53–63.
Ricard-Blum, S. (2011). The collagen family. Cold Spring Harbor Perspectives in Biology, 3, a004978.
C. Mechanotransduction
Humphrey, J. D., Dufresne, E. R., & Schwartz, M. A. (2014). Mechanotransduction and extracellular matrix homeostasis. Nature Reviews. Molecular Cell Biology, 15, 802–812.
D. Rolling, Adhesion Transmigration
Ley, K., Laudanna, C., Cybulsky, M. I., & Noursharhg, S. (2007). Getting to the site of inflammation: The leukocyte adhesion cascade update. Nature Reviews Immunology, 7, 678–689.
Muller, W. A. (2013). Getting leukocytes to the site of inflammation. Veterinary Pathology, 50, 7–22.
Sundd, P., Pospieszalska, M. K., & Ley, K. (2013). Neutrophil rolling at high shear: Flattening, catch bond behavior, tethers and slings. Molecular Immunology, 55, 59–69.
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Apostolopoulos, N.C. (2018). Literature Review. In: Stretch Intensity and the Inflammatory Response: A Paradigm Shift. Springer, Cham. https://doi.org/10.1007/978-3-319-96800-1_2
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