A conceptual framework for computational models of Achilles tendon homeostasis

Smith, David W.; Rubenson, Jonas; Lloyd, David G.; Zheng, Minghao; Fernandez, Justin; Besier, Thor F.; Xu, Jiake; Gardiner, Bruce S.

doi:10.1002/wsbm.1229

Cited by 29 publications

(33 citation statements)

References 106 publications

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“…The fibrils show different tendency of running directions, and fibrils with a same tendency form a secondary unit—fibril bundles. It is widely accepted that collagen fibres are constituted of a group of collagen fibrils in the tendon's hierarchical system, and no endotenon exists between collagen fibres . Therefore, it can be assumed that the definition of collagen fibres in tendon's hierarchical system actually refers to a group of collagen fibril bundles which have similar orientation.…”

Section: Resultsmentioning

confidence: 99%

Three dimensional microstructural network of elastin, collagen, and cells in Achilles tendons

Pang

Allison

et al. 2017

J. Orthop. Res.

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Similar to most biological tissues, the biomechanical, and functional characteristics of the Achilles tendon are closely related to its composition and microstructure. It is commonly reported that type I collagen is the predominant component of tendons and is mainly responsible for the tissue's function. Although elastin has been found in varying proportions in other connective tissues, previous studies report that tendons contain very small quantities of elastin. However, the morphology and the microstructural relationship among the elastic fibres, collagen, and cells in tendon tissue have not been well examined. We hypothesize the elastic fibres, as another fibrillar component in the extracellular matrix, have a unique role in mechanical function and microstructural arrangement in Achilles tendons. It has been shown that elastic fibres present a close connection with the tenocytes. The close relationship of the three components has been revealed as a distinct, integrated and complex microstructural network. Notably, a "spiral" structure within fibril bundles in Achilles tendons was observed in some samples in specialized regions. This study substantiates the hierarchical system of the spatial microstructure of tendon, including the mapping of collagen, elastin and tenocytes, with 3-dimensional confocal images. © 2017 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 35:1203-1214, 2017.

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Section: Resultsmentioning

confidence: 99%

Three dimensional microstructural network of elastin, collagen, and cells in Achilles tendons

Pang

Allison

et al. 2017

J. Orthop. Res.

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“…Because increased tendon longitudinal strain during tensile loading is closely associated with changes in tendon transverse morphology and strain (Obst et al, 2014b;Pokhai et al, 2009;Reeves and Cooper, 2014;Vergari et al, 2011), a similar relationship might be expected for the changes in tendon morphology and strain that occur in response to an exercise bout. In view of the high rate of exerciserelated injuries of the Achilles free tendon and the potential role short-term changes in tendon transverse dimensions could have on the local mechanical and biological environment (Heinemeier and Kjaer, 2011;Shim et al, 2014;Smith et al, 2013), there is a need to better understand the acute effects of exercise on the tendon 3D morphology and strain.…”

Section: Introductionmentioning

confidence: 99%

“…These changes were not explained by post-exercise differences in muscle activation patterns or torque production, but could reflect non-uniform fatigue or creep of Achilles tendon fascicles, due to differences in mechanical properties and/or tensile loading during eccentric heel drop (Arndt et al, 2011(Arndt et al, , 1998Slane and Thelen, 2014). Irrespective of the cause, acute alterations in the normal biaxial strain could have implications for intra-tendinous force distribution (Haraldsson et al, 2008), fluid flow (Reese et al, 2010;Yin and Elliott, 2004) and tissue homeostasis (Smith et al, 2013) and are therefore relevant in the context of exercise-dependent regional adaptation of Achilles free tendon structure and function. Our findings also suggest that AP diameter may be more responsive to change following exercise, compared with CSA or ML diameter, and support the use of AP diameter to evaluate acute, and possibly chronic, exercisedependent changes in Achilles free tendon transverse morphology (Grigg et al, 2012).…”

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confidence: 98%

Three-dimensional morphology and strain of the Achilles free tendon immediately following eccentric heel drop exercise

Obst

Newsham-West

Barrett

2015

Journal of Experimental Biology

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Our understanding of the immediate effects of exercise on Achilles free tendon transverse morphology is limited to single site measurements acquired at rest using 2D ultrasound. The purpose of this study was to provide a detailed 3D description of changes in Achilles free tendon morphology immediately following a single clinical bout of exercise. Freehand 3D ultrasound was used to measure Achilles free tendon length, and regional cross-sectional area (CSA), medio-lateral (ML) diameter and antero-posterior (AP) diameter in healthy young adults (N=14) at rest and during isometric muscle contraction, immediately before and after 3×15 eccentric heel drops. Post-exercise reductions in transverse strain were limited to CSA and AP diameter in the midproximal region of the Achilles free tendon during muscle contraction. The change in CSA strain during muscle contraction was significantly correlated to the change in longitudinal strain (r=−0.72) and the change in AP diameter strain (r=0.64). Overall findings suggest the Achilles free tendon experiences a complex change in 3D morphology following eccentric heel drop exercise that manifests under contractile but not rest conditions, is most pronounced in the mid-proximal tendon and is primarily driven by changes in AP diameter strain and not ML diameter strain.

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“…It is well accepted that collagen forms a hierarchical structure in tendons but the hierarchical structural order has been reported differently by different authors (Benjamin et al, 2008;Liu et al, 2011;Smith et al, 2013). Some scholars claimed that there are collagen fibres with a diameter from 10 to 50 µm in tendons that compose tendon fascicles.…”

Section: Discussionmentioning

confidence: 99%

“…Collagen (mainly type I collagen) is the most abundant constituent of the extracellular matrix (ECM) of tendons and plays a central role in the tissue's mechanical function (Fratzl et al, 1998;Gelse et al, 2003;Kuijpers et al, 2004;Provenzano & Vanderby, 2006). Thus, the collagen structure has been extensively studied to comprehend the physiology and function of tendons (Harvey et al, 2009;Liu et al, 2011), resulting in establishing nomenclature systems to describe the hierarchical characteristics of the collagen structure in the tendon (Kastelic et al, 1978;Kannus, 2000;Screen et al, 2005;Doroski et al, 2007;Harvey et al, 2009;Smith et al, 2013). However, the nomenclature systems existing in the literature mainly depict the collagen orienting longitudinally in the inner region.…”

Section: Introductionmentioning

confidence: 99%

High‐resolution study of the 3D collagen fibrillary matrix of Achilles tendons without tissue labelling and dehydrating

Swift

Becker

et al. 2017

Journal of Microscopy

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Knowledge of the collagen structure of an Achilles tendon is critical to comprehend the physiology, biomechanics, homeostasis and remodelling of the tissue. Despite intensive studies, there are still uncertainties regarding the microstructure. The majority of studies have examined the longitudinally arranged collagen fibrils as they are primarily attributed to the principal tensile strength of the tendon. Few studies have considered the structural integrity of the entire three-dimensional (3D) collagen meshwork, and how the longitudinal collagen fibrils are integrated as a strong unit in a 3D domain to provide the tendons with the essential tensile properties. Using second harmonic generation imaging, a 3D imaging technique was developed and used to study the 3D collagen matrix in the midportion of Achilles tendons without tissue labelling and dehydration. Therefore, the 3D collagen structure is presented in a condition closely representative of the in vivo status. Atomic force microscopy studies have confirmed that second harmonic generation reveals the internal collagen matrix of tendons in 3D at a fibril level. Achilles tendons primarily contain longitudinal collagen fibrils that braid spatially into a dense rope-like collagen meshwork and are encapsulated or wound tightly by the oblique collagen fibrils emanating from the epitenon region. The arrangement of the collagen fibrils provides the longitudinal fibrils with essential structural integrity and endows the tendon with the unique mechanical function for withstanding tensile stresses. A novel 3D microscopic method has been developed to examine the 3D collagen microstructure of tendons without tissue dehydrating and labelling. The study also provides new knowledge about the collagen microstructure in an Achilles tendon, which enables understanding of the function of the tissue. The knowledge may be important for applying surgical and tissue engineering techniques to tendon reconstruction.

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A conceptual framework for computational models of Achilles tendon homeostasis

Cited by 29 publications

References 106 publications

Three dimensional microstructural network of elastin, collagen, and cells in Achilles tendons

Three dimensional microstructural network of elastin, collagen, and cells in Achilles tendons

Three-dimensional morphology and strain of the Achilles free tendon immediately following eccentric heel drop exercise

High‐resolution study of the 3D collagen fibrillary matrix of Achilles tendons without tissue labelling and dehydrating

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