A finite element model predicts the mechanotransduction response of tendon cells to cyclic tensile loading

Lavagnino, Michael; Arnoczky, Steven P.; Kepich, Eugene; Caballero, Oscar; Haut, Roger C.

doi:10.1007/s10237-007-0104-z

Cited by 94 publications

(80 citation statements)

References 60 publications

(130 reference statements)

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“…34 While these load induced alterations in gene expression in tendon cells cannot be directly attributed to a mechanosensory function of the primary cilium, the affects of loading have been associated with changes in cilia length. 9,18,21,31,32 Tensile loading of rat tail tendons has been shown to result in fluid flow, 25,26 and cellular deformations. 24 Both of these mechanisms have previously been associated with a decrease in cilia length.…”

Section: Discussionmentioning

confidence: 99%

“…22 Studies from our lab have shown that stress-deprivation (SD) of tendon cells has been associated with a disruption of cytoskeletal organization, 23 while tensile loading of tendons has been associated with cell deformation 24 and extracellular fluid flow. 25,26 Therefore, the purpose of the current study was to examine the effect of loading conditions on the length of primary cilia of rat tail tendon cells in situ. We hypothesize that (A) SD will increase the length of primary cilia on cells within a rat tail tendon and (B) cyclic tensile loading will reverse (shorten) tendon cell cilia lengthened in response to SD.…”

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confidence: 99%

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Effect of in vitro stress‐deprivation and cyclic loading on the length of tendon cell cilia in situ

Gardner

Arnoczky

Lavagnino

2010

Journal Orthopaedic Research

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To determine the effect of loading conditions on the length of primary cilia in tendon cells in situ, freshly harvested rat tail tendons were stress-deprived (SD) for up to 72 h, cyclically loaded at 3% strain at 0.17 Hz for 24 h, or SD for 24 h followed by cyclic loading (CL) for 24 h. Tendon sections were stained for tubulin, and cilia measured microscopically. In fresh control tendons, cilia length ranged from 0.6 to 2.0 mm with a mean length of 1.1 mm. Following SD, cilia demonstrated an increase ( p < 0.001) in overall length at 24 h when compared to controls. Cilia length did not increase with time of SD ( p ¼ 0.329). Cilia in cyclically loaded tendons were shorter ( p < 0.001) compared to all SD time periods, but were not different from 0 time controls ( p ¼ 0.472). CL for 24 h decreased cilia length in 24 h SD tendons ( p < 0.001) to levels similar to those of fresh controls ( p ¼ 0.274). The results of this study demonstrate that SD resulted in an immediate and significant increase in the length of primary cilia of tendon cells, which can be reversed by cyclic tensile loading. This suggests that, as in other tissues, cilia length in tendon cells is affected by mechanical signaling from the extracellular matrix. Keywords: tendon cell; primary cilia; stress-deprivation; tensile loading Mechanical loading is essential for maintaining the health and homeostasis of tendons, although the fundamental mechanotransduction pathways by which cells mediate this process are unclear. 1 Primary cilia are sensory organelles for the detection and transmission of mechanical and chemical information from the extracellular environment of cells [2][3][4] and are known to function as mechanosensors in several connective tissue cell types, including tenocytes, osteocytes, and chondrocytes. [5][6][7][8][9][10][11] The expression of transmembrane extracellular matrix receptors (integrins) on the cilium strongly suggests that the cilium has the molecular machinery necessary to act as a mechanosensory linkage between the ECM and cytoplasmic organelles. 10 Bending or stretching of the cilium can tug on such integrins, thus generating a cascade of events ranging from internal calcium release 12 to the activation of genes 10 and signaling molecules. [13][14][15] However, the degree of cilia bending required to elicit a specific cellular response is unknown. 16 The primary cilium has been modeled as a cantilevered beam whose deflection, secondary to cell deformation or fluid flow, produces a mechanosensory signal to the cell. 17 As such, is it logical to assume that the longer the beam (cilium), the more sensitive it will be to smaller deflection forces and, conversely, the shorter the beam, the less sensitive it will be. 17 Indeed, previous studies have suggested that the level of mechanical stimuli experienced by a cell could lead to remodeling of its ciliary structure through changes in its length. 16 Such modifications could, theoretically, make the cilia more or less sensitive to mechanical signals transmitted by the e...

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Effect of in vitro stress‐deprivation and cyclic loading on the length of tendon cell cilia in situ

Gardner

Arnoczky

Lavagnino

2010

Journal Orthopaedic Research

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“…of view, four factors of the applied strain may affect the adaptive response of tendons: magnitude, frequency, rate and duration (Arnoczky et al, 2002;Lavagnino et al, 2008;Yamamoto et al, 2005;Yamamoto et al, 2003;Yang et al, 2004). Recent experiments on the human Achilles tendon (AT) in vivo by our group showed that a high strain magnitude (4.5-5.0%) is required to trigger adaptive effects on the tendon mechanical, morphological and material properties (Arampatzis et al, 2010;Arampatzis et al, 2007).…”

Section: Research Articlementioning

confidence: 99%

“…The strain at the cellular level is much lower compared with the external tendon strain (Arnoczky et al, 2002;Screen et al, 2005). Two modes were suggested for the transmission of the external strain to the cellular level: cell deformation and fluid flow-induced shear stress (Lavagnino et al, 2003;Lavagnino et al, 2008). With increasing strain, a loss of collagen crimp and an increase in fiber recruitment was observed (Hansen et al, 2002;Schatzmann et al, 1998) and likely results in an increased number of cells being deformed (Arnoczky et al, 2002).…”

Section: Research Articlementioning

confidence: 99%

“…With increasing strain, a loss of collagen crimp and an increase in fiber recruitment was observed (Hansen et al, 2002;Schatzmann et al, 1998) and likely results in an increased number of cells being deformed (Arnoczky et al, 2002). The inhibition of catabolic cell responses (collagenase mRNA) seems to be directly associated with progressive increases of strain magnitude (Arnoczky et al, 2004;Lavagnino et al, 2008;Lavagnino et al, 2003). Furthermore, the extracellular matrix features viscous behavior due to the content of collagen and water, and interactions between collagenous and non-collagenous properties (Ciarletta and Ben Amar, 2009;, and, thus, a time-dependent transmission of the external tendon strain to the cytoskeleton.…”

Section: Research Articlementioning

confidence: 99%

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Human achilles tendon plasticity in response to cyclic strain: effect of rate and duration

Böhm

Mersmann

Tettke

et al. 2014

Journal of Experimental Biology

104

180

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High strain magnitude and low strain frequency are important stimuli for tendon adaptation. Increasing the rate and duration of the applied strain may enhance the adaptive responses. Therefore, our purpose was to investigate the effect of strain rate and duration on Achilles tendon adaptation. The study included two experimental groups (N=14 and N=12) and a control group (N=13). The participants of the experimental groups exercised according to a reference protocol (14 weeks, four times a week), featuring a high strain magnitude (~6.5%) and a low strain frequency (0.17 Hz, 3 s loading/3 s relaxation) on one leg and with either a higher strain rate (one-legged jumps) or a longer strain duration (12 s loading) on the other leg. The strain magnitude and loading volume were similar in all protocols. Before and after the interventions, the tendon stiffness, Young's modulus and cross-sectional area were examined using magnetic resonance imaging, ultrasound and dynamometry. The reference and long strain duration protocols induced significantly increased (P<0.05) tendon stiffness (57% and 25%), cross-sectional area (4.2% and 5.3%) and Young's modulus (51% and 17%). The increases in tendon stiffness and Young's modulus were higher in the reference protocol. Although region-specific tendon hypertrophy was also detected after the high strain rate training, there was only a tendency of increased stiffness (P=0.08) and cross-sectional area (P=0.09). The control group did not show any changes (P=0.86). The results provide evidence that a high strain magnitude, an appropriate strain duration and repetitive loading are essential components for an efficient adaptive stimulus for tendons.

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A Parametrical Analysis on the Elastic Anisotropy of Woven Hierarchical Tissues

Chen

Pugno

2011

Adv Eng Mater

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In this paper, the elastic properties of 2‐D woven hierarchical tissues are modeled, considering matrix transformation and stiffness averaging, assuming the warp and fill yarns (level 0) an orthotropic material. The tissue at level 1 is considered as the fabric composed of warp and fill yarns at level 0. Warp and fill yarns at level 1 are defined as “pieces” of such 1‐level tissue and have a different mismatch between the inclination of their longitudinal axes and those of the composing sub‐fibers. Similarly, based on warp and fill yarns at level 1, we generate warp and fill yarns at level 2 and thus tissues with two hierarchical levels, and so on. We compare our theory with experiments on tendons from the literature and on leaves performed by ourselves. The result shows the possibility of designing a new class of hierarchical 2‐D scaffolds by tailoring the elastic anisotropy, better matching the anisotropy of the biological tissues and thus maximizing their regeneration at each hierarchical level.

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A finite element model predicts the mechanotransduction response of tendon cells to cyclic tensile loading

Cited by 94 publications

References 60 publications

Effect of in vitro stress‐deprivation and cyclic loading on the length of tendon cell cilia in situ

Effect of in vitro stress‐deprivation and cyclic loading on the length of tendon cell cilia in situ

Human achilles tendon plasticity in response to cyclic strain: effect of rate and duration

A Parametrical Analysis on the Elastic Anisotropy of Woven Hierarchical Tissues

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