Experimental evaluation of multiscale tendon mechanics

Fang, Fei; Lake, Spencer P.

doi:10.1002/jor.23488

Cited by 32 publications

(25 citation statements)

References 164 publications

(266 reference statements)

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“…Biochemical changes in ECM that could modify muscle stiffness, other than the amount of collagen, include the type of collagen expressed or the posttranslational processing of collagen fibers. Collagen exists in multiple isoforms, and changes in isoform composition often correlate with different biomechanical properties (16). This observation, based primarily on a comparison between tendons and ligaments, reveals a correlation between increased compliance in tendons and an increase in the type 3-to-type 1 collagen ratio (29 human digital flexors (69), have lower ratios than those that are compliant enough to stretch and store energy, such as the Achilles tendon (1,2,29).…”

Section: Extracellular Matrix Biochemical Changes In Contracturementioning

confidence: 99%

Muscle contracture and passive mechanics in cerebral palsy

Lieber

Fridén

2019

Journal of Applied Physiology

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Skeletal muscle contractures represent the permanent shortening of a muscle-tendon unit, resulting in loss of elasticity and, in extreme cases, joint deformation. They may result from cerebral palsy, spinal cord injury, stroke, muscular dystrophy, and other neuromuscular disorders. Contractures are the prototypic and most severe clinical presentation of increased passive mechanical muscle force in humans, often requiring surgical correction. Intraoperative experiments demonstrate that high muscle passive force is associated with sarcomeres that are abnormally stretched, although otherwise normal, with fewer sarcomeres in series. Furthermore, changes in the amount and arrangement of collagen in the extracellular matrix also increase muscle stiffness. Structural light and electron microscopy studies demonstrate that large bundles of collagen, referred to as perimysial cables, may be responsible for this increased stiffness and are regulated by interaction of a number of cell types within the extracellular matrix. Loss of muscle satellite cells may be related to changes in both sarcomeres and extracellular matrix. Future studies are required to determine the underlying mechanism for changes in muscle satellite cells and their relationship (if any) to contracture. A more complete understanding of this mechanism may lead to effective nonsurgical treatments to relieve and even prevent muscle contractures.

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Section: Extracellular Matrix Biochemical Changes In Contracturementioning

confidence: 99%

Muscle contracture and passive mechanics in cerebral palsy

Lieber

Fridén

2019

Journal of Applied Physiology

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“…The loading requirements of the attachment involve tensile forces (e.g., from muscle contraction), compressive forces (e.g., from joint motion), and shear forces (e.g., from tendon fibril sliding) [1,2]. The attachment withstands these loads through its hierarchical, structural, and compositional features that may act to reduce stress and control strain at the interface [3][4][5][6][7]. At the macroscale, the tendon-to-bone attachment splays outwardly, increasing its cross-sectional area (CSA) from tendon to bone to reduce localized stress at the interface [8,9].…”

Section: Introductionmentioning

confidence: 99%

Strain Distribution of Intact Rat Rotator Cuff Tendon-to-Bone Attachments and Attachments With Defects

Locke

Peloquin

Lemmon

et al. 2017

Journal of Biomechanical Engineering

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This study aimed to experimentally track the tissue-scale strains of the tendon-bone attachment with and without a localized defect. We hypothesized that attachments with a localized defect would develop strain concentrations and would be weaker than intact attachments. Uniaxial tensile tests and digital image correlation were performed on rat infraspinatus tendon-to-bone attachments with defects (defect group) and without defects (intact group). Biomechanical properties were calculated, and tissue-scale strain distributions were quantified for superior and inferior fibrous and calcified regions. At the macroscale, the defect group exhibited reduced stiffness (31.3±3.7 N/mm), reduced ultimate load (24.7±3.8 N), and reduced area under the curve at ultimate stress (3.7±1.5 J/m2) compared to intact attachments (42.4±4.3 N/mm, 39.3±3.7 N, and 5.6±1.4 J/m2, respectively). Transverse strain increased with increasing axial load in the fibrous region of the defect group but did not change for the intact group. Shear strain of the superior fibrous region was significantly higher in the defect group compared to intact group near yield load. This work experimentally identified that attachments may resist failure by distributing strain across the interface and that strain concentrations develop near attachment defects. By establishing the tissue-scale deformation patterns of the attachment, we gained insight into the micromechanical behavior of this interfacial tissue and bolstered our understanding of the deformation mechanisms associated with its ability to resist failure.

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“…74,75 The occurrence of fiber reorganization causes the tendon stress-strain curve to be nonlinear, that is, under lower stress, the fiber undergoes large deformation. [76][77][78] The linear region in the mechanical curve is the process in which the fiber is stretched. Finally, the fiber is stretched to break under load.…”

Section: Fiber and Tissue Strengthmentioning

confidence: 99%

Mechanical Roles in Formation of Oriented Collagen Fibers

Lin

Shi

Men

et al. 2020

Tissue Engineering Part B: Reviews

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Collagen is a structural protein that is widely present in vertebrates, being usually distributed in tissues in the form of fibers. In living organisms, fibers are organized in different orientations in various tissues. As the structural base in connective tissue and load-bearing tissue, the orientation of collagen fibers plays an extremely important role in the mechanical properties and physiological and biochemical functions. The study on mechanics role in formation of oriented collagen fibers enables us to understand how discrete cells use limited molecular materials to create tissues with different structures, thereby promoting our understanding of the mechanism of tissue formation from scratch, from invisible to tangible. However, the current understanding of the mechanism of fiber orientation is still insufficient. In addition, existing fabrication methods of oriented fibers are varied and involve interdisciplinary study, and the achievements of each experiment are favorable to the construction and improvement of the fiber orientation theory. To this end, this review focuses on the preparation methods of oriented fibers and proposes a model explaining the formation process of oriented fibers in tendons based on the existing fiber theory.

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Experimental evaluation of multiscale tendon mechanics

Cited by 32 publications

References 164 publications

Muscle contracture and passive mechanics in cerebral palsy

Muscle contracture and passive mechanics in cerebral palsy

Strain Distribution of Intact Rat Rotator Cuff Tendon-to-Bone Attachments and Attachments With Defects

Mechanical Roles in Formation of Oriented Collagen Fibers

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