A Systematic Review of Tissue Engineering Scaffold in Tendon Bone Healing in vivo

Mao, Zimu; Fan, Bao-Shi; Wang, Xinjie; Huang, Ximeng; Guan, Jian; Sun, Zewen; Xu, Bingbing; Yang, Meng; Chen, Zeyi; Jiang, Dong; Yu, Jia-Kuo

doi:10.3389/fbioe.2021.621483

Cited by 23 publications

(22 citation statements)

References 84 publications

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“…Contact area in particular is felt to be important for achieving tendon healing. 24 , 25 , 26 While DR repairs have decreased the incidence of retear, overall retears rates remain at approximately 25%, and are notably increased with larger tears. 27 Thus, it appears worthwhile to continue to attempt to maximize contact force in large and massive rotator cuff tears, given its direct relationship with area.…”

Section: Discussionmentioning

confidence: 99%

Three Medial All Suture Anchors Improves Contact Force Compared to Two Hard Body Anchors in a Biomechanical Two-Tendon Rotator Cuff Tear Model

Hoffman¹,

Lamplot²,

McClish³

et al. 2022

Arthroscopy, Sports Medicine, and Rehabilitation

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Section: Discussionmentioning

confidence: 99%

Three Medial All Suture Anchors Improves Contact Force Compared to Two Hard Body Anchors in a Biomechanical Two-Tendon Rotator Cuff Tear Model

Hoffman¹,

Lamplot²,

McClish³

et al. 2022

Arthroscopy, Sports Medicine, and Rehabilitation

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“…The depletion of tenocytes and collagen I may be a significant reason for this property deterioration [34][35][36]. Therefore, in addition to surgical repair, researchers have advocated rebuilding the biological and physical properties of the tendon by upregulating the cellular and tissue responses during tendon repair, including the supplementation of bioactive growth factors, modulation of the inflammatory response, and adoption of tissue engineering [37][38][39][40][41].…”

Section: Discussionmentioning

confidence: 99%

Tri-Layered Doxycycline-, Collagen- and Bupivacaine-Loaded Poly(lactic-co-glycolic acid) Nanofibrous Scaffolds for Tendon Rupture Repair

Shen

Hsu

et al. 2022

Polymers

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Achilles tendon rupture is a severe injury, and its optimal therapy remains controversial. Tissue engineering scaffolds play a significant role in tendon healing and tissue regeneration. In this study, we developed tri-layered doxycycline/collagen/bupivacaine (DCB)-composite nanofibrous scaffolds to repair injured Achilles tendons. Doxycycline, collagen, and bupivacaine were integrated into poly(lactic-co-glycolic acid) (PLGA) nanofibrous membranes, layer by layer, using an electrospinning technique as healing promoters, a 3D scaffold, and painkillers, respectively. After spinning, the properties of the nanofibrous scaffolds were characterized. In vitro drug discharge behavior was also evaluated. Furthermore, the effectiveness of the DCB–PLGA-composite nanofibers in repairing ruptured Achilles tendons was investigated in an animal tendon model with histological analyses. The experimental results show that, compared to the pristine PLGA nanofibers, the biomolecule-loaded nanofibers exhibited smaller fiber size distribution and an enhanced hydrophilicity. The DCB-composite nanofibers provided a sustained release of doxycycline and bupivacaine for over 28 days in vivo. Additionally, Achilles tendons repaired using DCB-composite nanofibers exhibited a significantly higher maximum load-to-failure than normal tendons, suggesting that the biomolecule-incorporated nanofibers are promising scaffolds for repairing Achilles tendons.

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“…Most studies of TDCs in vitro have used very stiff tissue culture plastic (TCP)to better understand tendon cell biology, which is well known to induce TDC dedifferentiation ( Taylor et al, 2009 ). Also, the majority of current tissue engineering approaches aim to apply material scaffolds that do not match the native tendon biomechanical properties, thus creating a mismatch in properties between the intervention and tendon resident cells ( Vasiliadis and Katakalos, 2020 ; Mao et al, 2021 ). Therefore, understanding how ECM microenvironemntal cues affect cell behaviour in tendon has importance for creating more physiologically-relevant in vitro platforms to study tendon cell biology, and for infomring future therapeutics which can better direct and maintain resident tendon cell characteristics.…”

Section: Introductionmentioning

confidence: 99%

Changes in Physiological Tendon Substrate Stiffness Have Moderate Effects on Tendon-Derived Cell Growth and Immune Cell Activation

Konar

Bolam

Coleman

et al. 2022

Front. Bioeng. Biotechnol.

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Tendinopathy is characterised by pathological changes in tendon matrix composition, architecture, and stiffness, alterations in tendon resident cell characteristics, and fibrosis, with inflammation also emerging as an important factor in tendinopathy progression. The sequence of pathological changes in tendinopathy and the cellular effects of the deteriorating matrix are largely unknown. This study investigated the effects of substrate stiffness on tendon-derived cells (TDCs) and THP-1 macrophages using PDMS substrates representing physiological tendon stiffness (1.88 MPa), a stiff gel (3.17 MPa) and a soft gel (0.61 MPa). Human TDCs were cultured on the different gel substrates and on tissue culture plastic. Cell growth was determined by alamarBlue™ assay, cell morphology was analysed in f-actin labelled cells, and phenotypic markers were analysed by real-time PCR. We found that in comparison to TDCs growing on gels with physiological stiffness, cell growth increased on soft gels at 48 h (23%, p = 0.003). Cell morphology was similar on all three gels. SCX expression was slightly reduced on the soft gels (1.4-fold lower, p = 0.026) and COL1A1 expression increased on the stiff gels (2.2-fold, p = 0.041). Culturing THP-1 macrophages on soft gels induced increased expression of IL1B (2-fold, p = 0.018), and IL8 expression was inhibited on the stiffer gels (1.9-fold, p = 0.012). We also found that culturing TDCs on plastic increased cell growth, altered cell morphology, and inhibited the expression of SCX, SOX9, MMP3, and COL3. We conclude that TDCs and macrophages respond to changes in matrix stiffness. The magnitude of responses measured in TDCs were minor on the range of substrate stiffness tested by the gels. Changes in THP-1 macrophages suggested a more inflammatory phenotype on substrates with non-physiological stiffness. Although cell response to subtle variations in matrix stiffness was moderate, it is possible that these alterations may contribute to the onset and progression of tendinopathy.

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A Systematic Review of Tissue Engineering Scaffold in Tendon Bone Healing in vivo

Cited by 23 publications

References 84 publications

Three Medial All Suture Anchors Improves Contact Force Compared to Two Hard Body Anchors in a Biomechanical Two-Tendon Rotator Cuff Tear Model

Three Medial All Suture Anchors Improves Contact Force Compared to Two Hard Body Anchors in a Biomechanical Two-Tendon Rotator Cuff Tear Model

Tri-Layered Doxycycline-, Collagen- and Bupivacaine-Loaded Poly(lactic-co-glycolic acid) Nanofibrous Scaffolds for Tendon Rupture Repair

Changes in Physiological Tendon Substrate Stiffness Have Moderate Effects on Tendon-Derived Cell Growth and Immune Cell Activation

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