&lt;p&gt;Promoting tendon to bone integration using graphene oxide-doped electrospun poly(lactic-co-glycolic acid) nanofibrous membrane&lt;/p&gt;

Su, Wei; Wang, Zhiying; Jiang, Jia; Liu, Xiaoyun; Zhao, Jinzhong; Zhang, Zhijun

doi:10.2147/ijn.s183842

Cited by 44 publications

(33 citation statements)

References 57 publications

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“…Based on ordinary fused deposition modeling (FDM) 3D printing, by increasing the electric field, the ink passing through the needle base can be further pulled, thereby breaking the aperture limit of the printing needle and achieving higher precision. In the past, electrospinning technology was used but was mostly used to prepare 2D electrospun nanofiber membranes [ [46] , [47] , [48] , [49] ]. When combined with 3D printing technology to obtain a 3D structure and achieve controlled printing, it is difficult for the wire diameter to reach the nanometer level of the nanofiber membrane, and the highest controllable precision can reach 1 μm [ 7 , 50 ].…”

Section: Discussionmentioning

confidence: 99%

High-precision, gelatin-based, hybrid, bilayer scaffolds using melt electro-writing to repair cartilage injury

Jia

Lian

Sun

et al. 2021

Bioactive Materials

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Section: Discussionmentioning

confidence: 99%

High-precision, gelatin-based, hybrid, bilayer scaffolds using melt electro-writing to repair cartilage injury

Jia

Lian

Sun

et al. 2021

Bioactive Materials

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“…Tendon-to-bone healing in rotator cuff repair is always a major problem, as is enthesis formation in all tendon repairs. 38 The healing or integration of artificial graft to bone is even more difficult, especially in reconstructing the transitional structure of the enthesis. 16,21,27 In 2014, Kim et al 21 made a structure with 4 layers to promote tendon-bone healing and found it effective in vitro.…”

Section: Discussionmentioning

confidence: 99%

“…10,34 As a consequence, grafts have been developed to bridge the MRCT. 38 However, limited healing potential between tendon and graft or between graft and bone is still a problem. 9…”

mentioning

confidence: 99%

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A Synthetic Graft With Multilayered Co-Electrospinning Nanoscaffolds for Bridging Massive Rotator Cuff Tear in a Rat Model

et al. 2020

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Background: Graft bridging is used in massive rotator cuff tear (MRCT); however, the integration of graft-tendon and graft-bone is still a challenge. Hypothesis: A co-electrospinning nanoscaffold of polycaprolactone (PCL) with an “enthesis-mimicking” (EM) structure could bridge MRCT, facilitate tendon regeneration, and improve graft-bone healing. Study Design: Controlled laboratory study. Methods: First, we analyzed the cytocompatibility of the electrospinning nanoscaffolds, including aligned PCL (aPCL), nonaligned PCL (nPCL), aPCL–collagen I, nPCL–collagen II, and nPCL-nanohydroxyapatite (nHA). Second, for the EM condition, nPCL–collagen II and nPCL-nHA were electrospun layer by layer at one end of the aPCL–collagen I; for the control condition, the nPCL was electrospun on the aPCL. In 40 mature male rats, resection of both the supraspinatus and infraspinatus tendons was performed to create MRCT, and the animals were divided randomly into EM and control groups. In both groups, one end of the layered structure was fixed on the footprint of the rotator cuff, whereas the other end of the layered structure was sutured with the tendon stump. The animals were euthanized for harvesting of tissues for histologic and biomechanical analysis at 4 weeks or 8 weeks postoperatively. Results: All scaffolds showed good cytocompatibility in vitro. The graft-tendon tissue in the EM group had more regularly arranged cells, denser tissue, a significantly higher tendon maturing score, and more birefringence compared with the control group at 8 weeks after operation. Newly formed fibrocartilage could be observed at the graft-bone interface in both groups by 8 weeks, but the EM group had a higher graft-bone healing score and significantly more newly formed fibrocartilage than the control group. An enthesis-like structure with transitional layers was observed in the EM group at 8 weeks. Biomechanically, the values for maximum failure load and stiffness of the tendon-graft-bone complex were significantly higher in the EM group than in the control group at 8 weeks. Conclusion: The co-electrospinning nanoscaffold of aPCL–collagen I could be used as a bridging graft to improve early graft-tendon healing for MRCT in a rat model and enhance early enthesis reconstruction in combination with a multilayered structure of nPCL–collagen II and nPCL-nHA. Clinical Relevance: We constructed a graft to bridge MRCT, enhance graft-tendon healing and graft-bone healing, and reconstruct the enthesis structure.

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“…However, to achieve osteoinductivity, it is necessary to add some functionalisation to the GO surface, by using, for example, poly(ethylamine) [ 141 ], poly(lactide-co-glycolide acid) [ 145 ], collagen [ 146 ], phosphates [ 147 ], hydroxyapatite [ 148 ] and silanes [ 149 ].…”

Section: Carbon-based Nanomaterialsmentioning

confidence: 99%

Advances in Biodegradable 3D Printed Scaffolds with Carbon-Based Nanomaterials for Bone Regeneration

et al. 2020

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Bone possesses an inherent capacity to fix itself. However, when a defect larger than a critical size appears, external solutions must be applied. Traditionally, an autograft has been the most used solution in these situations. However, it presents some issues such as donor-site morbidity. In this context, porous biodegradable scaffolds have emerged as an interesting solution. They act as external support for cell growth and degrade when the defect is repaired. For an adequate performance, these scaffolds must meet specific requirements: biocompatibility, interconnected porosity, mechanical properties and biodegradability. To obtain the required porosity, many methods have conventionally been used (e.g., electrospinning, freeze-drying and salt-leaching). However, from the development of additive manufacturing methods a promising solution for this application has been proposed since such methods allow the complete customisation and control of scaffold geometry and porosity. Furthermore, carbon-based nanomaterials present the potential to impart osteoconductivity and antimicrobial properties and reinforce the matrix from a mechanical perspective. These properties make them ideal for use as nanomaterials to improve the properties and performance of scaffolds for bone tissue engineering. This work explores the potential research opportunities and challenges of 3D printed biodegradable composite-based scaffolds containing carbon-based nanomaterials for bone tissue engineering applications.

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<p>Promoting tendon to bone integration using graphene oxide-doped electrospun poly(lactic-co-glycolic acid) nanofibrous membrane</p>

Cited by 44 publications

References 57 publications

High-precision, gelatin-based, hybrid, bilayer scaffolds using melt electro-writing to repair cartilage injury

High-precision, gelatin-based, hybrid, bilayer scaffolds using melt electro-writing to repair cartilage injury

A Synthetic Graft With Multilayered Co-Electrospinning Nanoscaffolds for Bridging Massive Rotator Cuff Tear in a Rat Model

Advances in Biodegradable 3D Printed Scaffolds with Carbon-Based Nanomaterials for Bone Regeneration

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