Engineering hybrid textile braids for tendon and ligament repair application

Peixoto, Tânia; Carneiro, Sofia M.; Fangueiro, Raúl; Guedes, Rui Miranda; Paiva, Maria C.; Lopes, M. A.

doi:10.1002/app.52013

Cited by 6 publications

(10 citation statements)

References 72 publications

(133 reference statements)

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“…27 Our group has previously described the production of individual braids made from PET and PLA multifilament yarns, where various PET:PLA compositions were tested. 28 The present work proposes a medical device based on the compositions that had previously presented the most promising mechanical properties. For that, different braids were used as elementary parts and gathered into intricate constructs that mimic the fibrous architecture and tensile mechanical behavior of the native tissue.…”

Section: Resultsmentioning

confidence: 99%

Hybrid structures for Achilles' tendon repair

Peixoto

Carneiro

Pereira

et al. 2022

Polymers for Advanced Techs

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The management of extensive tendon injuries poses a considerable challenge. These cases typically require a partial replacement of the tissue, and conventional treatment options, either grafts or synthetic constructs, present disadvantages. Synthetic constructs may be produced with either non-biodegradable or biodegradable polymers. However, while the former lacks biointegration, the latter requires a compromise between tissue ingrowth and biodegradability, frequently malfunctioning due to inadequate mechanical properties. The present work presents a textile medical device designed to repair the Achilles tendon (AT). This device is based on a core/shell design that mimics the multiscale organization of the native tissue. The core comprises several hybrid braids based on poly(ethylene terephthalate) (PET) and poly(lactic acid) (PLA) yarns, and the shell consists on braided PET yarns surrounding the core. Different PET/PLA compositions of the core braids were studied to optimize biodegradability without compromising mechanical performance. The morphology and mechanical properties of the structures were studied. The hybrid structures presented a non-linear force-strain curve comparable to a representative curve described for a native tendon. A decrease in force and stiffness was observed as the PLA content in the structure increased. Nevertheless, the obtained values for the hybrid structures are promising for AT replacement. Besides, these hybrid structures demonstrated appropriate resistance to cyclic loading and a beneficial creep behavior. The results obtained in the present work fall within the range of values reported for the native AT.

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Section: Resultsmentioning

confidence: 99%

Hybrid structures for Achilles' tendon repair

Peixoto

Carneiro

Pereira

et al. 2022

Polymers for Advanced Techs

Self Cite

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“…An innovative medical device produced from hybrid textile braids based on PET and PLA yarns was developed in a previous work. [8,9] The designed device presents a core-shell architecture (several hybrid braids surrounded by an exterior shell of braided PET yarns) that mimics the hierarchical morphological features and fulfills the high mechanical demands of tissues such as tendons and ligaments. During the first phase of the repair process, the non-degradable component (PET) protects the cells and newly formed tissue from excessive strains by withstanding physiological loads and providing mechanical support, allowing the body's natural healing process to take place.…”

Section: Resultsmentioning

confidence: 99%

“…Hybrid braids with a higher PET to PLA ratio demonstrated suitable mechanical properties for the intended purpose. [8,9] As such, the primary purpose of this work was to surface modify the PET yarns, which are present in higher number in the hybrid medical device. PLA was also functionalized to evaluate the impact of the surface modification process on the performance of the hybrid medical device.…”

Section: Resultsmentioning

confidence: 99%

Amination of Polymeric Braid Structures to Improve Tendon Healing: An Experimental Comparison

Peixoto

Silva

Rodrigues

et al. 2022

Macro Materials & Eng

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Several polymers are researched for tendon repair as polyethylene terephthalate (PET) and polylactic acid (PLA). These are biocompatible and useful in scaffolding repair though with minimal success due to long-term failure. There is a need to improve such scaffolds' design and physical-chemical nature. This work concerns surface functionalization of polymeric braids (PET and PLA) that fulfill the high mechanical demands of tissues such as tendons. The functionalization aims to incorporate amine groups in the braids' surface, improve cell adhesion, and consequently, the poor healing rate of these tissues and the biointegration of the braids. Two approaches are compared: the direct application of NH 3 plasma and the surface grafting of EDA after O 2 plasma activation. X-ray photoelectron spectroscopy (XPS) shows that amine groups are effectively introduced onto the samples' surfaces. Besides, the plasma parameters chosen do not compromise the topography and tensile behavior of the braids. Resazurin assay and scanning electron microscopy show that the NH 3 treatment improves cell-biomaterial interaction as improved cell adhesion and proliferation are observed. Both approaches are safe for biomedical applications. The NH 3 plasma approach is more environmentally friendly, faster, and easier to scale-up, showing potential for application in the final hybrid medical device.

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“…Tendons are responsible for transferring forces from muscle to bone and are critical for joint mobility and stability [ 65 ]. Overall, tendons have a low capacity to heal, primarily due to a lack of blood supply.…”

Section: Tissue Typesmentioning

confidence: 99%

“…The current gold standard of treatment following tendon injury involves surgery which may include suturing the ends of the ruptured tissue. In more complex cases, inclusion of a tendon graft may be required to provide a base material to initiate repair [ 65 ]. These treatment options possess disadvantages including insufficient mechanical stability, as well as a risk of graft failure [ 69 ].…”

Section: Tissue Typesmentioning

confidence: 99%

Current Concepts and Methods in Tissue Interface Scaffold Fabrication

2022

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Damage caused by disease or trauma often leads to multi-tissue damage which is both painful and expensive for the patient. Despite the common occurrence of such injuries, reconstruction can be incredibly challenging and often may focus on a single tissue, which has been damaged to a greater extent, rather than the environment as a whole. Tissue engineering offers an approach to encourage repair, replacement, and regeneration using scaffolds, biomaterials and bioactive factors. However, there are many advantages to creating a combined scaffold fabrication method approach that incorporates the treatment and regeneration of multiple tissue types simultaneously. This review provides a guide to combining multiple tissue-engineered scaffold fabrication methods to span several tissue types concurrently. Briefly, a background in the healing and composition of typical tissues targeted in scaffold fabrication is provided. Then, common tissue-engineered scaffold fabrication methods are highlighted, specifically focusing on porosity, mechanical integrity, and practicality for clinical application. Finally, an overview of commonly used scaffold biomaterials and additives is provided, and current research in combining multiple scaffold fabrication techniques is discussed. Overall, this review will serve to bridge the critical gap in knowledge pertaining to combining different fabrication methods for tissue regeneration without disrupting structural integrity and biomaterial properties.

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Engineering hybrid textile braids for tendon and ligament repair application

Cited by 6 publications

References 72 publications

Hybrid structures for Achilles' tendon repair

Hybrid structures for Achilles' tendon repair

Amination of Polymeric Braid Structures to Improve Tendon Healing: An Experimental Comparison

Current Concepts and Methods in Tissue Interface Scaffold Fabrication

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