Development of a vascular substitute produced by weaving yarn made from human amniotic membrane

Grémare, Agathe; Thibes, Lisa; Gluais, Maude; Torres, Yoann; Potart, Diane; Silva, Nicolas Da; Dusserre, Nathalie; Fénelon, Mathilde; Senthilhes, Loïc; Lacomme, Sabrina; Svahn, Isabelle; Gontier, Étienne; Fricain, Jean-Christophe; L’Heureux, Nicolas

doi:10.1088/1758-5090/ac84ae

Cited by 7 publications

(14 citation statements)

References 59 publications

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“…Mechanical mismatch between a vascular graft and the host artery is considered as an important cause of intimal hyperplasia, which is a major cause of graft failure [21,[23][24][25][26]39]. Our group recently published two studies in which TEVGs were woven either from CAM or human amniotic membrane threads [29,40]. Both grafts displayed burst pressure, suture retention strength, and transmural permeability that would support implantation, but would create a mechanical mismatch with native blood vessels.…”

Section: Discussionmentioning

confidence: 99%

“…Both grafts displayed burst pressure, suture retention strength, and transmural permeability that would support implantation, but would create a mechanical mismatch with native blood vessels. In the amniotic membrane study, high transmural permeability was reduced by using wider threads [40]. In the current study, we took advantage of the versatility of textile assembly to better understand how to control the overall properties of our woven CAM-based TEVG.…”

Section: Discussionmentioning

confidence: 99%

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Effects of weaving parameters on the properties of completely biological tissue-engineered vascular grafts

Roudier,

Hourques,

Da Silva

et al. 2023

Biofabrication

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Tissue-Engineered Vascular Grafts (TEVGs) made of human textiles have been recently introduced and offer remarkable biocompatibility as well as tunable mechanical properties. The approach combines the use of Cell-Assembled extracellular Matrix (CAM) threads, produced by cultured cells in vitro, with weaving, a versatile assembly method that gives fine control over graft properties. Herein, we investigated how production parameters can modify the geometrical and mechanical properties of TEVGs to better match that of native blood vessels in order to provide long-term patency. Our goals were to decrease the mechanical strength and the luminal surface profile of our first generation of woven TEVGs, while maintaining low transmural permeability and good suture retention strength.Different TEVGs were produced by varying CAM sheet strength as well as weaving parameters such as warp count, weft ribbons width, and weft tension. An optimized design reduced the burst pressure by 35%, wall thickness by 38% and increased compliance by 269%. The improved TEVG had properties closer to that of native blood vessels, with a burst pressure of 3492 mmHg, a wall thickness of 0.69 mm, and a compliance of 4.8%/100 mmHg, while keeping excellent suture retention strength (4.7 N) and low transmural permeability (24 mL·min-1·cm-2). Moreover, the new design reduced the luminal surface profile by 48% and utilized 47% less CAM. With a comparable design, the use of decellularized CAM threads, instead of devitalized ones, led to TEVGs with much more permeable walls and higher burst pressure.The next step is to implant this optimized graft in an allogeneic sheep model of arteriovenous shunt to assess its in vivo remodeling and performance.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Effects of weaving parameters on the properties of completely biological tissue-engineered vascular grafts

Roudier,

Hourques,

Da Silva

et al. 2023

Biofabrication

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“…This will allow evaluation of the effectiveness of the woven CAMbased TEVGs in a clinically relevant allogeneic context for long-term studies in large animals to justify translation to humans. A recent approach to produce human woven TEVG, which is more economical, uses biological yarns made from human amniotic membranes [98].…”

Section: Completely Biological Textile Approachesmentioning

confidence: 99%

Current biofabrication methods for vascular tissue engineering and an introduction to biological textiles

Kawecki

L’Heureux

2023

Biofabrication

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Cardiovascular diseases are the leading cause of mortality in the world and encompass several important pathologies, including atherosclerosis. In the cases of severe vessel occlusion, surgical intervention using bypass grafts may be required. Synthetic vascular grafts provide poor patency for small diameter applications (< 6 mm) but are widely used for hemodialysis access and, with success, larger vessel repairs. In very small vessels, such as coronary arteries, synthetics outcomes are unacceptable, leading to the exclusive use of autologous (native) vessels despite their limited availability and, sometimes, quality. Consequently, there is a clear clinical need for a small-diameter vascular graft that can provide outcomes similar to native vessels. Many tissue-engineering approaches have been developed to offer native-like tissues with the appropriate mechanical and biological properties in order to overcome the limitations of synthetic and autologous grafts. This review overviews current scaffold-based and scaffold-free approaches developed to biofabricate tissue-engineered vascular grafts (TEVGs) with an introduction to the biological textile approaches. Indeed, these assembly methods show a reduced production time compared to processes that require long bioreactor-based maturation steps. Another advantage of the textile-inspired approaches is that they can provide better directional and regional control of the TEVG mechanical properties.

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“…Cross-section of CAM ribbons was evaluated as previously described with biaxial laser micrometer [ 15 ]. Then, ribbons extremities were clamped between the flat jaws of a tensile test apparatus (100N load cell, AGSX, Shimadzu), pre-loaded (to 0.05 N, 20 mm/min), and stretch (to breaking point, at a speed of 1% of sec of the initial length (L0) of the sample after preloading.…”

Section: Mechanical Testingmentioning

confidence: 99%

The cell-assembled extracellular matrix: A focus on the storage stability and terminal sterilization of this human “bio” material

Potart

Gluais

Gaubert³

et al. 2023

Acta Biomaterialia

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Development of a vascular substitute produced by weaving yarn made from human amniotic membrane

Cited by 7 publications

References 59 publications

Effects of weaving parameters on the properties of completely biological tissue-engineered vascular grafts

Effects of weaving parameters on the properties of completely biological tissue-engineered vascular grafts

Current biofabrication methods for vascular tissue engineering and an introduction to biological textiles

The cell-assembled extracellular matrix: A focus on the storage stability and terminal sterilization of this human “bio” material

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