The in vivo performance of small-caliber nanofibrous polyurethane vascular grafts

Hu, Zhiqiang; Li, Zilun; Hu, Lingyu; He, Wei; Liu, Ruiming; Qin, Yuansen; Wang, Shenming

doi:10.1186/1471-2261-12-115

Cited by 29 publications

(23 citation statements)

References 22 publications

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“…Additionally, a functioning endothelium shields the underlying smooth muscle cells from factors in the blood stream and locally produces antiproliferative agents . In recent years, polyurethane grafts have shown promise in this space due to their more acceptable mechanical properties when compared to native vasculature …”

Section: Polymeric Biomaterials That Promote Endothelializationmentioning

confidence: 99%

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Promoting Endothelialization of Polymeric Cardiovascular Biomaterials

Heath

2017

Macro Chemistry & Physics

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The lack of a blood compatible synthetic interface is one of the largest unaddressed challenges in the field of biomaterials science. This technological shortcoming hinders the successful clinical application of small diameter vascular grafts and other cardiovascular devices such as stents and artificial heart valves. Therefore, intensive research activities are ongoing to develop polymer materials with improved blood compatibility. One attractive strategy to improve the blood compatibility of an interface is to design surfaces that promote the development of an endothelium, the monolayer of endothelial cells that line our native vasculature and is responsible for blood compatibility. This article describes the recent strategies that have been used to generate polymeric materials that promote the development of an endothelium, discusses shortcomings in the field, and proposes future directions of research that can be undertaken to design next generation polymeric biomaterial that promote endothelialization.

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Section: Polymeric Biomaterials That Promote Endothelializationmentioning

confidence: 99%

“…[14] In recent years, polyurethane grafts have shown promise in this space due to their more acceptable mechanical properties when compared to native vasculature. [34,35]…”

Section: Substrate Stiffnessmentioning

confidence: 99%

Promoting Endothelialization of Polymeric Cardiovascular Biomaterials

Heath

2017

Macro Chemistry & Physics

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“…PUR, due to their excellent hemocompatibility well-established as scaffold materials for vascular grafts [26][27][28][29], can be synthesized by a stepwise addition reaction, therefore called step-growth polymerization, between isocyanate and alcohol bifunctional monomers. In addition to the mentioned polyaddition and as a further type of step-growth polymerizations polycondensation reactions are generally used for the synthesis of polyesters.…”

Section: Synthetic and Natural Polymersmentioning

confidence: 99%

Polymers in Cardiology

Sternberg¹,

Busch

Petersen

2014

Advanced Polymers in Medicine

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Polymers have found widespread applications in cardiology, in particular in coronary vascular intervention as stent platforms, coating matrices for drug-eluting stents (DES) and drug-coated balloons (DCB) and for transcatheter valve therapy. Besides permanent polymers, biodegradable polymers came in focus of current research and development for medical applications, as they degrade once their function is fulfilled, which might efficiently reduce observed hypersensitivity reactions. After reviewing polymers used for cardiovascular applications, the book chapter deals with possible surface modification reactions of the polymers including the provision with a local drug delivery function and/ or biofunctionalization in order to selectively control cell-implant interactions. These functionalizations can be furthermore designed to enhance bio-and hemocompatibility, which is of special interest for cardiovascular implants and devices. A general discussion of bio-and hemo-compatibility of polymers for cardiovascular applications and corresponding evaluation methods is additionally given. With our own published data, we finally highlight exemplary polymer applications in cardiology as polymer-based biodegradable stent platforms, biodegradable polymeric coatings for DES and hydrogel-based coatings for DCB. Moreover, developed biofunctionalization strategies of polymers are discussed with regard to their application in cardiology.

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“…Electrospun polyurethane (ePU) has emerged as a possible substitute to ePTFE for vascular grafts (Hu et al 2012). Since ePU can be manufactured over a large range of mechanical properties (Montini-Ballarin et al 2016), resulting grafts can be tuned to better match the mechanical properties of native veins, thereby minimising graft-vein compliance mismatch.…”

mentioning

confidence: 99%

“…Since ePU can be manufactured over a large range of mechanical properties (Montini-Ballarin et al 2016), resulting grafts can be tuned to better match the mechanical properties of native veins, thereby minimising graft-vein compliance mismatch. Furthermore, since the grafts are spun, they exhibit a fibrous structure that closely resembles native extracellular matrix (Hu et al 2012). This structure allows for better graft endothelialisation compared to ePTFE grafts, which enhances the graft's biocompatibility (Hu et al 2012).…”

mentioning

confidence: 99%

Computational study on the haemodynamic and mechanical performance of electrospun polyurethane dialysis grafts

Quicken

Bruin

Mees

et al. 2019

Biomech Model Mechanobiol

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Compliance mismatch between an arteriovenous dialysis graft (AVG) and the connected vein is believed to result in disturbed haemodynamics around the graft-vein anastomosis and increased mechanical loading of the vein. Both phenomena are associated with neointimal hyperplasia development, which is the main reason for AVG patency loss. In this study, we use a patient-specific fluid structure interaction AVG model to assess whether AVG haemodynamics and mechanical loading can be optimised by using novel electrospun polyurethane (ePU) grafts, since their compliance can be better tuned to match that of the native veins, compared to gold standard, expanded polytetrafluoroethylene (ePTFE) grafts. It was observed that the magnitude of flow disturbances in the vein and the size of anastomotic areas exposed to highly oscillatory shear (OSI > 0.25) and very high wall shear stress (> 40 Pa) were largest for the ePTFE graft. Median strain and von Mises stress in the vein were similar for both graft types, whereas highest stress and strain were observed in the anastomosis of the ePU graft. Since haemodynamics were most favourable for the ePU graft simulation, AVG longevity might be improved by the use of ePU grafts.

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The in vivo performance of small-caliber nanofibrous polyurethane vascular grafts

Cited by 29 publications

References 22 publications

Promoting Endothelialization of Polymeric Cardiovascular Biomaterials

Promoting Endothelialization of Polymeric Cardiovascular Biomaterials

Polymers in Cardiology

Computational study on the haemodynamic and mechanical performance of electrospun polyurethane dialysis grafts

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