Cameron Best scite author profile

There is great clinical demand for synthetic vascular grafts with improved long-term efficacy. The ideal vascular conduit is easily implanted, nonthrombogenic, biocompatible, resists aneurysmal dilatation, and ultimately degrades or is assimilated as the patient remodels the graft into tissue resembling native vessel. The field of vascular tissue engineering offers an opportunity to design the ideal synthetic graft, and researchers have evaluated a variety of methods and materials for use in graft construction. Electrospinning is one method that has received considerable attention within tissue engineering for constructing so-called tissue scaffolds. Tissue scaffolds are temporary, porous structures which are commonly composed of bioresorbable polymers that promote native tissue ingrowth and have degradation kinetics compatible with a patient's rate of extracellular matrix production in order to successfully transit from synthetic conduits into neovessels. In this review, we summarize the history of tissue-engineered vascular grafts (TEVG), focusing on scaffolds generated by the electrospinning process, and discuss in vivo applications. We review the materials commonly employed in this approach and the preliminary results after implantation in animal models in order to gauge clinical viability of the electrospinning process for TEVG construction. Scientists have studied electrospinning technology for decades, but only recently has it been orthotopically evaluated in animal models such as TEVG. Advantages of electrospun TEVG include ease of construction, favorable cellular interactions, control of scaffold features such as fiber diameter and pore size, and the ability to choose from a variety of polymers possessing a range of mechanical and chemical properties and degradation kinetics. Given its advantages, electrospinning technology merits investigation for use in TEVG, but an emphasis on long-term in vivo evaluation is required before its role in clinical vascular tissue engineering can be realized.

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Tissue-Engineered Small Diameter Arterial Vascular Grafts from Cell-Free Nanofiber PCL/Chitosan Scaffolds in a Sheep Model

Fukunishi

et al. 2016

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Tissue engineered vascular grafts (TEVGs) have the potential to overcome the issues faced by existing small diameter prosthetic grafts by providing a biodegradable scaffold where the patient’s own cells can engraft and form functional neotissue. However, applying classical approaches to create arterial TEVGs using slow degrading materials with supraphysiological mechanical properties, typically results in limited host cell infiltration, poor remodeling, stenosis, and calcification. The purpose of this study is to evaluate the feasibility of novel small diameter arterial TEVGs created using fast degrading material. A 1.0mm and 5.0mm diameter TEVGs were fabricated with electrospun polycaprolactone (PCL) and chitosan (CS) blend nanofibers. The 1.0mm TEVGs were implanted in mice (n = 3) as an unseeded infrarenal abdominal aorta interposition conduit., The 5.0mm TEVGs were implanted in sheep (n = 6) as an unseeded carotid artery (CA) interposition conduit. Mice were followed with ultrasound and sacrificed at 6 months. All 1.0mm TEVGs remained patent without evidence of thrombosis or aneurysm formation. Based on small animal outcomes, sheep were followed with ultrasound and sacrificed at 6 months for histological and mechanical analysis. There was no aneurysm formation or calcification in the TEVGs. 4 out of 6 grafts (67%) were patent. After 6 months in vivo, 9.1 ± 5.4% remained of the original scaffold. Histological analysis of patent grafts demonstrated deposition of extracellular matrix constituents including elastin and collagen production, as well as endothelialization and organized contractile smooth muscle cells, similar to that of native CA. The mechanical properties of TEVGs were comparable to native CA. There was a significant positive correlation between TEVG wall thickness and CD68+ macrophage infiltration into the scaffold (R2 = 0.95, p = 0.001). The fast degradation of CS in our novel TEVG promoted excellent cellular infiltration and neotissue formation without calcification or aneurysm. Modulating host macrophage infiltration into the scaffold is a key to reducing excessive neotissue formation and stenosis.

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Vascular tissue engineering: the next generation

Cleary

Geiger

Grady

et al. 2012

Trends in Molecular Medicine

136

103

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3D‐Printed Biodegradable Polymeric Vascular Grafts

Melchiorri

Hibino

Best

et al. 2015

Adv Healthcare Materials

143

107

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Although several strategies to three-dimensionally print cardiovascular grafts exist, these technologies either have required extensive culturing of cells on scaffolds prior to implantation to impart mechanical stability, necessitate additional fabricated components after 3D printing, or have not been proven in vivo. Here, we demonstrate a material and methodology utilizing digital stereolithography for the fabrication of non-cellular biodegradable polymeric vascular grafts. Using this approach, we show, for the first time, the functionality of a 3D printed vascular graft in vivo as an inferior vena cava conduit interposition graft. Our 3D printing materials and methodology should provide a platform for future efforts to fabricate wholly 3D printed, custom-tailored cardiovascular grafts. Such a platform will also enable the precise control over both macroscale—like curvature and bifurcations—and microscale features—like porosity and surface roughness—to improve the performance and integration of these patient-specific vascular scaffolds.

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Spontaneous reversal of stenosis in tissue-engineered vascular grafts

et al. 2020

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We developed a tissue-engineered vascular graft (TEVG) for use in children and present results of a U.S. Food and Drug Administration (FDA)–approved clinical trial evaluating this graft in patients with single-ventricle cardiac anomalies. The TEVG was used as a Fontan conduit to connect the inferior vena cava and pulmonary artery, but a high incidence of graft narrowing manifested within the first 6 months, which was treated successfully with angioplasty. To elucidate mechanisms underlying this early stenosis, we used a data-informed, computational model to perform in silico parametric studies of TEVG development. The simulations predicted early stenosis as observed in our clinical trial but suggested further that such narrowing could reverse spontaneously through an inflammation-driven, mechano-mediated mechanism. We tested this unexpected, model-generated hypothesis by implanting TEVGs in an ovine inferior vena cava interposition graft model, which confirmed the prediction that TEVG stenosis resolved spontaneously and was typically well tolerated. These findings have important implications for our translational research because they suggest that angioplasty may be safely avoided in patients with asymptomatic early stenosis, although there will remain a need for appropriate medical monitoring. The simulations further predicted that the degree of reversible narrowing can be mitigated by altering the scaffold design to attenuate early inflammation and increase mechano-sensing by the synthetic cells, thus suggesting a new paradigm for optimizing next-generation TEVGs. We submit that there is considerable translational advantage to combined computational-experimental studies when designing cutting-edge technologies and their clinical management.

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Cameron Best

In VivoApplications of Electrospun Tissue-Engineered Vascular Grafts: A Review

Tissue-Engineered Small Diameter Arterial Vascular Grafts from Cell-Free Nanofiber PCL/Chitosan Scaffolds in a Sheep Model

Vascular tissue engineering: the next generation

3D‐Printed Biodegradable Polymeric Vascular Grafts

Spontaneous reversal of stenosis in tissue-engineered vascular grafts

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