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.
The development of vascular bioengineering has led to a variety of novel treatment strategies for patients with cardiovascular disease. Notably, combining biodegradable scaffolds with autologous cell seeding to create tissue-engineered vascular grafts (TEVG) allows for in situ formation of organized neovascular tissue and we have demonstrated the clinical viability of this technique in patients with congenital heart defects. The role of the scaffold is to provide a temporary 3-dimensional structure for cells, but applying TEVG strategy to the arterial system requires scaffolds that can also endure arterial pressure. Both biodegradable synthetic polymers and extracellular matrixbased natural materials can be used to generate arterial scaffolds that satisfy these requirements. Furthermore, the role of specific cell types in tissue remodeling is crucial and as a result many different cell sources, from matured somatic cells to stem cells, are now used in a variety of arterial TEVG techniques. However, despite great progress in the field over the past decade, clinical effectiveness of small-diameter arterial TEVG (<6 mm) has remained elusive. To achieve successful translation of this complex multidisciplinary technology to the clinic, active participation of biologists, engineers, and clinicians is required. (Circ J 2014; 78: 12 -19)
Objective Tissue engineering techniques have emerged that allow bioresorbable grafts to be implanted that restore function and transform into biologically active arteries. However, these implants are susceptible to calcification during the remodeling process. The objective of this study was to evaluate the role of pore size of bioabsorbable grafts in the development of calcification. Methods Two types of grafts were prepared: a large-pore graft constructed of poly(l-lactic acid) (PLA) fibers coated with poly(l-lactide-co-ε-caprolactone) (PLCL) (PLA-PLCL), and a small-pore graft made of electrospun PLA nanofibers (PLA-nano). Twenty-eight PLA-PLCL grafts and twenty-five PLA-nano grafts were implanted as infra-renal aortic interposition conduits in 8-week-old female SCID/Bg mice, and followed for 12 months after implantation. Results Large-pore PLA-PLCL grafts induced a well-organized neointima after 12 months, and Alizarin Red S staining showed neointimal calcification only in the thin neointima of small-pore PLA-nano grafts. At 12 months, macrophage infiltration, evaluated by F4/80 staining, was observed in the thin neointima of the PLA-nano graft, and there were few vascular smooth muscle cells (VSMCs) in this layer. On the other hand, the neointima of the PLA-PLCL graft was composed of abundant VSMCs, and a lower density of macrophages (F4/80 positive cells, PLA-PLCL; 68.1±41.4/mm2 vs PLA-nano; 188.3±41.9/mm2, p = 0.007). The VSMCs of PLA-PLCL graft expressed transcription factors of both osteoblasts and osteoclasts. Conclusion These findings demonstrate that in mouse arterial circulation, large-pore PLA-PLCL grafts created a well-organized neointima and prevented calcific deposition compared to small-pore, electrospun PLA-nano grafts.
In this study, we demonstrated well-organized neotissue of cell-free biodegradable arterial grafts. Although most grafts experienced aneurysmal change, such findings provide insight into the process of tissue-engineered vascular graft remodeling and should allow informed rational design of the next generation of arterial grafts.
Vascular Tissue Engineering belongs to a rapidly expanding discipline. Tissue engineered vascular grafts (TEVG) have a broad range of clinical application extending from use as small diameter vascular grafts in adult peripheral vasculature to serving as large vessel conduits in pediatric cardiovascular surgery. Several approaches have been utilized by different groups to design these grafts. Preliminary outcomes are exceedingly promising. These grafts have demonstrated the ability to transform into living blood vessels with growth potential and while the underlying mechanisms remain to be elucidated, it has been shown that inflammatory pathways may play an important role. Small animal experiments, development of cell seeding techniques and the application of nanotechnology have all contributed vastly to our understanding of the mechanisms involved in TEVG remodeling. The application of nanomedicine in TEVG design continues to expand at a rapid rate and has provided some clues as to how vascular graft design can be pursued in the future. In this review we discuss the current state of the field of tissue engineered vascular grafts and how the principles of nanomedicine are being applied to aid in the design of second-generation grafts.
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