An Assessment of Blood Vessel Remodeling of Nanofibrous Poly(ε-Caprolactone) Vascular Grafts in a Rat Animal Model (original) (raw)
Related papers
2023
Over the last decade, engineering the polymeric vascular grafs has been extensively studied. Various types of polymers have been used in this feld such as synthetc polymers, natural polymers, and polymer blends. Synthetc polymers, such as Polycaprolactone (PCL), have displayed improved mechanical specifcatons compared to natural polymers. Polycaprolactone is biodegradable polyester that can be blended with another synthetc polymer or a natural polymer to yield even greater enhanced mechanical propertes. The mechanical propertes of artfcial blood vessels play an important role while the vessels are atached to the natve vessels in the animal body. Furthermore, the artfcial blood vessels must be adequately strong to resist frequent blood circulaton and related pressure. The most signifcant advantage of engineered vascular tssue implants is their ability to grow, remodel, rebuild, and respond to injury. This artcle serves as a review of the fabricaton, specifcatons, and benefts of various kinds of polycaprolactone grafs. The primary focus is on the in vivo implantaton of nanofbrous ones for vascular regeneraton in large and small animals. First, the subject of the study was thoroughly investgated, then the search was conducted with a combinaton of index and text terms. Finally, a number of artcles, scientfc books, patents, manuals, and university theses were selected and studied, and the obtained data were analyzed, categorized, and edited. PCL polymer has been the most sought-afer biodegradable polymer for use as a vascular tssue engineering material.
Circulation, 2008
Background— Long-term patency of conventional synthetic grafts is unsatisfactory below a 6-mm internal diameter. Poly(ε-caprolactone) (PCL) is a promising biodegradable polymer with a longer degradation time. We aimed to evaluate in vivo healing and degradation characteristics of small-diameter vascular grafts made of PCL nanofibers compared with expanded polytetrafluoroethylene (ePTFE) grafts. Methods and Results— We prepared 2-mm–internal diameter grafts by electrospinning using PCL (M n =80 000 g/mol). Either PCL (n=15) or ePTFE (n=15) grafts were implanted into 30 rats. Rats were followed up for 24 weeks. At the conclusion of the follow-up period, patency and structural integrity were evaluated by digital subtraction angiography. The abdominal aorta, including the graft, was harvested and investigated under light microscopy. Endothelial coverage, neointima formation, and transmural cellular ingrowth were measured by computed histomorphometry. All animals survived until the end o...
Circulation, 2008
Background— Long-term patency of conventional synthetic grafts is unsatisfactory below a 6-mm internal diameter. Poly(ε-caprolactone) (PCL) is a promising biodegradable polymer with a longer degradation time. We aimed to evaluate in vivo healing and degradation characteristics of small-diameter vascular grafts made of PCL nanofibers compared with expanded polytetrafluoroethylene (ePTFE) grafts. Methods and Results— We prepared 2-mm–internal diameter grafts by electrospinning using PCL (M n =80 000 g/mol). Either PCL (n=15) or ePTFE (n=15) grafts were implanted into 30 rats. Rats were followed up for 24 weeks. At the conclusion of the follow-up period, patency and structural integrity were evaluated by digital subtraction angiography. The abdominal aorta, including the graft, was harvested and investigated under light microscopy. Endothelial coverage, neointima formation, and transmural cellular ingrowth were measured by computed histomorphometry. All animals survived until the end o...
In Vivo Evaluation of PCL Vascular Grafts Implanted in Rat Abdominal Aorta
Polymers
Electrospun tissue-engineered grafts made of biodegradable materials have become a perspective search field in terms of vascular replacement, and more research is required to describe their in vivo transformation. This study aimed to give a detailed observation of hemodynamic and structural properties of electrospun, monolayered poly-ε-caprolactone (PCL) grafts in an in vivo experiment using a rat aorta replacement model at 10, 30, 60 and 90 implantation days. It was shown using ultrasound diagnostic and X-ray tomography that PCL grafts maintain patency throughout the entire follow-up period, without stenosis or thrombosis. Vascular compliance, assessed by the resistance index (RI), remains at the stable level from the 10th to the 90th day. A histological study using hematoxylin-eosin (H&E), von Kossa and Russell–Movat pentachrome staining demonstrated the dynamics of tissue response to the implant. By the 10th day, an endothelial monolayer was forming on the graft luminal surface, ...
International Journal of Basic Science in Medicine
Increasing the cardiovascular diseases and decreasing the possibility of autograft surgery are important factors that cause the choice of artificial vascular graft as an alternative treatment method. In this regard, producing artificial grafts similar to natural vessels is an important purpose that has long been followed as a gold standard by many researchers worldwide. In addition, mechanical properties including strength, long patency, bio-compatibility and hydrophobicity are necessary properties to achieve ideal vascular grafts. Hence there are various factors such as polymer type and preparation methods, which contribute to suitable mechanical properties. The electrospinning as an optimized method on one side and biocompatible, degradable and semicrystalline polycaprolactone (PCL) on the other side are used for their acceptable mechanical properties to manufacture synthetic vessels. In this study, PCL vascular grafts have been reviewed and a wide range of parameters affecting the improvement of mechanical properties and their performance have been described along with clinical applications. Therefore, by investigating and comparing single and composite PCL vascular grafts, we achieved acceptable results in the field of cell growth and adhesion as well as implanting grafts in animals such as rat and rabbit. By reviewing other studies, it was revealed that synthetic composite vessels made of PCL and natural polymers such as collagen and chitosan and synthetic polymers such as polyurethane (PU) for long patency and acceptable cell adhesion have shown good clinical results.
Journal of Biological Engineering
Background The poor performance of conventional techniques used in cardiovascular disease patients requiring hemodialysis or arterial bypass grafting has prompted tissue engineers to search for clinically appropriate off-the-shelf vascular grafts. Most patients with cardiovascular disease lack suitable autologous tissue because of age or previous surgery. Commercially available vascular grafts with diameters of < 5 mm often fail because of thrombosis and intimal hyperplasia. Result Here, we tested tubular biodegradable poly-e-caprolactone/polydioxanone (PCL/PDO) electrospun vascular grafts in a rat model of aortic interposition for up to 12 weeks. The grafts demonstrated excellent patency (100%) confirmed by Doppler Ultrasound, resisted aneurysmal dilation and intimal hyperplasia, and yielded neoarteries largely free of foreign materials. At 12 weeks, the grafts resembled native arteries with confluent endothelium, synchronous pulsation, a contractile smooth muscle layer, and co-...
Journal of biomedical materials research. Part B, Applied biomaterials, 2017
Long-term evaluation of vascular grafts is an essential step to facilitate clinical translation. In this study, we investigate the long-term performance of a macro-porous poly(ɛ-caprolactone) (PCL) electrospun vascular graft using the rat abdominal artery replacement model. Long-term patency, endothelialization, and smooth muscle cell regeneration were evaluated, as well as calcification and degradation. The data showed that all the grafts remained open and unobstructed. There was no evidence of aneurysm, stenosis, or calcification one year after implantation. Importantly, neo-vessel was regenerated on the luminal surface of the graft, and was composed of a complete endothelial layer and several layers of smooth muscle cells. The neo-vessel showed vascular physiological function, although not as good as that in native blood vessels, likely due to the remaining scaffold fibers. These data indicated that the PCL macro-porous electrospun vascular graft has potential to be an artery sub...
Journal of the Mechanical Behavior of Biomedical Materials, 2012
The purpose of this study was to create seamless, acellular, small diameter bioresorbable arterial grafts that attempt to mimic the extracellular matrix and mechanical properties of native artery using synthetic and natural polymers. Silk fibroin, collagen, elastin, and polycaprolactone (PCL) were electrospun to create a tri-layered structure for evaluation. Dynamic compliance testing of the electrospun grafts ranged from 0.4-2.5%/100 mmHg, where saphenous vein (1.5%/100 mmHg) falls within this range. Increasing PCL content caused a gradual decrease in medial layer compliance, while changes in PCL, elastin, and silk content in the adventitial layer had varying affects. Mathematical modeling was used to further characterize these results. Burst strength results ranged from 1614-3500 mmHg, where some exceeded the capacity of the pressure regulator. Four week degradation studies demonstrated no significant changes in compliance or burst strength, indicating that these grafts could withstand the initial physiological conditions without risk of degradation. Overall, we were able to manufacture a multi-layered graft that architecturally mimics the native vascular wall and mechanically matches the gold standard of vessel replacement, saphenous vein.