Small-diameter vascular grafts (SDVGs) are associated with a high incidence of failure due to infection and obstruction. Although several vascular grafts are commercially available, specific anatomical differences of defect sites require patient-based design and fabrication. Design and fabrication of such custom-tailored grafts are possible with 3d-printing technology. The aim of this study is to develop 3d-printed SDVGs with a nitric oxide (NO)-releasing coating to improve the success rate of implantation. The SDVGs were printed from polylactic acid and coated with blending of 10 wt S-nitroso-N-acetyl-D-penicillamine into the polymeric substrate consisting of poly (ethylene glycol) and polycaprolactone. Our results show that NO is released...
Cardiovascular implants must resist thrombosis and intimal hyperplasia, but they are prone to such p...
In bypass graft surgery, surgeons have turned to synthetic materials such as polyethylene terephthal...
Three-dimensional (3D) engineered cardiovascular tissues have shown great promise to replace damaged...
The vascular network has a complex architecture such as branches, curvatures, and bifurcations which...
Thrombogenicity and bacterial infectiveness are the most common complications for foreign blood cont...
Thrombogenicity and bacterial infectiveness are the most common complications for foreign blood cont...
Nitric oxide [NO] is an endogenous gas involved in a multitude of physiological functions, ranging f...
ObjectivesNitric oxide (NO), produced by normal vascular endothelial cells, reduces platelet aggrega...
Over the years, many attempts have been made to increase the patency of small- to medium-sized prost...
Nitric Oxide releasing biopolymers have the potential to prolong vascular graft and stent potency wi...
The integration of bioactive and biomimetic signals into materials for drug delivery and tissue engi...
© 2018 Elsevier Ltd. Due to the limitation of vascular autografts, there is a growing demand to deve...
Nondegradable synthetic polymer vascular grafts used in cardiovascular surgery have shown serious sh...
Our hypothesis was that vascular grafts could be created using three-dimensional (3D) bioprinting te...
The broad clinical use of synthetic vascular grafts for vascular diseases is limited by their thromb...
Cardiovascular implants must resist thrombosis and intimal hyperplasia, but they are prone to such p...
In bypass graft surgery, surgeons have turned to synthetic materials such as polyethylene terephthal...
Three-dimensional (3D) engineered cardiovascular tissues have shown great promise to replace damaged...
The vascular network has a complex architecture such as branches, curvatures, and bifurcations which...
Thrombogenicity and bacterial infectiveness are the most common complications for foreign blood cont...
Thrombogenicity and bacterial infectiveness are the most common complications for foreign blood cont...
Nitric oxide [NO] is an endogenous gas involved in a multitude of physiological functions, ranging f...
ObjectivesNitric oxide (NO), produced by normal vascular endothelial cells, reduces platelet aggrega...
Over the years, many attempts have been made to increase the patency of small- to medium-sized prost...
Nitric Oxide releasing biopolymers have the potential to prolong vascular graft and stent potency wi...
The integration of bioactive and biomimetic signals into materials for drug delivery and tissue engi...
© 2018 Elsevier Ltd. Due to the limitation of vascular autografts, there is a growing demand to deve...
Nondegradable synthetic polymer vascular grafts used in cardiovascular surgery have shown serious sh...
Our hypothesis was that vascular grafts could be created using three-dimensional (3D) bioprinting te...
The broad clinical use of synthetic vascular grafts for vascular diseases is limited by their thromb...
Cardiovascular implants must resist thrombosis and intimal hyperplasia, but they are prone to such p...
In bypass graft surgery, surgeons have turned to synthetic materials such as polyethylene terephthal...
Three-dimensional (3D) engineered cardiovascular tissues have shown great promise to replace damaged...