Current biofabrication methods for vascular tissue engineering and an introduction to biological textiles.
Fabien KaweckiNicolas L'HeureuxPublished in: Biofabrication (2023)
Cardiovascular diseases are the leading cause of mortality in the world and encompass several important pathologies, including atherosclerosis. In the cases of severe vessel occlusion, surgical intervention using bypass grafts may be required. Synthetic vascular grafts provide poor patency for small-diameter applications (< 6 mm) but are widely used for hemodialysis access and, with success, larger vessel repairs. In very small vessels, such as coronary arteries, synthetics outcomes are unacceptable, leading to the exclusive use of autologous (native) vessels despite their limited availability and, sometimes, quality. Consequently, there is a clear clinical need for a small-diameter vascular graft that can provide outcomes similar to native vessels. Many tissue-engineering approaches have been developed to offer native-like tissues with the appropriate mechanical and biological properties in order to overcome the limitations of synthetic and autologous grafts. This review overviews current scaffold-based and scaffold-free approaches developed to biofabricate tissue-engineered vascular grafts (TEVGs) with an introduction to the biological textile approaches. Indeed, these assembly methods show a reduced production time compared to processes that require long bioreactor-based maturation steps. Another advantage of the textile-inspired approaches is that they can provide better directional and regional control of the TEVG mechanical properties.
Keyphrases
- tissue engineering
- cardiovascular disease
- wastewater treatment
- randomized controlled trial
- bone marrow
- cell therapy
- gene expression
- coronary artery disease
- coronary artery
- chronic kidney disease
- cardiovascular events
- stem cells
- quality improvement
- optic nerve
- risk factors
- platelet rich plasma
- aortic valve
- end stage renal disease
- glycemic control