1 January 2021
Designer blood vessels for treating cardiovascular diseases
Cardiovascular diseases, such as coronary heart disease, are the largest cause of death worldwide, now and in the coming decade. The financial impact on society and our healthcare system is huge, since current treatments are less than optimal. A common treatment option for cardiovascular diseases is to replace the damaged blood vessel with a synthetic graft. However, this approach often fails due to uncontrolled tissue growth in the problematic area. A precisely designed blood vessel that fits the patient at a cellular scale will prevent long-term complications that currently trouble the use of a synthetic graft.
Designed to mimic native blood vessels
The currently used vascular grafts are significantly different from the native blood vessels found in the human body. In particular, these grafts lack the complex structural and mechanical characteristics of blood vessels, which from biological point of view are essential for a proper functioning. In other words, design is a missing link and may be a key factor in the development of successful cardiovascular solutions.
Recent technological advances in the fabrication of biologically-compatible materials, in particular by using cuttingedge 3D printing technologies, offer opportunities for grafts with precisely designed and controlled architectures at the (sub-)micrometer scale – smaller than the size of a human cell. A rational design of the graft structure at such small scale prior to its implantation, will make it possible to direct the biological processes in the body and thereby to replicate the complexity and functionality of the living blood vessels. This innovative idea is exactly what will be explored in the project “Advaessel: Advanced materials processing and design for regenerating blood vessels”.
Bring the design to the patient
The project proposes a multidisciplinary collaboration of experts in the Netherlands and Europe in the fields of advanced material design and processing, vascular biology, and tissue engineering. Furthermore, the team will engage enterprises and a national network of clinical partners and medical advisors to ensure a smooth translation to the end users. The outcome is expected to make a leap into a new generation of functional, fully resorb-able implants for cardiovascular applications.