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The research group in Biomaterials, Biomechanics and Tissue Engineering (BBT) and the Center for Research in Multiscale Science and Engineering (CCEM) at the Universitat Politècnica de Catalunya – BarcelonaTech (UPC) have developed biodegradable shape-memory stents for pediatric patients with aortic coarctation.
Aortic coarctation, a narrowing of the aorta, accounts for between 4% and 6% of all congenital heart diseases. It is a highly heterogeneous condition that often coexists with other cardiac abnormalities. Some patients may remain asymptomatic for years; however, when the narrowing is severe, hypertension, headaches, chest pain and muscle weakness may appear. If left untreated, the mortality rate reaches 90% by the age of 50, which is why addressing this condition during childhood is essential.
Current clinical treatments are based on two main strategies. The first is open-heart surgery, in which the narrowed aortic segment is removed. The second, less invasive option consists of balloon angioplasty and the implantation of a permanent metallic endovascular stent, initially designed for adults. In pediatrics, these stents are progressively fractured by surgeons as the aorta increases in diameter with the patient’s growth. Although mortality is below 1–2%, neither option is free from long-term complications —60% of which are cardiovascular in nature— such as aneurysms, aortic ruptures, dissections, arrhythmias, hypertension or recoarctation. Moreover, reinterventions continue to be frequent during growth and remain a clinical challenge.
To address these limitations, an innovative solution has been developed based on smart stents capable of adapting to the natural expansion of the aorta during childhood. The approach focuses on the development of polymeric, resorbable, shape-memory stents (SMP), manufactured using 3D printing and designed for minimally invasive surgery. This device, activated by body temperature, is biodegradable and designed to restore aortic functionality without leaving obstructive residues. If clinicians need to implant a new stent after 3–4 years, no remnants of the original device will remain. In addition, 3D printing technologies applied to smart devices —known as 4D printing— allow precise customisation to meet the specific needs of each patient.
Impact
The main outcome of this project is the protection of intellectual property, through a patent (PCTEP2025070937), for a new family of resorbable stents that reduce complications, minimise reinterventions and maintain long-term aortic patency, while enabling the continuous refinement of their development. Furthermore, a market study has been carried out, highlighting the technology’s potential and reinforcing both its viability and its market transfer potential to other applications, such as peripheral vascular diseases, providing support in areas like the femoral arteries, as well as paediatric pulmonary stenosis.
Partners and Funding
The project had a budget of € 20,000 funded by the Agència de Gestió d’Ajuts Universitaris i de Recerca (AGAUR) of the Government of Catalonia and lasted six months (from February to July 2024).
Related Projects
- The Image and Video Processing Group (GPI), part of the IDEAI-UPC research group, and the Digital Culture and Creative Technologies Research Group (DiCode) from the Image Processing and Multimedia Technology Center (CITM) at the Universitat Politècnica de Catalunya – BarcelonaTech (UPC), have co-organised the AI and Music Festival (S+T+ARTS) together with Sónar+D and Betevé, to explore the creative use of artificial intelligence in music.
- The Visualisation, Virtual Reality and Graphic Interaction Research Group (ViRVIG) at the Universitat Politècnica de Catalunya - BarcelonaTech (UPC) has participated in the XR4ED project, an initiative that connects the educational technology (EdTech) and Extended Reality (XR) sectors, with the aim of transforming learning and training across Europe.
- The inLab FIB at the UPC has collaborated with Lizcore® for the development of a proof of concept based on artificial intelligence to improve safety in climbing with autobelay devices. The system allows the automatic and accurate detection of risk situations before starting a route.
- Researchers from the Centre for Image and Multimedia Technology of the UPC (CITM) and from the DiCode research group (Digital Culture and Creative Technologies Research Group) of the Universitat Politècnica de Catalunya – BarcelonaTech (UPC) have worked on the project The Eyes of History, an initiative of the Catalan Agency for Cultural Heritage that offers an immersive view of Catalan cultural heritage. It is especially aimed at the first and second cycles of secondary education and was created to bring heritage into the classroom. Its goal is to bring the history and monuments of Catalonia closer in a vivid and innovative way, using tools such as virtual reality and new museographic narratives.
