Double-crosslinked dECM bioink to print a self-sustaining 3D multi-layered aortic-like construct

Cardiovascular disease is the leading cause of death worldwide, with related mortality increasing from 12.1 million to 18.6 million in the past 30 years. To address the supply limitation of autologous vascular grafts and overcome the limits of current treatment options, 3D bioprinting techniques hav...

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Bibliographic Details
Published in:Bioprinting (Amsterdam, Netherlands) Netherlands), 2024-12, Vol.44, p.e00368, Article e00368
Main Authors: Potere, Federica, Venturelli, Giovanni, Belgio, Beatrice, Guagliano, Giuseppe, Boschetti, Federica, Mantero, Sara, Petrini, Paola
Format: Article
Language:English
Subjects:
3D bioprinting
Biofabrication
Bioink
Blood vessels
Decellularization
Extracellular matrix
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Summary:Cardiovascular disease is the leading cause of death worldwide, with related mortality increasing from 12.1 million to 18.6 million in the past 30 years. To address the supply limitation of autologous vascular grafts and overcome the limits of current treatment options, 3D bioprinting techniques have been investigated. This study aimed at introducing a self-supporting and multi-layered 3D bioprinted construct as a promising alternative for large-blood vessel replacement. To this end, we developed an alginate-gelatin bioink enriched with decellularized extracellular matrix (dECM) of porcine aorta combined with a two-step crosslinking process. We investigated the feasibility of achieving structural stability and shape fidelity of the bioprinted construct over time through rheological characterization, printability tests, and degradation tests. According to the results of rheology and printability tests, dECM-enriched bioink combined with the double-crosslinking process (internal and external crosslink) showed good printability and high shape fidelity, withstanding more than 35 layers without the need for support. Moreover, the bioprinted construct preserved its structural stability over time, retaining a wall thickness comparable to that of the native aorta. Finally, immortalized mouse fibroblasts embedded in the bioink were well adhered to the bioink and alive over time. The double-crosslinked bioink represents an impactful strategy to produce an alternative conduit with the native hierarchical structure of the large blood vessels. •Innovative bioink mimics native vascular tissue using natural polymers and dECM.•Constructs retain multi-layered structure and shape fidelity after 28 days in static culture.•High cell viability at days 1 and 7 of static culture.
ISSN:2405-8866
2405-8866
DOI:10.1016/j.bprint.2024.e00368