Rapid 3D printing of anatomically accurate and mechanically heterogeneous aortic valve hydrogel scaffolds

Hockaday, Laura A.; Kang, Kevin H.; Colangelo, N W; Cheung, P Y C; Duan, Bin; Malone, Evan; Wu, Jun; Girardi, Leonard N.; Bonassar, Lawrence J.; Lipson, Hod; Chu, C. C.; Butcher, Jonathan T.

doi:10.1088/1758-5082/4/3/035005

articleBiofabricationAug 23, 2012Closed access

Rapid 3D printing of anatomically accurate and mechanically heterogeneous aortic valve hydrogel scaffolds

LALaura A. Hockaday KHKevin H. Kang NWN W Colangelo PYP Y C Cheung BDBin Duan

Cornell University

PubMed

Indexed incrossrefpubmed

Abstract

The aortic valve exhibits complex three-dimensional (3D) anatomy and heterogeneity essential for the long-term efficient biomechanical function. These are, however, challenging to mimic in de novo engineered living tissue valve strategies. We present a novel simultaneous 3D printing/photocrosslinking technique for rapidly engineering complex, heterogeneous aortic valve scaffolds. Native anatomic and axisymmetric aortic valve geometries (root wall and tri-leaflets) with 12-22 mm inner diameters (ID) were 3D printed with poly-ethylene glycol-diacrylate (PEG-DA) hydrogels (700 or 8000 MW) supplemented with alginate. 3D printing geometric accuracy was quantified and compared using Micro-CT. Porcine aortic valve…

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682

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FWCI: 18.67
Percentile: 100%
References: 71

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Authors

12

Topics & keywords

Topics

Keywords

Self-healing hydrogels
Biomedical engineering
Materials science
Ethylene glycol
Aortic valve
3d printed
Tissue engineering
3D printing

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