Engineering a 3D-Bioprinted Model of Human Heart Valve Disease Using Nanoindentation-Based Biomechanics

In calcific aortic valve disease (CAVD), microcalcifications originating from nanoscale calcifying vesicles disrupt the aortic valve (AV) leaflets, which consist of three (biomechanically) distinct layers: the fibrosa, spongiosa, and ventricularis. CAVD has no pharmacotherapy and lacks in vitro mode...

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Bibliographic Details
Published in:Nanomaterials (Basel, Switzerland) Switzerland), 2018-05, Vol.8 (5), p.296
Main Authors: van der Valk, Dewy C, van der Ven, Casper F T, Blaser, Mark C, Grolman, Joshua M, Wu, Pin-Jou, Fenton, Owen S, Lee, Lang H, Tibbitt, Mark W, Andresen, Jason L, Wen, Jennifer R, Ha, Anna H, Buffolo, Fabrizio, van Mil, Alain, Bouten, Carlijn V C, Body, Simon C, Mooney, David J, Sluijter, Joost P G, Aikawa, Masanori, Hjortnaes, Jesper, Langer, Robert, Aikawa, Elena
Format: Article
Language:English
Subjects:
3D printing
Aortic valve
Apoptosis
Biocompatibility
Bioengineering
Biomechanics
Biomedical materials
bioprinting
calcific aortic valve disease
Calcification
Catheters
Coronary artery disease
Crosslinking
Drug screening
Gelatin
Heart diseases
Hyaluronic acid
Hydrogels
Immunofluorescence
Interstitial cells
Mechanical properties
mechanobiology
microdissection
Mimicry
Nanoindentation
Pathogenesis
Pharmacology
Rheumatic heart disease
Three dimensional models
Three dimensional printing
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Summary:In calcific aortic valve disease (CAVD), microcalcifications originating from nanoscale calcifying vesicles disrupt the aortic valve (AV) leaflets, which consist of three (biomechanically) distinct layers: the fibrosa, spongiosa, and ventricularis. CAVD has no pharmacotherapy and lacks in vitro models as a result of complex valvular biomechanical features surrounding resident mechanosensitive valvular interstitial cells (VICs). We measured layer-specific mechanical properties of the human AV and engineered a three-dimensional (3D)-bioprinted CAVD model that recapitulates leaflet layer biomechanics for the first time. Human AV leaflet layers were separated by microdissection, and nanoindentation determined layer-specific Young's moduli. Methacrylated gelatin (GelMA)/methacrylated hyaluronic acid (HAMA) hydrogels were tuned to duplicate layer-specific mechanical characteristics, followed by 3D-printing with encapsulated human VICs. Hydrogels were exposed to osteogenic media (OM) to induce microcalcification, and VIC pathogenesis was assessed by near infrared or immunofluorescence microscopy. Median Young's moduli of the AV layers were 37.1, 15.4, and 26.9 kPa (fibrosa/spongiosa/ventricularis, respectively). The fibrosa and spongiosa Young's moduli matched the 3D 5% GelMa/1% HAMA UV-crosslinked hydrogels. OM stimulation of VIC-laden bioprinted hydrogels induced microcalcification without apoptosis. We report the first layer-specific measurements of human AV moduli and a novel 3D-bioprinted CAVD model that potentiates microcalcification by mimicking the native AV mechanical environment. This work sheds light on valvular mechanobiology and could facilitate high-throughput drug-screening in CAVD.
ISSN:2079-4991
2079-4991
DOI:10.3390/nano8050296