TY - JOUR
T1 - Intracellular proteomics and extracellular vesiculomics as a metric of disease recapitulation in 3D-bioprinted aortic valve arrays
AU - Clift, Cassandra L.
AU - Blaser, Mark C.
AU - Gerrits, Willem
AU - Turner, Mandy E.
AU - Sonawane, Abhijeet
AU - Pham, Tan
AU - Andresen, Jason L.
AU - Fenton, Owen S.
AU - Grolman, Joshua M.
AU - Campedelli, Alesandra
AU - Buffolo, Fabrizio
AU - Schoen, Frederick J.
AU - Hjortnaes, Jesper
AU - Muehlschlegel, Jochen D.
AU - Mooney, David J.
AU - Aikawa, Masanori
AU - Singh, Sasha A.
AU - Langer, Robert
AU - Aikawa, Elena
N1 - Publisher Copyright:
© 2024 the Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. no claim to original U.S. Government Works. distributed under a Creative Commons Attribution nonCommercial license 4.0 (CC BY-nC).
PY - 2024/3
Y1 - 2024/3
N2 - In calcific aortic valve disease (CAVD), mechanosensitive valvular cells respond to fibrosis- and calcification-induced tissue stiffening, further driving pathophysiology. No pharmacotherapeutics are available to treat CAVD because of the paucity of (i) appropriate experimental models that recapitulate this complex environment and (ii) benchmarking novel engineered aortic valve (AV)–model performance. We established a biomaterial-based CAVD model mimicking the biomechanics of the human AV disease-prone fibrosa layer, three-dimensional (3D)–bioprinted into 96-well arrays. Liquid chromatography–tandem mass spectrometry analyses probed the cellular proteome and vesiculome to compare the 3D-bioprinted model versus traditional 2D monoculture, against human CAVD tissue. The 3D-bioprinted model highly recapitulated the CAVD cellular proteome (94% versus 70% of 2D proteins). Integration of cellular and vesicular datasets identified known and unknown proteins ubiquitous to AV calcification. This study explores how 2D versus 3D-bioengineered systems recapitulate unique aspects of human disease, positions multiomics as a technique for the evaluation of high throughput–based bioengineered model systems, and potentiates future drug discovery.
AB - In calcific aortic valve disease (CAVD), mechanosensitive valvular cells respond to fibrosis- and calcification-induced tissue stiffening, further driving pathophysiology. No pharmacotherapeutics are available to treat CAVD because of the paucity of (i) appropriate experimental models that recapitulate this complex environment and (ii) benchmarking novel engineered aortic valve (AV)–model performance. We established a biomaterial-based CAVD model mimicking the biomechanics of the human AV disease-prone fibrosa layer, three-dimensional (3D)–bioprinted into 96-well arrays. Liquid chromatography–tandem mass spectrometry analyses probed the cellular proteome and vesiculome to compare the 3D-bioprinted model versus traditional 2D monoculture, against human CAVD tissue. The 3D-bioprinted model highly recapitulated the CAVD cellular proteome (94% versus 70% of 2D proteins). Integration of cellular and vesicular datasets identified known and unknown proteins ubiquitous to AV calcification. This study explores how 2D versus 3D-bioengineered systems recapitulate unique aspects of human disease, positions multiomics as a technique for the evaluation of high throughput–based bioengineered model systems, and potentiates future drug discovery.
UR - http://www.scopus.com/inward/record.url?scp=85186740161&partnerID=8YFLogxK
U2 - 10.1126/sciadv.adj9793
DO - 10.1126/sciadv.adj9793
M3 - Article
C2 - 38416823
AN - SCOPUS:85186740161
VL - 10
JO - Science advances
JF - Science advances
IS - 9
M1 - eadj9793
ER -