Instrumented cardiac microphysiological devices via multimaterial three-dimensional printing
Johan Ulrik Lind,Johan Ulrik Lind,Travis Alexander Busbee,Travis Alexander Busbee,Alexander D. Valentine,Alexander D. Valentine,Francesco S. Pasqualini,Francesco S. Pasqualini,Hongyan Yuan,Hongyan Yuan,Hongyan Yuan,Moran Yadid,Moran Yadid,Sung-Jin Park,Sung-Jin Park,Arda Kotikian,Arda Kotikian,Alexander P. Nesmith,Alexander P. Nesmith,Patrick H. Campbell,Patrick H. Campbell,Joost J. Vlassak,Jennifer A. Lewis,Jennifer A. Lewis,Kevin Kit Parker,Kevin Kit Parker +25 more
TLDR
Six functional inks are designed, based on piezo-resistive, high conductance, and biocompatible soft materials that enable integration of soft strain gauge sensors within micro-architectures that guide the self-assembly of physio-mimetic laminar cardiac tissues via multi-material 3D printing.Abstract:
Biomedical research has relied on animal studies and conventional cell cultures for decades. Recently, microphysiological systems (MPS), also known as organs-on-chips, that recapitulate the structure and function of native tissues in vitro, have emerged as a promising alternative. However, current MPS typically lack integrated sensors and their fabrication requires multi-step lithographic processes. Here, we introduce a facile route for fabricating a new class of instrumented cardiac microphysiological devices via multimaterial three-dimensional (3D) printing. Specifically, we designed six functional inks, based on piezo-resistive, high-conductance, and biocompatible soft materials that enable integration of soft strain gauge sensors within micro-architectures that guide the self-assembly of physio-mimetic laminar cardiac tissues. We validated that these embedded sensors provide non-invasive, electronic readouts of tissue contractile stresses inside cell incubator environments. We further applied these devices to study drug responses, as well as the contractile development of human stem cell-derived laminar cardiac tissues over four weeks.read more
Citations
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Elastic 3D-Printed Hybrid Polymeric Scaffold Improves Cardiac Remodeling after Myocardial Infarction.
Yang Yang,Dong Lei,Shixing Huang,Qi Yang,Benyan Song,Yifan Guo,Ao Shen,Zhize Yuan,Sen Li,Feng-Ling Qing,Xiaofeng Ye,Zhengwei You,Qiang Zhao +12 more
TL;DR: This study demonstrates the therapeutic effects and versatile applications of a novel 3D‐printed, biodegradable and biocompatible cardiac scaffold, which represents a promising strategy for improving myocardial remodeling after MI.
Journal ArticleDOI
Combining additive manufacturing with microfluidics: an emerging method for developing novel organs-on-chips
TL;DR: The recent advances in the field are focused on, specifically in the fabrication modalities, materials and characterization methods, which are commonly employed for OOCs based on 3D bioprinting, aiming to provide future strategies for more efficient, automated, modularly integrated, and customizable O OCs.
Journal ArticleDOI
Integration concepts for multi-organ chips: how to maintain flexibility?!
TL;DR: This perspective elucidates the concept of ‘mix-and-match’ toolboxes and discusses the numerous advantages compared with static/semistatic platforms as well as remaining challenges.
Journal ArticleDOI
Heart on a chip: Micro-nanofabrication and microfluidics steering the future of cardiac tissue engineering
TL;DR: The micro and nanofabrication methods used for cardiac tissue engineering are surveyed, ranging from clean room-based patterning to electrospinning and additive manufacturing, and their efficacy for future development of cardiac disease modeling and drug screening platforms is assessed.
Journal ArticleDOI
Traction force microscopy of engineered cardiac tissues.
Francesco S. Pasqualini,Ashutosh Agarwal,Blakely B. O'Connor,Blakely B. O'Connor,Qihan Liu,Qihan Liu,Sean P. Sheehy,Sean P. Sheehy,Kevin Kit Parker,Kevin Kit Parker +9 more
TL;DR: This system investigated the relationship between contractile proficiency and metabolism in neonate rat ventricular myocytes cultured on gels with stiffness mimicking soft immature, normal healthy, and stiff diseased cardiac microenvironments and found that tissues engineered on the softest gels generated the least amount of stress and had the smallest work output.
References
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