| Cardiopatch platform enables maturation and scale-up of human pluripotent stem cell-derived engineered heart tissues IY Shadrin, BW Allen, Y Qian, CP Jackman, AL Carlson, ME Juhas, ... Nature communications 8 (1), 1825, 2017 | 398 | 2017 |
| Bioengineered human myobundles mimic clinical responses of skeletal muscle to drugs L Madden, M Juhas, WE Kraus, GA Truskey, N Bursac elife 4, e04885, 2015 | 344 | 2015 |
| Biomimetic engineered muscle with capacity for vascular integration and functional maturation in vivo M Juhas, GC Engelmayr Jr, AN Fontanella, GM Palmer, N Bursac Proceedings of the National Academy of Sciences 111 (15), 5508-5513, 2014 | 258 | 2014 |
| Hydrated xenogeneic decellularized tracheal matrix as a scaffold for tracheal reconstruction NT Remlinger, CA Czajka, ME Juhas, DA Vorp, DB Stolz, SF Badylak, ... Biomaterials 31 (13), 3520-3526, 2010 | 171 | 2010 |
| Incorporation of macrophages into engineered skeletal muscle enables enhanced muscle regeneration M Juhas, N Abutaleb, JT Wang, J Ye, Z Shaikh, C Sriworarat, Y Qian, ... Nature biomedical engineering 2 (12), 942-954, 2018 | 131 | 2018 |
| Engineering skeletal muscle repair M Juhas, N Bursac Current opinion in biotechnology 24 (5), 880-886, 2013 | 104 | 2013 |
| Local tissue geometry determines contractile force generation of engineered muscle networks W Bian, M Juhas, TW Pfeiler, N Bursac Tissue Engineering Part A 18 (9-10), 957-967, 2012 | 88 | 2012 |
| Roles of adherent myogenic cells and dynamic culture in engineered muscle function and maintenance of satellite cells M Juhas, N Bursac Biomaterials 35 (35), 9438-9446, 2014 | 79 | 2014 |
| Design, evaluation, and application of engineered skeletal muscle M Juhas, J Ye, N Bursac Methods 99, 81-90, 2016 | 70 | 2016 |
| Synergizing engineering and biology to treat and model skeletal muscle injury and disease N Bursac, M Juhas, TA Rando Annual review of biomedical engineering 17 (1), 217-242, 2015 | 55 | 2015 |
| An engineered optogenetic switch for spatiotemporal control of gene expression, cell differentiation, and tissue morphogenesis LR Polstein, M Juhas, G Hanna, N Bursac, CA Gersbach ACS synthetic biology 6 (11), 2003-2013, 2017 | 44 | 2017 |
| Cardiopatch platform enables maturation and scale-up of human pluripotent stem cell-derived engineered heart tissues. Nat Commun. 2017; 8 (1): 1825 IY Shadrin, BW Allen, Y Qian, CP Jackman, AL Carlson, ME Juhas, ... | 10 | |
| Toward a comprehensive hybrid physical-virtual reality simulator of peripheral anesthesia with ultrasound and neurostimulator guidance JT Samosky, P Allen, S Boronyak, B Branstetter, S Hein, M Juhas, ... Medicine Meets Virtual Reality 18, 552-554, 2011 | 7 | 2011 |
| Skeletal Muscle-Macrophage Platform for Modeling Tissue Regeneration M Juhas, NO Abutaleb, JT Wang, N Bursac TISSUE ENGINEERING PART A 23, S9-S9, 2017 | | 2017 |
| In Vitro Bioengineered Model for Studies of Human Muscle Regeneration J Wang, A Khodabukus, M Juhas, N Abutaleb, N Bursac TISSUE ENGINEERING PART A 23, S71-S71, 2017 | | 2017 |
| Engineering Highly-functional, Self-regenerative Skeletal Muscle Tissues with Enhanced Vascularization and Survival In Vivo ME Juhas Duke University, 2016 | | 2016 |
| Engineering Regenerative Skeletal Muscle Tissues M Juhas, J Wang, J Ye, I Shadrin, N Bursac TISSUE ENGINEERING PART A 21, S310-S310, 2015 | | 2015 |
| Bioengineered Skeletal Muscle With Functional Stem Cell Pool and Capacity for Vascular Integration and Maturation In Vivo M Juhas, G Engelmayr, N Bursac MOLECULAR THERAPY 22, S53-S54, 2014 | | 2014 |
| Engineered Muscle Tissues with Significantly Improved Force Production ME Juhas, N Bursac | | |
Nenad BursacProfessor at Duke University在 duke.edu 的电子邮件经过验证
