Engineering human pluripotent stem cells into a functional skeletal muscle tissue L Rao, Y Qian, A Khodabukus, T Ribar, N Bursac Nature communications 9 (1), 126, 2018 | 285 | 2018 |
A Novel Bioreactor for Stimulating Skeletal Muscle In Vitro K Donnelly, A Khodabukus, A Philp, L Deldicque, RG Dennis, K Baar Tissue Engineering Part C: Methods 16 (4), 711-718, 2010 | 155 | 2010 |
Electrical stimulation increases hypertrophy and metabolic flux in tissue-engineered human skeletal muscle A Khodabukus, L Madden, NK Prabhu, TR Koves, CP Jackman, ... Biomaterials 198, 259-269, 2019 | 154 | 2019 |
Striated muscle function, regeneration, and repair IY Shadrin, A Khodabukus, N Bursac Cellular and molecular life sciences 73, 4175-4202, 2016 | 117 | 2016 |
Factors affecting the structure and maturation of human tissue engineered skeletal muscle NRW Martin, SL Passey, DJ Player, A Khodabukus, RA Ferguson, ... Biomaterials 34 (23), 5759-5765, 2013 | 96 | 2013 |
Regulating fibrinolysis to engineer skeletal muscle from the C2C12 cell line A Khodabukus, K Baar Tissue Engineering Part C: Methods 15 (3), 501-511, 2009 | 94 | 2009 |
In vitro tissue‐engineered skeletal muscle models for studying muscle physiology and disease A Khodabukus, N Prabhu, J Wang, N Bursac Advanced Healthcare Materials 7 (15), 1701498, 2018 | 92 | 2018 |
Defined electrical stimulation emphasizing excitability for the development and testing of engineered skeletal muscle A Khodabukus, K Baar Tissue Engineering Part C: Methods 18 (5), 349-357, 2012 | 92 | 2012 |
Engineered skeletal muscles for disease modeling and drug discovery J Wang, A Khodabukus, L Rao, K Vandusen, N Abutaleb, N Bursac Biomaterials 221, 119416, 2019 | 87 | 2019 |
Tissue-engineered skeletal muscle models to study muscle function, plasticity, and disease A Khodabukus Frontiers in Physiology 12, 619710, 2021 | 47 | 2021 |
The effect of serum origin on tissue engineered skeletal muscle function A Khodabukus, K Baar Journal of cellular biochemistry 115 (12), 2198-2207, 2014 | 44 | 2014 |
Contractile and metabolic properties of engineered skeletal muscle derived from slow and fast phenotype mouse muscle A Khodabukus, K Baar Journal of Cellular Physiology 230 (8), 1750-1757, 2015 | 41 | 2015 |
Role of contraction duration in inducing fast‐to‐slow contractile and metabolic protein and functional changes in engineered muscle A Khodabukus, LM Baehr, SC Bodine, K Baar Journal of Cellular Physiology 230 (10), 2489-2497, 2015 | 38 | 2015 |
Engineered muscle: a tool for studying muscle physiology and function A Khodabukus, JZ Paxton, K Donnelly, K Baar Exercise and sport sciences reviews 35 (4), 186-191, 2007 | 34 | 2007 |
Factors that affect tissue-engineered skeletal muscle function and physiology A Khodabukus, K Baar Cells Tissues Organs 202 (3-4), 159-168, 2016 | 32 | 2016 |
Glucose concentration and streptomycin alter in vitro muscle function and metabolism A Khodabukus, K Baar Journal of cellular physiology 230 (6), 1226-1234, 2015 | 32 | 2015 |
Tissue-engineered human myobundle system as a platform for evaluation of skeletal muscle injury biomarkers A Khodabukus, A Kaza, J Wang, N Prabhu, R Goldstein, VS Vaidya, ... Toxicological Sciences 176 (1), 124-136, 2020 | 23 | 2020 |
Three-dimensional tissue-engineered human skeletal muscle model of Pompe disease J Wang, CJ Zhou, A Khodabukus, S Tran, SO Han, AL Carlson, L Madden, ... Communications biology 4 (1), 524, 2021 | 21 | 2021 |
Neuromuscular Development and Disease: Learning From in vitro and in vivo Models Z Fralish, EM Lotz, T Chavez, A Khodabukus, N Bursac Frontiers in cell and developmental biology 9, 764732, 2021 | 19 | 2021 |
Streptomycin decreases the functional shift to a slow phenotype induced by electrical stimulation in engineered muscle A Khodabukus, K Baar Tissue Engineering Part A 21 (5-6), 1003-1012, 2015 | 16 | 2015 |