|Engineering microscale topographies to control the cell–substrate interface|
M Nikkhah, F Edalat, S Manoucheri, A Khademhosseini
Biomaterials 33 (21), 5230-5246, 2012
|Hydrogel bioprinted microchannel networks for vascularization of tissue engineering constructs|
LE Bertassoni, M Cecconi, V Manoharan, M Nikkhah, J Hjortnaes, ...
Lab on a Chip 14 (13), 2202-2211, 2014
|Carbon-nanotube-embedded hydrogel sheets for engineering cardiac constructs and bioactuators|
SR Shin, SM Jung, M Zalabany, K Kim, P Zorlutuna, S Kim, M Nikkhah, ...
ACS nano 7 (3), 2369-2380, 2013
|Microfabricated biomaterials for engineering 3D tissues|
P Zorlutuna, N Annabi, G Camci‐Unal, M Nikkhah, JM Cha, JW Nichol, ...
Advanced materials 24 (14), 1782-1804, 2012
|Injectable graphene oxide/hydrogel-based angiogenic gene delivery system for vasculogenesis and cardiac repair|
A Paul, A Hasan, HA Kindi, AK Gaharwar, VTS Rao, M Nikkhah, SR Shin, ...
ACS nano 8 (8), 8050-8062, 2014
|Vascularized bone tissue engineering: approaches for potential improvement|
LH Nguyen, N Annabi, M Nikkhah, H Bae, L Binan, S Park, Y Kang, ...
Tissue Engineering Part B: Reviews 18 (5), 363-382, 2012
|Directed endothelial cell morphogenesis in micropatterned gelatin methacrylate hydrogels|
M Nikkhah, N Eshak, P Zorlutuna, N Annabi, M Castello, K Kim, ...
Biomaterials 33 (35), 9009-9018, 2012
|PGS: Gelatin nanofibrous scaffolds with tunable mechanical and structural properties for engineering cardiac tissues|
M Kharaziha, M Nikkhah, SR Shin, N Annabi, N Masoumi, AK Gaharwar, ...
Biomaterials 34 (27), 6355-6366, 2013
|Highly elastic micropatterned hydrogel for engineering functional cardiac tissue|
N Annabi, K Tsang, SM Mithieux, M Nikkhah, A Ameri, A Khademhosseini, ...
Advanced functional materials 23 (39), 4950-4959, 2013
|Tough and flexible CNT–polymeric hybrid scaffolds for engineering cardiac constructs|
M Kharaziha, SR Shin, M Nikkhah, SN Topkaya, N Masoumi, N Annabi, ...
Biomaterials 35 (26), 7346-7354, 2014
|Reduced graphene oxide‐gelMA hybrid hydrogels as scaffolds for cardiac tissue engineering|
SR Shin, C Zihlmann, M Akbari, P Assawes, L Cheung, K Zhang, ...
Small 12 (27), 3677-3689, 2016
|Natural and synthetic biomedical polymers|
S Kumbar, C Laurencin, M Deng
Elsevier 17, 402, 2014
|Emerging biofabrication strategies for engineering complex tissue constructs|
RD Pedde, B Mirani, A Navaei, T Styan, S Wong, M Mehrali, A Thakur, ...
Advanced Materials 29 (19), 1606061, 2017
|A combinatorial cell-laden gel microarray for inducing osteogenic differentiation of human mesenchymal stem cells|
A Dolatshahi-Pirouz, M Nikkhah, AK Gaharwar, B Hashmi, E Guermani, ...
Scientific reports 4 (1), 1-9, 2014
|Nanoreinforced hydrogels for tissue engineering: Biomaterials that are compatible with load‐bearing and electroactive tissues|
M Mehrali, A Thakur, CP Pennisi, S Talebian, A Arpanaei, M Nikkhah, ...
Advanced Materials 29 (8), 1603612, 2017
|Exoskeletal device for rehabilitation|
H Ashrafiuon, M Nikkhah
US Patent 7,190,141, 2007
|Gold nanorod-incorporated gelatin-based conductive hydrogels for engineering cardiac tissue constructs|
A Navaei, H Saini, W Christenson, RT Sullivan, R Ros, M Nikkhah
Acta biomaterialia 41, 133-146, 2016
|Layer‐by‐layer assembly of 3D tissue constructs with functionalized graphene|
SR Shin, B Aghaei‐Ghareh‐Bolagh, X Gao, M Nikkhah, SM Jung, ...
Advanced functional materials 24 (39), 6136-6144, 2014
|The cytoskeletal organization of breast carcinoma and fibroblast cells inside three dimensional (3-D) isotropic silicon microstructures|
M Nikkhah, JS Strobl, R De Vita, M Agah
Biomaterials 31 (16), 4552-4561, 2010
|Biodegradable nanofibrous polymeric substrates for generating elastic and flexible electronics|
AH Najafabadi, A Tamayol, N Annabi, M Ochoa, P Mostafalu, M Akbari, ...
Advanced Materials 26 (33), 5823-5830, 2014