“Designer” scaffolds for tissue engineering and regeneration T Dvir, O Tsur‐Gang, S Cohen Israel journal of chemistry 45 (4), 487-494, 2005 | 61 | 2005 |
3D printing of personalized thick and perfusable cardiac patches and hearts N Noor, A Shapira, R Edri, I Gal, L Wertheim, T Dvir Advanced science 6 (11), 1900344, 2019 | 956 | 2019 |
3D tissue and organ printing—hope and reality A Shapira, T Dvir Advanced Science 8 (10), 2003751, 2021 | 78 | 2021 |
A microfluidic chip containing multiple 3D nanofibrous scaffolds for culturing human pluripotent stem cells L Wertheim, A Shapira, RJ Amir, T Dvir Nanotechnology 29 (13), 13LT01, 2018 | 6 | 2018 |
A novel perfusion bioreactor providing a homogenous milieu for tissue regeneration T Dvir, N Benishti, M Shachar, S Cohen Tissue engineering 12 (10), 2843-2852, 2006 | 152 | 2006 |
A ray of light for treating cardiac conduction disorders R Feiner, T Dvir Proceedings of the National Academy of Sciences 116 (2), 347-349, 2019 | 3 | 2019 |
A self-healing, all-organic, conducting, composite peptide hydrogel as pressure sensor and electrogenic cell soft substrate P Chakraborty, T Guterman, N Adadi, M Yadid, T Brosh, ... ACS nano 13 (1), 163-175, 2018 | 164 | 2018 |
A stretchable and flexible cardiac tissue–electronics hybrid enabling multiple drug release, sensing, and stimulation R Feiner, L Wertheim, D Gazit, O Kalish, G Mishal, A Shapira, T Dvir Small 15 (14), 1805526, 2019 | 59 | 2019 |
A universal, multimodal cell-based biosensing platform for optimal intracellular action potential recording D Xu, J Fang, M Yadid, M Zhang, H Wang, Q Xia, H Li, N Cao, T Dvir, ... Biosensors and Bioelectronics 206, 114122, 2022 | 7 | 2022 |
Activation of the ERK1/2 cascade via pulsatile interstitial fluid flow promotes cardiac tissue assembly T Dvir, O Levy, M Shachar, Y Granot, S Cohen Tissue engineering 13 (9), 2185-2193, 2007 | 113 | 2007 |
Advanced micro-and nanofabrication technologies for tissue engineering A Shapira, DH Kim, T Dvir Biofabrication 6 (2), 020301, 2014 | 35 | 2014 |
Advanced Technologies for Engineering Tissue Mimetics T Cohen‐Karni, T Dvir Israel Journal of Chemistry 53 (9‐10), 630-636, 2013 | | 2013 |
Albumin fiber scaffolds for engineering functional cardiac tissues S Fleischer, A Shapira, O Regev, N Nseir, E Zussman, T Dvir Biotechnology and bioengineering 111 (6), 1246-1257, 2014 | 99 | 2014 |
An electromechanical hug for the failing heart R Feiner, T Dvir Annals of Translational Medicine 4 (20), 2016 | | 2016 |
Autospecies and Post–Myocardial Infarction Sera Enhance the Viability, Proliferation, and Maturation of 3D Cardiac Cell Culture R Schwarzkopf, M Shachar, T Dvir, Y Dayan, R Holbova, J Leor, S Cohen Tissue Engineering 12 (12), 3467-3475, 2006 | 14 | 2006 |
Biodegradable, Biocompatible, and Implantable Multifunctional Sensing Platform for Cardiac Monitoring R Omar, W Saliba, M Khatib, Y Zheng, C Pieters, H Oved, E Silberman, ... ACS sensors 9 (1), 126-138, 2024 | 2 | 2024 |
Bioengineering approaches to treat the failing heart: from cell biology to 3D printing M Yadid, H Oved, E Silberman, T Dvir Nature Reviews Cardiology 19 (2), 83-99, 2022 | 49 | 2022 |
Bioreactor engineering: regenerating the dynamic cell microenvironment T Dvir, S Cohen Advances in tissue engineering, 517-535, 2008 | 7 | 2008 |
Cardiac tissue engineering: From matrix design to the engineering of bionic hearts S Fleischer, R Feiner, T Dvir Regenerative medicine 12 (3), 275-284, 2017 | 17 | 2017 |
Channeled ECM-based nanofibrous hydrogel for engineering vascularized cardiac tissues S Arvatz, L Wertheim, S Fleischer, A Shapira, T Dvir Nanomaterials 9 (5), 689, 2019 | 12 | 2019 |