| 3D bioprinting for cartilage and osteochondral tissue engineering AC Daly, FE Freeman, T Gonzalez‐Fernandez, SE Critchley, J Nulty, ... Advanced healthcare materials 6 (22), 1700298, 2017 | 307 | 2017 |
| 3D printed microchannel networks to direct vascularisation during endochondral bone repair AC Daly, P Pitacco, J Nulty, GM Cunniffe, DJ Kelly Biomaterials 162, 34-46, 2018 | 204 | 2018 |
| 3D bioprinting spatiotemporally defined patterns of growth factors to tightly control tissue regeneration FE Freeman, P Pitacco, LHA van Dommelen, J Nulty, DC Browe, JY Shin, ... Science advances 6 (33), eabb5093, 2020 | 162 | 2020 |
| 3D bioprinting of prevascularised implants for the repair of critically-sized bone defects J Nulty, FE Freeman, DC Browe, R Burdis, DP Ahern, P Pitacco, YB Lee, ... Acta biomaterialia 126, 154-169, 2021 | 99 | 2021 |
| Affinity-bound growth factor within sulfated interpenetrating network bioinks for bioprinting cartilaginous tissues B Wang, PJ Diaz-Payno, DC Browe, FE Freeman, J Nulty, R Burdis, ... Acta Biomaterialia 128, 130-142, 2021 | 80 | 2021 |
| Biofabrication of multiscale bone extracellular matrix scaffolds for bone tissue engineering FE Freeman, DC Browe, J Nulty, S Von Euw, WL Grayson, DJ Kelly Eur. Cells Mater 38, 168-187, 2019 | 62 | 2019 |
| Spatial patterning of phenotypically distinct microtissues to engineer osteochondral grafts for biological joint resurfacing R Burdis, F Chariyev-Prinz, DC Browe, FE Freeman, J Nulty, ... Biomaterials 289, 121750, 2022 | 28 | 2022 |
| Bilayered extracellular matrix derived scaffolds with anisotropic pore architecture guide tissue organization during osteochondral defect repair DC Browe, PJ Díaz-Payno, FE Freeman, R Schipani, R Burdis, DP Ahern, ... Acta Biomaterialia 143, 266-281, 2022 | 28 | 2022 |
| Scaffold microarchitecture regulates angiogenesis and the regeneration of large bone defects KF Eichholz, FE Freeman, P Pitacco, J Nulty, D Ahern, R Burdis, ... Biofabrication 14 (4), 045013, 2022 | 25 | 2022 |
| Biofabrication of prevascularised hypertrophic cartilage microtissues for bone tissue engineering J Nulty, R Burdis, DJ Kelly Frontiers in bioengineering and biotechnology 9, 661989, 2021 | 25 | 2021 |
| Promoting endogenous articular cartilage regeneration using extracellular matrix scaffolds DC Browe, R Burdis, PJ Díaz-Payno, FE Freeman, JM Nulty, CT Buckley, ... Materials Today Bio 16, 100343, 2022 | 22 | 2022 |
| Radial glial cells organize the central nervous system via microtubule dependant processes J Nulty, M Alsaffar, D Barry brain research 1625, 171-179, 2015 | 15 | 2015 |
| Bioinks and their applications in tissue engineering J Nulty, R Schipani, R Burdis, DJ Kelly Polymer-Based Additive Manufacturing: Biomedical Applications, 187-218, 2019 | 11 | 2019 |
| Gremlin-1 Suppresses Hypertrophy of Engineered Cartilage In Vitro but Not Bone Formation In Vivo PJ Díaz-Payno, DC Browe, FE Freeman, J Nulty, R Burdis, DJ Kelly Tissue Engineering Part A 28 (15-16), 724-736, 2022 | 8 | 2022 |
| Development of a 3D bioprinted scaffold with spatio-temporally defined patterns of BMP-2 and VEGF for the regeneration of large bone defects FE Freeman, P Pitacco, LHA Van Dommelen, J Nulty, DC Browe, JY Shin, ... Bio-protocol 11 (21), e4219-e4219, 2021 | 7 | 2021 |
| BIPHASIC TISSUE-SPECIFIC EXTRACELLULAR MATRIX DERIVED SCAFFOLDS PROMOTE ZONALLY DEFINED ARTICULAR CARTILAGE REGENERATION IN A CAPRINE OSTEOCHONDRAL DEFECT MODEL D Browe, PD Payno, R Schipani, F Freeman, R Burdis, D Ahern, ... TISSUE ENGINEERING PART A 28, S494-S494, 2022 | | 2022 |
| THE DEVELOPMENT OF A NOVEL 3D BIOPRINTING STRATEGY TO DRIVE VASCULARISATION, AND ITS APPLICATION FOR BONE TISSUE ENGINEERING J Nulty University of Dublin, 2020 | | 2020 |
Daniel KellyTrinity Centre for Biomedical Engineering, School of Engineering, Trinity College Dublin在 tcd.ie 的电子邮件经过验证
