Josef Goding
Cited by
Cited by
Conductive hydrogels: mechanically robust hybrids for use as biomaterials
RA Green, RT Hassarati, JA Goding, S Baek, NH Lovell, PJ Martens, ...
Macromolecular bioscience 12 (4), 494-501, 2012
Interpenetrating conducting hydrogel materials for neural interfacing electrodes
J Goding, A Gilmour, P Martens, L Poole‐Warren, R Green
Advanced healthcare materials 6 (9), 1601177, 2017
Conductive elastomer composites for fully polymeric, flexible bioelectronics
E Cuttaz, J Goding, C Vallejo-Giraldo, U Aregueta-Robles, N Lovell, ...
Biomaterials science 7 (4), 1372-1385, 2019
Living Bioelectronics: Strategies for Developing an Effective Long‐Term Implant with Functional Neural Connections
JA Goding, AD Gilmour, UA Aregueta‐Robles, EA Hasan, RA Green
Advanced Functional Materials 28 (12), 1702969, 2018
Actively controlled local drug delivery using conductive polymer-based devices
CAR Chapman, EA Cuttaz, JA Goding, RA Green
Applied Physics Letters 116 (1), 2020
Considerations for hydrogel applications to neural bioelectronics
J Goding, C Vallejo-Giraldo, O Syed, R Green
Journal of Materials Chemistry B 7 (10), 1625-1636, 2019
Self-assembling hydrogel structures for neural tissue repair
S Peressotti, GE Koehl, JA Goding, RA Green
ACS Biomaterials Science & Engineering 7 (9), 4136-4163, 2021
Visual prosthesis: interfacing stimulating electrodes with retinal neurons to restore vision
A Barriga-Rivera, L Bareket, J Goding, UA Aregueta-Robles, GJ Suaning
Frontiers in neuroscience 11, 620, 2017
Mind the gap: State-of-the-art technologies and applications for EEG-based brain–computer interfaces
R Portillo-Lara, B Tahirbegi, CAR Chapman, JA Goding, RA Green
APL bioengineering 5 (3), 2021
Conductive hydrogel electrodes for delivery of long-term high frequency pulses
NA Staples, JA Goding, AD Gilmour, KY Aristovich, P Byrnes-Preston, ...
Frontiers in neuroscience 11, 748, 2018
A living electrode construct for incorporation of cells into bionic devices
J Goding, A Gilmour, UA Robles, L Poole-Warren, N Lovell, P Martens, ...
Mrs Communications 7 (3), 487-495, 2017
Stiffness quantification of conductive polymers for bioelectrodes
RT Hassarati, JA Goding, S Baek, AJ Patton, LA Poole‐Warren, RA Green
Journal of Polymer Science Part B: Polymer Physics 52 (9), 666-675, 2014
Stretchable, fully polymeric electrode arrays for peripheral nerve stimulation
EA Cuttaz, CAR Chapman, O Syed, JA Goding, RA Green
Advanced Science 8 (8), 2004033, 2021
Small bioactive molecules as dual functional co-dopants for conducting polymers
JA Goding, AD Gilmour, PJ Martens, LA Poole-Warren, RA Green
Journal of Materials Chemistry B 3 (25), 5058-5069, 2015
Hydrogels for 3D neural tissue models: Understanding cell-material interactions at a molecular level
C Vallejo-Giraldo, M Genta, O Cauvi, J Goding, R Green
Frontiers in Bioengineering and Biotechnology 8, 601704, 2020
The influence of physicochemical properties on the processibility of conducting polymers: A bioelectronics perspective
J Heck, J Goding, RP Lara, R Green
Acta Biomaterialia 139, 259-279, 2022
Challenges of therapeutic delivery using conducting polymers
L Poole-Warren, J Goding, R Green, P Martens
Therapeutic Delivery 3 (4), 421-427, 2012
Stretchable bioelectronics: Mitigating the challenges of the percolation threshold in conductive elastomers
A Novikov, J Goding, C Chapman, E Cuttaz, RA Green
APL Materials 8 (10), 2020
Adaptive biomimicry: Design of neural interfaces with enhanced biointegration
R Portillo-Lara, JA Goding, RA Green
Current Opinion in Biotechnology 72, 62-68, 2021
Biosynthetic conductive polymer composites for tissue-engineering biomedical devices
RA Green, JA Goding
Biosynthetic Polymers for Medical Applications, 277-298, 2016
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