Joseph J. Pancrazio
Affiliations: | 2009-2015 | Biomedical Engineering | George Mason University, Washington, DC |
2015- | Bioengineering | University of Texas at Dallas, Richardson, TX, United States |
Area:
Neuroscience Biology, Biomedical EngineeringGoogle:
"Joseph Pancrazio"Mean distance: 53433
Parents
Sign in to add mentorYong I. Kim | grad student | 1985-1990 | UVA |
Carl Lynch III | post-doc | 1990-1991 | UVA |
Children
Sign in to add traineeBrandon S Sturgill | grad student | UT Dallas | |
Rahul Radhakrishna | grad student | 2020- | UT Dallas |
Gretchen L. Knaack | grad student | 2014 | George Mason |
Hamid Charkhkar | grad student | 2011-2015 | George Mason University, Fairfax VA |
Rahul Atmaramani | grad student | 2016-2020 | UT Dallas |
Rashed Rihani | grad student | 2016-2020 | UT Dallas |
Allison M. Stiller | grad student | 2016-2020 | UT Dallas |
Christopher L. Frewin | post-doc | 2015-2019 | UT Dallas (Chemistry Tree) |
Bryan J. Black | post-doc | 2015-2020 | UT Dallas |
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Publications
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Sturgill BS, Hernandez-Reynoso AG, Druschel LN, et al. (2024) Reactive Amine Functionalized Microelectrode Arrays Provide Short-Term Benefit but Long-Term Detriment to Recording Performance. Acs Applied Bio Materials |
Hernandez-Reynoso AG, Sturgill BS, Hoeferlin GF, et al. (2023) The effect of a Mn(III)tetrakis(4-benzoic acid)porphyrin (MnTBAP) coating on the chronic recording performance of planar silicon intracortical microelectrode arrays. Biomaterials. 303: 122351 |
Hoeferlin GF, Bajwa T, Olivares H, et al. (2023) Antioxidant Dimethyl Fumarate Temporarily but Not Chronically Improves Intracortical Microelectrode Performance. Micromachines. 14 |
Jeakle EN, Abbott JR, Usoro JO, et al. (2023) Chronic Stability of Local Field Potentials Using Amorphous Silicon Carbide Microelectrode Arrays Implanted in the Rat Motor Cortex. Micromachines. 14 |
Krebs OK, Mittal G, Ramani S, et al. (2022) Tools for Surface Treatment of Silicon Planar Intracortical Microelectrodes. Journal of Visualized Experiments : Jove |
Sturgill B, Radhakrishna R, Thai TTD, et al. (2022) Characterization of Active Electrode Yield for Intracortical Arrays: Awake versus Anesthesia. Micromachines. 13 |
Atmaramani R, Veeramachaneni S, Mogas LV, et al. (2021) Investigating the Function of Adult DRG Neuron Axons Using an In Vitro Microfluidic Culture System. Micromachines. 12 |
Usoro JO, Dogra K, Abbott JR, et al. (2021) Influence of Implantation Depth on the Performance of Intracortical Probe Recording Sites. Micromachines. 12 |
Usoro JO, Sturgill BS, Musselman KC, et al. (2021) Intracortical Microelectrode Array Unit Yield under Chronic Conditions: A Comparative Evaluation. Micromachines. 12 |
Garcia-Sandoval A, Guerrero E, Hosseini SM, et al. (2021) Stable softening bioelectronics: A paradigm for chronically viable ester-free neural interfaces such as spinal cord stimulation implants. Biomaterials. 277: 121073 |