Paper
| • X, Wang., S, Wu., H, Yang., Y, Bao., Z, Li., C, Gan., Y, Deng., J, Cao., X, Li., Y, Wang., C, Ren.*, Z, Yang.*Z, Zhao.# (2024) Intravascular delivery of an ultraflexible neural electrode array for recordings of cortical spiking activity. Nat Commun. 15(1): 9442. |
| • G, Wang., C, You., C, Feng., W, Yao., Z, Zhao., N, Xue., L, Yao. (2024) Modeling and Analysis of Environmental Electromagnetic Interference in Multiple-Channel Neural Recording Systems for High Common-Mode Interference Rejection Performance. Biosensors (Basel). 14(7): 343. |
| • J. Fan, X. Li, P. Wang, F. Yang, B. Zhao, J. Yang, Z, Zhao. (2023) A Hyperflexible Electrode Array for Long-Term Recording and Decoding of Intraspinal Neuronal Activity. Adv. Sci. : 10, 2303377. |
| • Tian, Y., Yin, J., Wang, C., He, Z., Xie, J., Feng, X., Zhou, Y., Ma, T., Xie, Y., Li, X., Yang, T., Ren, C.*,Li. C.*,Z, Zhao. (2023) An Ultraflexible Electrode Array for Large-Scale Chronic Recording in the Nonhuman Primate Brain. Adv. Sci. 10(33): e2302333. |
| • Z, Zhao.#, H, Zhu.#, X, Li.#, L, Sun., F, He., JE, Chung., DF, Liu., L, Frank., L, Luan., and C, Xie. (2022) Ultraflexible electrode arrays enable long-term, volumetric mapping of neural networks at the thousands-of-neuron scale. Nat. Biomed. Eng. 7(4): 520-532 |
| • Wang, Q., You, C., Xue, N., Zhang, X., Feng, C., Z, Zhao., Yao, L. and Li, T. (2022) A DC-coupled 1.2 μW 0.012 mm2 per channel neural amplifiers array with 75 dB system common mode rejection ratio and 300 mV common mode interference. Electron. Lett. 58: 876-878. |
| • X, Zeng., X, Zhang., Z, Wang., Z, Zhao., X, Li., L, Yao., N, Xue. (2022) A 12-V Single-Input Multiple-Independently Configurable-Output Dynamic Voltage Scaling Supply in Standard 0.18-μm CMOS for Electrical Stimulation Applications. IEEE Solid-State Circuits Letters 5: 33-36. |
| • F He, C Sullender, H Zhu, M Williamson, X Li,Z Zhao, T Jones, C Xie, A Dunn and L Luan (2020) Multimodal mapping of neural activity and cerebral blood flow reveals long-lasting neurovascular dissociations after small-scale strokes Science Advances 6: eaba1933 |
| • Z Zhao, X Li, F He, X Wei, S Lin and C Xie (2019) Parallel, minimally-invasive implantation of ultra-flexible neural electrode arrays Journal of Neural Engineering 16: 35001 |
| • CT Sullender, X Li,Z Zhao, H Zhu, X Wei, C Xie and AK Dunn (2018) Nanoelectronics enabled chronic multimodal neural platform in a mouse ischemic model Journal of Neuroscience Methods 295: 68-76 |
| • X Wei#, L Luan#,Z Zhao#, X Li, H Zhu, O Potnis and C Xie (2018) Nanofabricated ultra-flexible electrode arrays for high-density intracortical recording Advanced Science 5: 1700625 |
| • B Amoozgar, X Wei, J Lee, M Bloomer,Z Zhao, P Coh, F He, L Luan, C Xie, Y Han (2017) A novel flexible microfluidic meshwork to reduce fibrosis in glaucoma surgery Plos One 12: e0172556 |
| • L Luan#, X Wei#,Z Zhao#, JJ Siegel, O Potnis, CA Tuppen, S Lin, S Kazmi, RA Fowler, S Holloway, AK Dunn, RA Chitwood, C Xie (2017) Ultraflexible nanoelectronic probes form reliable, glial scar–free neural integration Science Advances 3: e1601966 |
| • Z Zhao#, L Luan#, X Wei, H Zhu, X Li, S Lin, JJ Siegel, RA Chitwood, C Xie (2017) Nanoelectronic Coating Enabled Versatile Multifunctional Neural Probes Nano Letters 17: 4588–4595 |
| • R Liu#,Z Zhao#, A Argento, Q Fang, JF Lo (2015) Compact Non-invasive Frequency Domain Lifetime Deifferentiation of Type I vs. III Collagen Sensors and Actuators B: Chemical 219: 283-293 |
| • Z Zhao, MA Ameen, K Duan, G Ghosh and JF Lo (2015) On chip Porous Microgel Generation and Microfluidic Enhanced VEGF Detection Biosensors and Bioelectronics 74: 305-312 |
| • Q Yang,Z Zhao, Ben Q. Li and Y Ding (2015) Numerical Analysis of the Rayleigh-Taylor Instability in an Electric Field Journal of Fluid Mechanics 2016: 397-434 |
| • Z Li, D Hu,Z Zhao, M Zhou, LP Lee, JF Lo (2014) Balancing Diffusion and Convection in a Spiral Oxygen Gradient Modulates Fibroblast VEGF Biomedical Microdevices 17: 14 |
| • JF Lo, Y Wang, Z Li,Z Zhao, D Hu, DT Eddington, J Oberholzer (2013) Quantitative and Temporal Control of Oxygen Microenvironment at the Single Islet Level Journal of Visualized Experiments 81: e50616 |
