Publications
S. Kato , D. W. Carlson, A. Q. Shen, Y. Guo*, “Twisted Fiber Microfluidics: A Cutting-Edge Approach to 3D Spiral Devices”, Microsystems & Nanoengineering10(1) (2024)
T. Saizaki, M. Kubo, Y. Sato, H. Abe, T. Ohshiro, H. Mushiake, F. Sorin, Y. Guo*, The Development of Aptamer-Coupled Microelectrode Fiber Sensors (apta-μFS) for Highly Selective Neurochemical Sensing. Analytical Chemistry 95(17) (2023),pp. 6791-6800
Y. Sato , Y. Guo*, Shape-Memory-Alloys Enabled Actuatable Fiber Sensors via the Preform-to-Fiber Fabrication. ACS Applied Engineering Materials 1 (2023),pp.822-831
J. Wu, Y. Sato,Y. Guo*, Microelectronic fibers for multiplexed sweat sensing. Analytical and Bioanalytical Chemistry 415(2023),pp.4307-4318
R. Nishimoto, Y. Sato, J. Wu, T. Saizaki, M. Kubo, M. Wang, H. Abe, I. Richard, T. Yoshinobu, F. Sorin, Y. Guo*,Thermally Drawn CNT-Based Hybrid Nanocomposite Fiber for Electrochemical Sensing.Biosensors 12(8) (2022), pp.559
T. Iwama, Y. Guo*, S. Handa, Kumi Y. Inoue, T. Yoshinobu, F. Sorin, H. Shiku,Thermally-Drawn Multi-Electrode Fibers for Bipolar Electrochemistry and Magnified Electrochemical Imaging.Advanced Material Technologies 7(5) (2021),2101066
H. Abe, T. Iwama, Y. Guo*, Light in Electrochemistry. Electrochem 2(3) (2021), pp.472-489
Y. Guo*, C.F. Werner, S. Handa, M. Wang, T. Ohshiro, H. Mushiake, T. Yoshinobu, Miniature multiplexed label-free pH probe in vivo. Biosensors and Bioelectronics 174 (2021), 112870
プレスリリース:生体への適用が可能なpH可視化プローブの開発 脳深部におけるpHのリアルタイム観察に成功(令和2年12月21日)
Press Release: Eavesdropping on the pH Levels Inside the Brain (2020/12/22)
S. Jiang, D. C. Patel, J. Kim, S. Yang, W. A. Mills, Y. Zhang, K. Wang, Z. Feng, S. Vijayan, W. Cai, A. Wang, Y. Guo, I. F. Kimbrough, H. Sontheimer, X. Jia, Spatially expandable fiber-based probes as a multifunctional deep brain interface. Nature Communications 11 (2020), article number: 6115.
Y. Guo*, C.F. Werner, A. Canales, L. Yu, X. Jia, P. Anikeeva and T. Yoshinobu, Polymer-fiber-coupled field-effect sensors for label-free deep brain recordings. PLOS ONE 15 (2020) article no.: e0228076.
T. Yoshinobu, D. Sato, Y. Guo, C. F. Werner and K. Miyamoto, Modeling of the Return Current in a Light-Addressable Potentiometric Sensor. Sensors 19 (2019), article no.: 4566 (a part of the Special Issue on Light-Addressing and Chemical Imaging Technologies for Electrochemical Sensing
Y. Guo*, J. Shan, B. Grena, I. Kimbrough, E. Thompson, Y. Fink, H. Sontheimer, T. Yoshinobu and X. Jia*, Polymer composite with carbon nanofibers aligned during the thermal drawing as a microelectrode for chronic neural interfaces. ACS Nano 11(2017), pp. 6574-6585.
L. Yu, H. Xuan, Y. Guo, A. L. Chin, R. Tong, G. Pickrell, A. Wang, and X. Jia*, Porous polymer optical fiber fabrication and potential biomedical application. Optical Material Express 7 (2017), pp.1813-1819.
S. Park, Y. Guo, X. Jia, H. K. Choe, B. Grena, J. Kang, J. Park, C. Lu, A. Canales, R. Chen, Y. S. Yim, G. B. Choi, Y. Fink and P. Anikeeva*, One-step optogenetics with multifunctional flexible polymer fibers. Nature Neuroscience 20 (2017), pp.612–619.
Y. Guo*, K. Miyamoto, T. Wagner, M. J. Schöning and T. Yoshinobu, Device simulation of the light-addressable potentiometric sensor for the investigation of the spatial resolution. Sensors and Actuators B 204 (2014) pp.659-665.
Y. Guo*, K. Seki, K. Miyamoto, T. Wagner, M. J. Schöning and T. Yoshinobu*, A novel photoexcitation method for the light-addressable potentiometric sensor with a higher spatial resolution. Applied Physics Express 7 (2014) 067301.
Y. Guo*, K. Miyamoto, T. Wagner, M. J. Schöning and T. Yoshinobu, Theoretical study and simulation of light-addressable potentiometric sensors, Physica Status Solidi A 211 (2014) pp.1467-1472.
Y. Guo*, K. Seki, K. Miyamoto, T. Wagner, M. J. Schöning and T. Yoshinobu*, Device simulation of the light-addressable potentiometric sensor with a novel photoexcitation method for a higher spatial resolution. Procedia Engineering 87(2014), pp.456-459.
K. Miyamoto*, K. Seki, Y. Guo, T. Wagner, M. J. Schöning and T. Yoshinobu, Enhancement of the spatial resolution of the chemical imaging sensor by a hybrid fiber-optic illumination. Procedia Engineering 87 (2014), pp. 612-615.