Jinping Luo | Aerospace Information Research Institute, Chinese Academy of Sciences | China
Luo Jinping is an accomplished researcher at the Aerospace Information Research Institute, Beijing, recognized for his impactful contributions at the intersection of neuroscience, biosensing technologies, and advanced microelectrode systems. With 1,748 citations, 91 publications, and an h-index of 20 in Scopus, his work demonstrates strong scientific influence and consistent research productivity. His research interests span aptamer-based biosensors, implantable and flexible microelectrode arrays, neural information decoding, neuromodulation, brain-on-chip systems, and neuroengineering for cognitive restoration. He is skilled in micro/nano-fabrication, biocompatible material integration, neural signal analysis, in vitro neural network modeling, and biosensor development for neurological and biomedical applications. Luo has contributed to advancing technologies for dopamine sensing, sleep-wake dynamics, Alzheimer’s disease models, and deep-brain interface stability, reflecting both innovation and translational potential. His achievements have earned him recognition within the scientific community, including multiple collaborations, extensive citations, and inclusion in high-impact journals such as Nature Communications, Biosensors and Bioelectronics, and Microsystems & Nanoengineering. Overall, Luo Jinping stands as a forward-driven researcher whose multidisciplinary expertise continues to shape the future of neurotechnology and biosensing, with a growing global impact supported by strong publication metrics and ongoing research excellence.
Profiles: Scopus
Featured Publications
1. Luo, J., Liu, J., Lu, Z., Song, Y., Xu, Z., Wang, M., Jia, Q., Lv, S., Wang, Y., & Cai, X. (2025). A movable microfiber establishes a new paradigm for implantable bioelectronics. Science Bulletin.
2. Hua, S., Liu, Y., Luo, J. , Li, S., Jiang, L., Wu, P., Sun, S., Shang, L., Lu, C., Zhang, K., Liu, J., Wang, M., Shi, H., & Cai, X.* (2025). Microelectrode arrays cultured with in vitro neural networks for motion control tasks: Encoding and decoding progress and advances. Microsystems & Nanoengineering.
3. Jia, Q., Xu, Z., Wang, Y., Duan, Y., Liu, Y., Shan, J., Ma, J., Li, Q., Luo, J., Luo, Y., Wang, Y., Duan, S., Yu, Y., & Wang, M., Cai, X. (2025). Targeted-modified multitransm microelectrode arrays simultaneously track dopamine and cellular electrophysiology in nucleus accumbens during sleep–wake transitions. Research, 8. https://doi.org/10.34133/research.0944
4. Shan, J., Xu, W., Luo, J., Xu, Z., Liu, Y., Jia, Q., Lv, S., Duan, Y., Jiao, P., Li, Q., Luo, Y., Ma, Y., Zhang, X., Song, Y., Mi, W., & Cai, X.* (2025). Neuromodulation in the prelimbic cortex of sleep-deprived rats via a bidirectional microelectrode array modified with PtNPs/sorbitol-doped PEDOT:PSS. ACS Applied Electronic Materials. https://doi.org/10.1021/acsaelm.5c01393
5. Liu, Y., Jia, Q., Miao, J., Jiang, L., Shan, J., Wang, Y., Lv, S., Li, Q., Liu, Y., Jiao, P., Song, Y., Luo, J., & Cai, X.* (2025). Ultra-biocompatible PEDOT:DSS-modified dual-mode bi-directional microelectrode arrays reveal phase-locking dynamics across sleep–wake. Biosensors and Bioelectronics, 290, Article 117973. https://doi.org/10.1016/j.bios.2025.117973