Zhejiang University, China
Dr. Xuhua Wang is an accomplished researcher recognized for influential contributions to neuroscience, regenerative medicine, spinal cord injury repair, and advanced biomedical technologies. Affiliated with Zhejiang University, Dr. Wang has established a distinguished scientific reputation through innovative studies integrating neural regeneration, biomaterials, gene delivery, and artificial intelligence-based therapeutic design. Their scholarly achievements include 2,855 citations, an h-index of 23, and an
i10-index of 27, reflecting sustained academic impact and international recognition. Dr. Wang’s publications in prestigious journals such as Nature, Cell, and Neuron demonstrate excellence in translational neuroscience and clinical innovation. Through collaborations with renowned global scientists and institutions, the researcher has contributed significantly to advancing functional recovery therapies and neural circuit restoration. Their interdisciplinary expertise continues to influence emerging biomedical strategies aimed at improving neurological healthcare and regenerative treatment methodologies worldwide.
Professional Profile
Education
Dr. Xuhua Wang possesses a strong interdisciplinary academic foundation in neuroscience, biomedical engineering, regenerative medicine, and molecular therapeutics. Their educational development reflects extensive specialization in neural regeneration, fluorescence bioimaging, drug delivery systems, and advanced translational biomedical research. Through academic training and continuous scientific engagement, Dr. Wang cultivated expertise in corticospinal circuitry, neurobiology, nanotechnology-assisted therapeutics, and biomaterials engineering. Association with Zhejiang University further strengthened their research-oriented academic background and exposure to high-level scientific innovation. The combination of theoretical knowledge and laboratory-based experience has enabled Dr. Wang to pursue groundbreaking investigations addressing spinal cord injury recovery and emerging therapeutic technologies in neuroscience.
Professional Experience
Dr. Xuhua Wang has accumulated extensive research experience in neuroscience, regenerative medicine, and biomedical innovation through collaborations with internationally recognized institutions and scientists. Their professional journey includes contributions to spinal cord injury repair, neural pathway reconstruction, advanced hydrogel development, and targeted therapeutic delivery systems. Collaborative research associations with Boston Children’s Hospital and other leading biomedical centers have enhanced their scientific exposure and interdisciplinary expertise. Dr. Wang has actively participated in high-impact experimental studies involving neural regeneration, AI-assisted biomedical applications, and translational medicine. Their professional experience demonstrates strong leadership in conducting innovative research with significant clinical and scientific relevance.
Research Interest
Dr. Xuhua Wang’s research interests focus primarily on spinal cord injury repair, stroke rehabilitation, neural regeneration, biomaterials engineering, and targeted drug and gene delivery systems. Their investigations explore corticospinal tract regeneration, extracellular vesicle therapies, hydrogel-based neural repair technologies, and advanced fluorescence bioimaging techniques. Additionally, Dr. Wang demonstrates growing interest in integrating artificial intelligence for AAV capsid engineering and precision therapeutic design. The interdisciplinary nature of their research combines neuroscience, nanomedicine, molecular biology, and biomedical engineering to develop innovative treatment approaches for neurological disorders. Their scientific interests continue to contribute toward improving functional recovery and regenerative healthcare strategies worldwide.
Award and Honor
Dr. Xuhua Wang has earned significant academic recognition through a highly influential publication record, exceptional citation performance, and impactful scientific contributions in neuroscience and regenerative medicine. With 2,855 total citations, 1,594 citations since 2021, an h-index of 23, and an i10-index of 27, Dr. Wang demonstrates sustained international scholarly influence. Publications in prestigious journals including Nature, Cell, and Nature Communications reflect the quality and significance of their research achievements. Their scientific accomplishments and collaborations with globally recognized researchers highlight professional excellence, innovation, and outstanding contributions to translational neuroscience and biomedical advancement.
Conclusion
Dr. Xuhua Wang has demonstrated exceptional scientific excellence through impactful research in neuroscience, regenerative medicine, and biomedical engineering. Their influential publications, strong citation metrics, and innovative interdisciplinary contributions highlight significant global academic impact. Dr. Wang continues to advance translational healthcare research with remarkable dedication, innovation, and scientific leadership.
Publications Top Noted
Title: Short hairpin RNA against PTEN enhances regenerative growth of corticospinal tract axons after spinal cord injury
Authors: K Zukor, S Belin, C Wang, N Keelan, X Wang, Z He
Year: 2013
Citation: 346
Title: Touch and tactile neuropathic pain sensitivity are set by corticospinal projections
Authors: Y Liu, A Latremoliere, X Li, Z Zhang, M Chen, X Wang, C Fang, J Zhu, et al.
Year: 2018
Citation: 288
Title: Deconstruction of corticospinal circuits for goal-directed motor skills
Authors: X Wang, Y Liu, X Li, Z Zhang, H Yang, Y Zhang, PR Williams, et al.
Year: 2017
Citation: 245
Title: Restoration of skilled locomotion by sprouting corticospinal axons induced by co-deletion of PTEN and SOCS3
Authors: D Jin, Y Liu, F Sun, X Wang, X Liu, Z He
Year: 2015
Citation: 231
Title: A sensitized IGF1 treatment restores corticospinal axon-dependent functions
Authors: Y Liu, X Wang, W Li, Q Zhang, Y Li, Z Zhang, J Zhu, B Chen, PR Williams, et al.
Year: 2017
Citation: 225