Your search keyword '"Wang, Liyue"' showing total 2 results

1. Contact Separation Triboelectric Nanogenerator Based Neural Interfacing for Effective Sciatic Nerve Restoration.

Author

Zhou, Mi, Huang, Mingkun, Zhong, Hao, Xing, Cong, An, Yang, Zhu, Rusen, Jia, Zeyu, Qu, Haodong, Zhu, Shibo, Liu, Song, Wang, Liyue, Ma, Hongpeng, Qu, Zhigang, Ning, Guangzhi, and Feng, Shiqing

Subjects

SCIATIC nerve, NEURAL stimulation, PERIPHERAL nerve injuries, ENERGY harvesting, ELECTRIC stimulation, REPAIRING, BRAIN-computer interfaces

Abstract

Peripheral nerve injuries represent one of the most common causes of permanent disabilities. Therapeutic electrical stimulation has been widely used in neural regeneration for decades. Combined with the implantation of a nerve cuff, several outcomes have proven effectiveness and feasibility in neuroprosthetic applications. However, the current electrical stimulation strategy fails to complete nerve repair. There is a lack of research on long‐term implantable nanogenerators in the neurostimulation scenario. Especially considering many disease models, those devices may not reach the in vitro simulative working setting. Thus, an implanted sciatic nerve stimulation system that spontaneously generates biphasic electric pulses in response to rats' movement is developed. The electric signals generated by this device could stimulate injured sciatic nerve by cuff electrode. This work introduces an implantable self‐regulated neural electrical stimulation system generated by a contact separation triboelectric nanogenerator with a nerve cuff electrode and compares it with chronic therapeutic electrical stimulation for sciatic nerve restoration effect. Neural function restoration is observed in gait and histological analysis. Moreover, the upregulation of growth associated protein 43 can be a protentional target. This could have potential clinical application in facilitating closed‐loop energy harvesting for long‐term electrical stimulation. [ABSTRACT FROM AUTHOR]

Published

2022

2. NaCl-responsive ROS scavenging and energy supply in alkaligrass callus revealed from proteomic analysis.

Author

Zhang, Yongxue, Zhang, Yue, Yu, Juanjuan, Zhang, Heng, Wang, Liyue, Wang, Sining, Guo, Siyi, Miao, Yuchen, Chen, Sixue, Li, Ying, and Dai, Shaojun

Subjects

ENERGY harvesting, POWER resources, CALLUS, BETAINE, SOMATIC embryogenesis, PROTEIN synthesis, CELLULAR signal transduction, CROP growth

Abstract

Background: Salinity has obvious effects on plant growth and crop productivity. The salinity-responsive mechanisms have been well-studied in differentiated organs (e.g., leaves, roots and stems), but not in unorganized cells such as callus. High-throughput quantitative proteomics approaches have been used to investigate callus development, somatic embryogenesis, organogenesis, and stress response in numbers of plant species. However, they have not been applied to callus from monocotyledonous halophyte alkaligrass (Puccinellia tenuifora). Results: The alkaligrass callus growth, viability and membrane integrity were perturbed by 50 mM and 150 mM NaCl treatments. Callus cells accumulated the proline, soluble sugar and glycine betaine for the maintenance of osmotic homeostasis. Importantly, the activities of ROS scavenging enzymes (e.g., SOD, APX, POD, GPX, MDHAR and GR) and antioxidants (e.g., ASA, DHA and GSH) were induced by salinity. The abundance patterns of 55 salt-responsive proteins indicate that salt signal transduction, cytoskeleton, ROS scavenging, energy supply, gene expression, protein synthesis and processing, as well as other basic metabolic processes were altered in callus to cope with the stress. Conclusions: The undifferentiated callus exhibited unique salinity-responsive mechanisms for ROS scavenging and energy supply. Activation of the POD pathway and AsA-GSH cycle was universal in callus and differentiated organs, but salinity-induced SOD pathway and salinity-reduced CAT pathway in callus were different from those in leaves and roots. To cope with salinity, callus mainly relied on glycolysis, but not the TCA cycle, for energy supply. [ABSTRACT FROM AUTHOR]

Published

2019