Fangyi Cheng, Jian Shen, Bo Peng, Yuede Pan, Zhanliang Tao, Jun Chen*. Lithium-air batteries: something from nothing.ġ2. Fangyi Cheng*, Tianran Zhang, Yi Zhang, Jing Du, Xiaopeng Han, Jun Chen*.Įnhancing electrocatalytic oxygen reduction on MnO2 with vacancies.Īngew. Recycling application of Li-MnO2 batteries as rechargeable lithium-air batteries.Īngew. Yuxiang Hu, Tianran Zhang, Fangyi Cheng*, Qing Zhao, Xiaopeng Han, Jun Chen*. Stabilizing nickel-rich layered oxide cathode by magnesium doping for rechargeable lithium-ion batteries.ĩ. Hang Li, Pengfei Zhou, Fangming Liu, Haixia Li, Fangyi Cheng*, Jun Chen. Phase and composition controllable synthesis of cobalt manganese spinel nanoparticles towards efficient oxygen electrocatalysis.Ĩ. Chun Li, Xiaopeng Han, Fangyi Cheng*, Yuxiang Hu, Chengcheng Chen, Jun Chen*. Rechargeable aqueous zinc-manganese dioxide batteries with high energy and power densities.ħ. Ning Zhang, Fangyi Cheng*, Junxiang Liu, Liubin Wang, Xinghui Long, Xiaosong Liu, Fujun Li, Jun Chen*. Ning Zhang, Fangyi Cheng*, Yongchang Liu, Qing Zhao, Kaixiang Lei, Chengcheng Chen, Xiaosong Liu, Jun Chen.Ĭation-deficient spinel ZnMn2O4 cathode in Zn(CF3SO3)2 electrolyte for rechargeable aqueous Zn-ion battery. Xingchao Wang, Zhenfeng Shang, Aikai Yang, Qiu Zhang, Fangyi Cheng*, Dianzeng Jia, Jun Chen.Ĭombining quinone cathode and ionic liquid electrolyte for organic sodium-ion batteries.ĥ. Self-supported transition metal-based electrocatalysts for hydrogen and oxygen evolution.Ĥ. Hongming Sun, Zhenhua Yan, Fangming Liu, Wence Xu, Fangyi Cheng*, Jun Chen. Zhenhua Yan, Hongming Sun, **********, Huanhuan Liu, Yaran Zhao, Haixia Li, Wei Xie, Fangyi Cheng*, Jun Chen.Īnion insertion enhanced electrodeposition of robust metal hydroxide/oxide electrodes for oxygen evolutionģ. Nanoporous palladium hydride for electrocatalytic N2 reduction under ambient conditionsĢ. Wence Xu, Guilan Fan, Jialiang Chen, Jinhan Li, Le Zhang, Shengli Zhu, Xuncheng Su, Fangyi Cheng*, Jun Chen. He is among highly cited Chinese researchers by Elsevier and 2018 highly cited researcher by Clarivate Analytics (Web of Science).ġ. He has co-authored more than 200 peer-reviewed journal papers with >20000 citations (H index 71). Cheng's research interests encompass the design, preparation, mechanistic understanding and applications of energy materials, with focus on nonstoichiometric electrode materials for electrocatalysis and batteries. The increased knowledge of PGCCs will offer a completely new paradigm to explore the therapeutic intervention for lethal cancers.Ĭell fusion Endoreplication Polyploid giant cancer cells Recombinatorial reproduction Therapeutic resistance.Ĭopyright © 2021 The Authors. We will discuss the potential opportunities in fighting resistant cancers. In this article, we will review the polyploidy involved in development and inflammation, and the process of PGCCs formation and propagation that benefits to cell survival. Recent work shows that cancer cells can be induced into polyploid giant cancer cells (PGCCs) that leads to reprogramming of surviving cancer cells to acquire resistance. In human, they play a variety of roles in physiology and pathologic conditions and perform the specialized functions during development, inflammation, and cancer. The polyploid cells are due to an increase in DNA content, commonly associated with cell enlargement. However, the underlying mechanisms of such resistance have remained unclear. Therapeutic resistance represents a major cause of death for most lethal cancers.
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