1)智能药物递送系统；

2)界面生物力学电学抗菌行为；

3)微生物基因工程与高价值药物的生物合成；

4)医用多功能植入体界面构建；

5)等离子体界面处理及其生物医学应用。

招生信息：

实验室经费充足，拥有良好的微纳加工及生物实验平台，致力于交叉学科前沿研究的同时积极争取成果转化机会，根据发展需要：

欢迎具有药学、生物、医学、物理、化学和生物医学工程等相关背景的学生报考硕士和博士研究生；

有意者请联系gwang@tongji.edu.cn，标题为：XX职位申请+XX单位+姓名。

2022- ，同济大学医学院“青年百人A岗”教授，博士生导师，硕士生导师

2022- ，Professor, School of Medicine, Tongji University

王国敏，入选国家海外高层次青年人才引进计划，先后于南开大学、北京大学、香港城市大学获得本科、硕士、博士学位。现为同济大学医学院界面生物力学电学研究团队负责人。围绕生物医药创新平台设计方向，以第一/通讯作者在Nat. Commun., Adv. Mater., Adv. Sci., Adv. Funct. Mater.等期刊发表论文20多篇，授权3项中国发明专利。获香港政府人才项目奖、国际华人生物材料协会奖。主持国自然优青（海外）项目、上海市领军人才项目、香港医疗卫生研究基金、HK Tech 300创业基金。

Guomin Wang received her BS, MS and PhD from Nankai University, Peking University and City University of Hong Kong, respectively. She joined Tongji University in 2022 and is now leading the group of “biomechanics and bioelectronics at the interface”. She has published more than 20 papers (as first/corresponding author) in journals including Nat. Commun., Adv. Mater., Adv. Sci., and Adv. Funct. Mater. The papers published in Advanced Science and Biomaterials were featured on the journal cover and the latter became an ESI highly-cited paper. Three of her submitted patents have been certified by the Chinese government. She received awards from Hong Kong government and the the Chinese Association for Biomaterials (CAB). For projects, she is principal investigator for National Natural Science Fund for Excellent Young Scientists, Shanghai Lingjun Program, Hong Kong HMRF and HK Tech 300.

Publication：* and # denoting corresponding and co-first authorship, respectively.

1.G. Wang*, K. Tang, W. Jiang, Q. Liao, Y. Li, P. Liu, Y. Wu, M. Liu, H. Wang, B. Li, J. Du, P. K. Chu. Quantifiable Relationship between Antibacterial Efficacy and Electro-Mechanical Intervention on Nanowire Arrays, Advanced Materials, 35: 2212315, 2023.

2.P. Liu, Y. Wu, B. Mehrjou, K. Tang, G. Wang*, P. K. Chu*. Versatile phenol-incorporated nanoframes for in situ antibacterial activity based on oxidative and physical damages. Advanced Functional Materials, 32: 2110635, 2022.

3.G. Wang*, K. Tang, G. M. Wang, Z. Meng, P. Liu, S. Mo, B. Mehrjou, H. Wang, X. Liu*, Z. Wu*, P. K. Chu*. A quantitative bacteria monitoring and killing platform based on electron transfer from bacteria to semiconductor. Advanced Materials, 32: 2003616, 2020.

4.G. Wang, W. Jiang, S. Mo, L. Xie, Q. Liao, L. Hu, Q. Ruan, K. Tang, B. Mehrjou, M. Liu, L. Tong, H. Wang, J. Zhuang, G. Wu, P. K. Chu. Nonleaching antibacterial concept demonstrated by in situ construction of 2D nanoflakes on magnesium. Advanced Science, 1902089, 2020.

5.G. Wang, H. Feng, L. Hu, W. Jin, Q. Hao, A. Gao, X. Peng, W. Li, K. Y. Wong, H. Wang, Z. Li, P. K. Chu. An antibacterial platform based on capacitive carbon-doped TiO2 nanotubes after charging with direct or alternating currents. Nature Communications, 9: 2055, 2018.

6.G. Wang, W. Jin, A. M. Qasim, A. Gao, X. Peng, W. Li, H. Feng, P. K. Chu. Antibacterial effects of titanium embedded with silver nanoparticles based on electron-transfer-induced reactive oxygen species. Biomaterials, 124: 25-34, 2017.

7.S. Mo, B. Mehrjou, K. Tang, H. Wang, K. Huo, A. M. Qasim, G. Wang*, P. K. Chu*. Dimensional-dependent antibacterial behavior on bioactive micro/nano polyetheretherketone (PEEK) arrays. Chemical Engineering Journal, 392: 123736, 2020.

8.P. Liu, G. Wang*, Q. Ruan, K. Tang, P. K. Chu*. Plasma-activated interfaces for biomedical engineering. Bioactive Materials, 6: 2134-2143, 2021.

9.L. Xie#, G. Wang#, H. Wang. Programmed surface on poly(aryl-ether-ether-ketone) initiating immune mediation and fulfilling bone regeneration sequentially. The Innovation, 2: 100148, 2021.