陈超湛

博士、讲师

研究领域：微纳机电器件、微流控传感器、数值计算

办公地点：创新大楼A719

电子邮箱：chenchaozhan@gzhu.edu.cn

ResearchGate：https://www.researchgate.net/profile/Chaozhan-Chen

个人简历：

陈超湛，工学博士，研究方向包括微尺度流动调控、多物理场数值计算、电化学传感界面设计及微流控检测平台开发。发表研究论文20余篇，以第一作者/通讯作者在Biosens. Bioelectron.、Anal. Chem.、Anal. Chim. Acta等权威期刊发表SCI收录论文13篇，指导/协助指导硕士生6人。主持广州市青年博士启动项目1项，参与国家重点研发计划项目、国家自然科学基金面上基金等纵向科研项目3项。中国微米纳米技术学会会员，担任Anal. Chem.、Microfluid. Nanofluid.、Anal. Methods等国际期刊审稿人。

教育背景：

◆ 2019-2023   哈尔滨工业大学   力学   博士

◆ 2016-2019   哈尔滨工业大学   机械工程   硕士

◆ 2012-2016   郑州大学   机械工程及自动化   学士

职业经历：

◆ 2024-至今   广州大学   机械与电气工程学院   讲师

教授课程：

《机械制图II》、《机械制造技术》等

主持/参与的研究项目：

◆ 广州市教育局青年博士启动项目，202411079，2024-2026，主持

◆ 国家重点研发计划项目，2024YFD2100203，2024-2027，参与

◆ 国家自然科学基金面上项目，32171400，2022-2025，参与

◆ 深圳市科创委学科布局项目，JCYJ20200109112801728，2021-2024，参与

研究成果：

1. 已发表学术论文

[1] C. Chen, B. Ran, B. Liu, X. Liu, Y. Liu, M. Lan, R. Manasseh, Y. Zhu*. Development of a novel microfluidic biosensing platform integrating micropillar array electrode and acoustic microstreaming techniques. Biosens. Bioelectron., 2022, 36: 262. (JCR Q1, 2022 IF=12.5)

[2] C. Chen, B. Ran, B. Liu, X. Liu, Z. Zhang, Y. Li, H. Li, M. Lan, Y. Zhu*. Multiplexed detection of biomarkers using a microfluidic chip integrated with mass-producible micropillar array electrodes. Anal. Chim. Acta, 2023, 1272: 341450. (JCR Q1, 2023 IF=6.2)

[3] C. Chen, B. Ran, B. Liu, Y. Xiao, G. Tang, T. Shen, J. Liang*, Z. Liang*. Development of an origami microfluidic Paper-Based analytical device for highly sensitive detection of dual biomarkers in artificial saliva. Microchem. J., 2025, 25: 112966. (JCR Q1, 2024 IF=4.9)

[4] T. Shen, Z. Chen, B. Ran, B. Liu, J. Liang, L. Ding*, J. Zan, D. Chen, C. Chen*. AI-assisted Microfluidic Paper-Based Analytical Device with Au-Pt Nanoparticles for Multiplex, Interference-Resistant Quantification of Urinary Biomarkers. Anal. Chem., 2025, 97: 27394. (JCR Q1, 2025 IF=6.7)

[5] C. Chen, B. Ran, B. Liu, X. Liu, J. Jin, Y. Zhu*. Numerical study on a bio-Inspired micropillar array electrode in a microfluidic device. Biosensors, 2022, 12(10): 878. (JCR Q1, 2022 IF=5.7)

[6] Y. Xiao, P. Deng, J. Gao, Z. Liu, H. Lei, C. Song, C. Chen*, Z. Liang*. Study on the reprinting properties of pure titanium powder after selective laser melting under nitrogen gas. Mater. Sci. Eng. A, 2026, 957: 149950. (JCR Q1, 2025 IF=7)

[7] C. Chen, B. Ran, Z. Wang, H. Zhao, M. Lan, H. Chen* and Y. Zhu*. Development of micropillar array electrodes for highly sensitive detection of biomarkers. RSC Adv., 2020, 10: 41110. (JCR Q2, 2020 IF=3.1)

[8] C. Chen, R. Ye, Z. Chen, J. Ye, B. Ran, B. Liu, J. Liang, J. Huang* and T. Shen*. A microfluidic paper-based analytical device based on a surface-modified screen-printed electrode Pt-Pd/RGO nanocomposite for glucose detection in urine. Anal. Methods, 2025a, 17: 6326. (JCR Q2, 2025 IF=2.6)

[9] Z. Liang, B. Zhong, C. Chen*, Z. Chen, R. Ye, J. Ye, B. Ran, B. Liu, Y. Xiao*, J. Liang and T. Shen. N-doped mesoporous carbon spheres/Pt–Pd nanocomposite-based amperometric biosensors for sensitive hydrogen peroxide and glucose detection in beverages and fruit juices. Anal. Methods, 2025b, 17: 6496. (JCR Q2, 2025 IF=2.6)

[10] Z. Liang, G. Yang, Z. Chen, B. Zhong, B. Ran, B. Liu, J. Liang, T. Shen, D. Chen* and C. Chen*. Quantification of Nitrite in Beverages and Pickled Foods with a High-Sensitivity Amperometric Biosensor Enhanced by a Multilayer Perceptron Neural Network. Anal. Methods, 2026, 17: 6496-6506. (JCR Q2, 2025 IF=2.6)

[11] D. Chen, Z. Fang, Y. Zhou, Z. Zeng, J. Liang, B. Zhu and C. Chen*. Cascade signal amplification-based fluorescent biosensor utilizing exonuclease III and self-locking DNAzyme synergy for microRNA detection. Analyst, 2025, 150, 5023. (JCR Q2, 2025 IF=3.3)

[12] D. Chen, B. Zhu, Y. Zhou, Z. Fang, Z. Zhu and C. Chen* and T. Shen*. Dual-mode CRISPR/Cas12a-mediated alkaline phosphatase detection (CAD) biosensor. Anal. Methods, 2026b, 18: 1239. (JCR Q2, 2025 IF=3.3)

[13] J. Huang, H. Zhou, W. Huang, X. Peng, S. Fan, G. Huang, C. Chen* and J. Gou*. Design and Crashworthiness Analysis of Novel Petal-Inspired Pentagonal Fractal Structure. Int. J. Struct. Stab. Dyn., 2025, 2750028. (JCR Q2, 2025 IF=3.4)

[14] B. Ran, B. Liu, C. Chen, W. Tong, J. Shi, J. Du, Z. Yu, S. Bai, H. Chen, Y. Zhu. Acoustic micromixing in a serpentine channel with sharp teeth for controllable nanomaterial synthesis. Chem. Eng. J., 2025, 504: 159094. (JCR Q1, 2024 IF=13.4)

[15] B. Liu, C. Chen, B. Ran, L. Shi, J. Wei, J. Jin* and Y. Zhu*. Numerical Investigation of Flow Patterns and Mixing Characteristics in a 3D Micromixer with Helical Elements over Wide Reynolds Numbers. Adv. Theory Simul., 2023, 6: 2200671. (JCR Q2, 2023 IF=2.9)

2. 已授权发明专利

[1] 朱永刚，陈华英，陈超湛，冉斌，刘波. 发明专利，图案化电极及其制备方法和应用（专利号:ZL202011622339.7）

[2] 朱永刚，陈超湛，冉斌，刘波，刘校璇. 发明专利，一种集成声波微流的电化学微流控检测芯片（专利号: ZL202210688730.X）

[3] 朱永刚，陈超湛，冉斌，刘波，刘校璇. 发明专利，一种集成声波微流和微柱阵列电极技术的电化学检测芯片（专利号: ZL202210687456.4）

[4] 朱永刚，刘波，金晶，冉斌，陈超湛. 发明专利，一种负载纳米金属颗粒的碳纳米管纳米复合材料连续可控合成方法及微流控合成平台（专利号: ZL202310820270.6）

3. 学术会议

[1] 陈超湛，口头报告，第八届微流控技术应用创新论坛，2025年8月2-4日，广东广州

[2] 陈超湛，口头报告，微纳器件与系统创新论坛，2025年5月9-11日，江苏苏州

[3] 陈超湛，邀请报告，第七届微流控技术应用创新论坛，2024年12月6-8日，广东深圳

[4] Chaozhan Chen, Poster Presentation, The Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2022), 23-27 October 2022, Hangzhou, China.

[5] Chaozhan Chen, Poster Presentation, The Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2021), 10-14 October 2021, California, USA.

[6] Chaozhan Chen, Oral Presentation, The 3rd International Conference of Microfluidics, Nanofluidics and Lab-on-a-Chip (ICMFLOC 2020), 26-28 June 2020, Shenzhen, China.