教育背景
1999-2004 浙江大学生物医学工程系 学士
2004-2006 浙江大学生物医学工程系 硕士
2006-2007 荷兰特文特大学电气工程 硕士
2007-2011 荷兰特文特大学电气工程 博士
2013-2015 荷兰特文特大学MESA+纳米技术研究院 博士后
教学工作
微机电系统设计基础(本硕博)、数值分析(本)、微流控技术及应用(硕博)
研究领域
微纳传感器、器官芯片、微流控芯片及其在生物医学、环境监测等领域的应用
近期发表文章
[1]. F. Xu, H. Jin, Z. Zhou, A. Jiang, L. Liu, H. Fang, Q. Gao, Y. Su, Z. Ding, Q. Chen, S. Chen*, D. Sun*, Surface Tension Confined Digital Light Processing for Hydrogel Printing with High Availability, Journal of Manufacturing Processes, 2025, 136, 370-379.
[2]. J. Yang, F. Xu, H. Jin, Z. Zhou, H. Wu, W. Zhang, M. Xue, B. Qiu, Q. Gao, B. Lin, S. Chen*, D. Sun*, A 3D Hydrogel Scaffold with Adjustable Interlayer Spacing for the Formation of Compact Myocardial Tissue, Journal of Applied Polymer Science, 2025, 142(1), e56311.
[3]. Y. Jiang, M. Xue, L. Ou, B. Lin, W. Kong, S. Chen*, and D. Sun*, Rapid Analysis Method for Cardiac Tissue Contraction Synchrony in Wide View Field Based on Variations in Optical Field Brightness, Tissue Engineering and Regenerative Medicine, 2025, 22, 211-224.
[4]. H. Wu, F. Xu, H. Jin, M. Xue, W. Zhang, J. Yang, B. Qiu, B. Lin, Q. Gao, S. Chen*, D. Sun*, 3D Nanofiber-Assisted Embedded Extrusion Bioprinting for Oriented Cardiac Tissue Fabrication, ACS Biomaterials Science & Engineering, 2024, 10(11), 7256-7265
[5]. Y. You, F. Xu, L. Liu, S. Chen, Z. Ding*, D. Sun*, Construction of thick myocardial tissue through layered seeding in multi-layer nanofiber scaffolds, Polymers, 2024, 16(18), 2664
[6]. A. Jiang, F. Xu, H. Fang, C. Zhang, S. Chen*, D. Sun*, Direct ink writing of liquid metal on hydrogel through oxides introduction, Langmuir, 2024, 40, 19830-19838.
[7]. L. Ou, T. Wu, B. Qiu, H. Jin, F. Xu, H. Wu, W. Zhang, M. Xue, Z. Zhou, B. Lin, D. Sun*, S. Chen*, Real-time wireless sensing of cardiomyocyte contractility by integrating magnetic microbeam and oriented nanofibers, ACS Applied Materials & Interfaces, 2024, 16, 45861-45870.
[8]. W. Zhang, S. You, Y. Zhou, L. Ou, H. Jin, F. Xu, B. Qiu, B. Lin, Y. Yang, D. Sun*, S. Chen*, Flexible Microelectrode Arrays Based on Vacuum filling for Electrophysiology Sensing of Cardiomyocytes, ACS Applied Electronic Materials, 2024
[9]. F. Xu, H. Jin, H. Wu, A. Jiang, B. Qiu, L. Liu, Q. Gao, B. Lin W. Kong, S. Chen*, D. Sun*, Digital Light Processing Printed Hydrogel Scaffolds with Adjustable Modulus, Scientific Report, 2024, 14, 15695.
[10]. F. Xu, H. Jin, L. Liu, Y. Yang, J. Cen, Y. Wu, S. Chen*, D. Sun*, Architecture design and advanced manufacturing of heart-on-a-chip: scaffolds, stimulation and sensors, Microsystems & Nanoengineering, 2024, 10, 96.
[11]. C. Zhang, Y. You, Y. Xie, L. Han, D. Sun, S. Chen*, Salt gradient enhanced sensitivity in nanopores for intracellular calcium ion detection, Talanta, 2024, 276, 126261.
[12]. Y. You, C. Zhang, Z. Guo, F. Xu, D. Sun, J. Xia, S. Chen*, Lung-on-a-chip composed of styrene-butadiene-styrene nano-fiber/porous PDMS composite membranes with cyclic triaxial stimulation, Microfluidics and Nanofluidics, 2024, 28, 45.
[13]. B. Qiu, D. Wu, M. Xue, L. Ou, Y. Zheng, F. Xu, H. Jin, Q. Gao, J. Zhuang, J. Cen, Y.C. Su, S. Chen*, D. Sun*, 3D aligned nanofiber scaffold fabrication with trench-guided electrospinning for cardiac tissue engineering, Langmuir, 2024, 40, 4709-4718.
[14]. L. Liu, F. Xu, H. Jin, B. Qiu, J. Yang, W. Zhang, Q. Gao, B. Lin, S. Chen*, D. Sun*, Integrated Manufacturing of Suspended and Aligned Nanofibrous Scaffold for Structural Maturation and Synchronous Contraction of HiPSC-Derived Cardiomyocytes, Bioengineering, 2023,10, 702. (Best paper awards)
[15]. Y. Wu, Z. Wang, J. Xu, Z. Chen, G. Zeng, Z. Xu, J. Zhou, X. Chen, Q. Tan, Q. Chen, Y. Yang, S. Chen, L. Wang, Dezhi Wu*, Direct-writing of liquid metal onto an electrospun graphene oxide composite polymer nanofibers membrane for robust and stretchable electrodes, Advanced Materials Technologies, 2023, 202201935.
[16]. Z. Chen, G. Wang, Y. Yang, J. Mao, Z. Chen, S. Chen, L. Wang, D. Wu*, Fabrication of flexible organic field effect transistors with high carrier mobility via sheath gas-assisted direct writing Poly(3-hexylthiophene) solution, Organic Electronics, 2023, 106813.
[17]. J. Zhang, H. Yao, J. Mo, S. Chen, Y. Xie, S. Ma, R. Chen, T. Luo, W. Ling, L. Qin, Z. Wang, W. Zhou, Finger-inspired rigid-soft hybrid tactile sensor with superior sensitivity at high frequency, Nature Communication, 2022, 5076
[18]. B. Qiu, X. Chen, F. Xu, D. Wu, Y. Zhou, W. Tu, H. Jin, G. He, S. Chen*, D. Sun*, Nanofiber self-consistent additive manufacturing process for 3D microfluidics, Microsystems & Nanoengineering, 2022, 102, 239-246.
[19]. D. Geng, S. Chen, R. Chen, Y. You, C. Xiao, C. Bai, T. Luo, W. Zhou*, Tunable Wide Range and High Sensitivity Flexible Pressure Sensors with Ordered Multilevel Microstructures, Advanced Materials Technologies, 2021, 2101031.
[20]. Y. Li, W. Zhou, C. Liu, D. Geng, J. Dai, Y. Xie, S. Chen, T. Luo, Z. Shen, Fabrication and characteristic of flexible dry bioelectrodes with microstructures inspired by golden margined century plant leaf, Sensors and Actuators A: Physical, 2021, 321, 112397.
[21]. S. Chen*, C. Bai, C. Zhang, D. Geng, R. Liu, Y. Xie, W. Zhou, Flexible piezoresistive 3D force sensor based on interlocked structures, Sensors and Actuators A: Physical, 2021, 330, 112857.
[22]. C. Zhang, W. Zhou*, D. Geng, C. Bai, W. Li, S. Chen*, T. Luo, L. Qin, Y. Xie, Laser direct writing and characterizations of flexible piezoresistive sensors with microstructures, Opto-Electronic Advances, 2021, 4(4), 200061.
[23]. 白成,耿达,周伟,陈松月*,高性能电阻型柔性压力传感器研究进展,微纳电子技术,2021, 8, 659-668.
[24]. S. Chen*, H. Chen, J. Zhang, H. Dong, K. Zhan, Y. Tang, Glass nanopore ionic sensor for surface charge analysis, RSC Advances, 2020, 10, 21615-21620.
[25]. S. Chen*, H. Dong, J. Yang, Surface potential/charge sensing techniques and applications, Sensors, 2020, 20, 1690.
[26]. Y. Tang, L. Cao, K. Zhan, Y. Xie, D. Sun, X. Hou*, S. Chen*, Performance analysis of solid-state nanopore chemical sensor, Sensors and Actuators B: Chemical, 2019, 286, 315-320.
[27]. L. Min, H. Pan, S. Chen*, C. Wang, N. Wang*, J. Zhang, Y. Cao*, X. Chen, X. Hou*, Recent progress in bio-inspired electrospun materials, Composites Communications, 2019, 11, 12-20.
[28]. S. Chen*, Y. Tang, K. Zhan, D. Sun, X. Hou*, Chemiresistive Nanosensors with Convex/Concave Structures, Nano Today, 2018, 20, 84-100.
[29]. Z. Sheng, H. Wang, Y. Tang, M. Wang, L. Huang, L. Min, H. Meng, S. Chen, L. Jiang, X. Hou, Liquid Gating Elastomeric Porous System with Dynamically Controllable Gas/Liquid Transport, Science Advances, 2018, 4 (2), eaao6724.
[30]. F. Wu#, S. Chen#, B. Chen#, M. Wang, L. Min, J. Alvarenga, J. Ju, A. Khademhosseini, Y. Yao, Y.S. Zhang, J. Aizenberg, and X. Hou*, Bioinspired Universal Flexible Elastomer-Based Microchannels, Small, 2018, 14, 1702710. (#equal contribution)
[31]. 谢歆雯,黄立志,陈松月,侯旭,仿生设计:沟通生物与新材料的桥梁,张江科技评论,2017.3,35-38.
[32]. L. Min#, S. Chen#, Z. Sheng, H. Wang, F. Wu, M. Wang, X. Hou*, Development and application of bio-inspired and biomimetic microfluidics, Acta Physica Sinica, 65, 178301, 2016 (#equal contribution)
[33]. Y. Xie*, Y. Zhou, W. Xi, F. Zeng, S. Chen, Fabrication of a cell fixation device for robotic cell microinjection, Micromachines, 2016, 7, 131.
[34]. S. Chen*, J.W. van Nieuwkasteele, A. van den Berg, J.C.T. Eijkel, Ion-step method for surface potential sensing of silicon nanowires, Analytical Chemistry, 2016, 88, 7890-7893.
[35]. D. Narezo-Guzman, Y. Xie, S. Chen, D. Fernandez Rivas, C. Sun, D. Lohse, G. Ahlers, Heat-flux enhancement by vapour-bubble nucleation in Rayleigh-Benard turbulence, Journal of Fluid Mechanics,2016, 787, 331-366.
[36]. S. Chen, A. van den Berg, E.T. Carlen, Sensitivity and detection limit analysis of silicon nanowire bio(chemical)sensors, Sensors & Actuators: B. Chemical, 2015, 209, 486-489.
[37]. S. Chen, Y. Xie, A. De, A. van den Berg, E.T. Carlen, Electrical shielding for silicon nanowire biosensor in microchannels, Applied Physics Letters, 2013, 103, 173702.
[38]. S. Chen, J.G. Bomer, E.T. Carlen, A. van den Berg, Al2O3/Silicon nanoISFET with near ideal Nernstian response, Nano Letters, 2011, 11, 2334-2341.
[39]. M. Masood, S. Chen, E.T. Carlen, A. van den Berg, All-(111) Surface Silicon Nanowires: Selective Functionalization for Biosensing Applications, ACS Applied Materials & Interfaces, 2010, 2, 3422-3428.
[40]. S. Chen, J.G. Bomer, W.G. van der Wiel, E.T. Carlen, A. van den Berg, Top-down fabrication of sub-30 nm monocrystalline silicon nanowires using conventional microfabrication, ACS Nano, 2009, 3, 3485-3492.
[41]. H.D. Tong, S. Chen, W.G. van der Wiel, E.T. Carlen, A. van den Berg, Novel top-down wafer-scale fabrication of single crystal silicon nanowires, Nano Letters, 2009, 9, 1015-1022.
[42]. L. Wang, S. Chen, Q. Liu, P. Wang, The application of nanotechnology in the biosensor and biodetection field, Chinese Journal of Sensors and Actuators, 2006, 19, 581-587.
[43]. D. Zhang, S. Chen, L. Qin, R. Li, P. Wang, Research of a new biosensor for detecting Escherichia coli O157:H7 with electrochemical impedance spectroscopy. Chinese Journal of Sensors and Actuators, 2005, 18, 5-9.
获奖情况
被推荐参加第60届林岛诺贝尔奖获得者会议
Viva杂志评为2010年荷兰最杰出的400位年轻女性(Viva400)
福建省引进高层次人才
中国工程前沿杰出青年学者(2023)
科研项目
[1]. 翔安创新实验室培育项目,心肌组织芯片的柔性共体传感技术及应用,2023/12-2025/12,在研,主持
[2]. 国家重点研发计划子课题,功重比10以上航空发动机高温部件健康状态检测传感系统及应用,2022/1-2025/11,在研,负责人
[3]. 国家自然科学基金重点支持项目,面向心肌芯片的柔性传感/激励-3D支架供体制造基础研究,2021/01-2024/12,结题,参与
[4]. 国家重点研发计划,医疗用微纳集成芯片与集成系统,2020/01-2023/12,结题,参与。
[5]. 精密测试技术及仪器国家重点实验室开放课题,基于纳米孔道的高灵敏度生物检测技术,2017/08-2010/08,结题,主持
[6]. 我们校长基金项目,微纳流体的传输与控制及在DNA分子检测中的应用研究,2017/01-2019/12,结题,主持
[7]. 国家自然科学基金青年项目,固态纳米孔阵列DNA 的杂交动力学及应用研究,2017/01-2019/12,结题,主持
[8]. 国家自然科学基金联合基金项目,基于逻辑门的微流控系统设计与3D打印制造基础研究,2016/01-2019/12,结题,参与
[9]. 荷兰Achmea医疗保险公司横向项目,Nanopil2.0,2014/03-2018/03,结题,参与
[10]. 荷兰国家项目NanoNextNL计划出资,NG Nanowire,2010/01-2015/04,结题,参与
[11]. 私人投资项目,Blue Bolus Chip,2008/01-2011/12,结题,参与
