Publications by Citations (Google Scholar)
Cover images
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Book chapters
[B3] Qiyue Sun, Jianghua Pei, Qinyu Li, and Xiaolin Wang*, "Chapter 5: Vascularized microfluidic organ on a chip and its applications" in "Microfluidics and Bio-MEMS: Devices and Applications", pp. 215-256, Jenny Stanford Publishing Pte. Ltd., 2 November 2020.
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[B2] Xiaolin Wang, Duc T. T. Phan, Steven C. George, Christopher C. W. Hughes, and Abraham P. Lee, "Chapter 24: 3D anastomosed microvascular network model with living capillary networks and endothelial cell-lined microfluidic channels" in "3D Cell Culture: Methods and Protocols", pp.325-344, Humana Press,21 June 2017.
[B1] Xiaolin Wang, Shuxun Chen, Dong Sun, “Chapter 16: Robot-aided micromanipulation of biological cells with integrated optical tweezers and microfluidic chip,” in “Micro- and Nanomanipulation Tools”, pp. 393-416, Wiley-VCH, November 2015.
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[B2] Xiaolin Wang, Duc T. T. Phan, Steven C. George, Christopher C. W. Hughes, and Abraham P. Lee, "Chapter 24: 3D anastomosed microvascular network model with living capillary networks and endothelial cell-lined microfluidic channels" in "3D Cell Culture: Methods and Protocols", pp.325-344, Humana Press,21 June 2017.
[B1] Xiaolin Wang, Shuxun Chen, Dong Sun, “Chapter 16: Robot-aided micromanipulation of biological cells with integrated optical tweezers and microfluidic chip,” in “Micro- and Nanomanipulation Tools”, pp. 393-416, Wiley-VCH, November 2015.
Journal papers # Co-first author *Corresponding author
[J22] Zhangjie Li#, Dingyuan Yu#, Chenyang Zhou, Feifan Wang, Kangyi Lu, Yijun Liu, Jiaqi Xu, Lian Xuan, Xiaolin Wang*, Engineering vascularised organoid-on-a-chip: strategies, advances and future perspectives, Biomaterials Translational, 2024, 5(1), 21-32.(WeChat Official Account)
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[J21] Zhangjie Li#, Kai Niu#, Chenyang Zhou, Feifan Wang, Kangyi Lu, Yijun Liu, Lian Xuan and Xiaolin Wang*, Multifunctional cardiac microphysiological system based on transparent ITO electrodes for simultaneous optical measurement and electrical signal monitoring, Lab on a Chip, 2024, 24(7), 1903-1917. (Back cover, WeChat Official Account)
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[J20] Kangyi Lu, Chenyang Zhou, Zhangjie Li, Yijun Liu, Feifan Wang, Lian Xuan and Xiaolin Wang*, Multi-level magnetic microrobots delivery strategy within a hierarchical vascularized organ-on-a-chip, Lab on a Chip, 2024, 24(3), 446-459. (CCTV Report,WeChat Official Account)
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[J19] Chenyang Zhou, Zhangjie Li, Kangyi Lu, Yijun Liu, Lian Xuan, Hongju Mao*, Xiaolin Wang*, Advances in Human Organs-on-Chips and Applications for Drug Screening and Personalized Medicine, Fundamental Research, 2024, DOI:10.1016/j.fmre.2023.12.019. (Invited Review, WeChat Official Account)
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[J18] Ding Wang#, Qinyu Li#, Chenyang Zhou, Zhangjie Li, Kangyi Lu, Yijun Liu, Lian Xuan, Xiaolin Wang*, Dissolvable temporary barrier: a novel paradigm for flexible hydrogel patterning in organ-on-a-chip models, Bio-Design and Manufacturing, 2024, 7(2), 153-166. (WeChat Official Account)
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[J17] Zhangjie Li#, Qinyu Li#, Chenyang Zhou, Kangyi Lu, Yijun Liu, Lian Xuan, Xiaolin Wang*, Organoid-on-a-Chip: Current Challenges, Trends and Future Scope Towards Medicine, Biomicrofluidics, 2023, 17(5), 051505. (Invited Review)
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[J16] Qinyu Li, Kai Niu, Ding Wang, Lian Xuan and Xiaolin Wang*, Low-cost rapid prototyping and assembly of open microfluidic device for 3D vascularized organ-on-a-chip, Lab on a Chip, 2022, 22(14), 2682-2694. (Back cover)(Times Cited: 12)
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[J15] Tao Yue, Da Zhao, Duc T. T. Phan, Xiaolin Wang, Joshua Jonghyun Park, Zayn Biviji, Christopher C. W. Hughes and Abraham P. Lee, A modular microfluidic system based on a multilayered configuration to generate large-scale perfusable microvascular networks, Microsystems & Nanoengineering, 7, 4 (2021).
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[J14] Jianghua Pei, Qiyue Sun, Zhiran Yi, Qinyu Li, Xiaolin Wang*, Recoverable elastic barrier for robust hydrogel patterning with uniform flow profile for organ-on-a-chip applications, Journal of Micromechanics and Microengineering, 2020, 30(3), 035005. (Selected by the Editorial Board as JMM Highlights of 2020)(Times Cited: 49)
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[J13] Yiwei Bai, Jiaojiao Tian, Zude Lin, Minmin You, Jingquan Liu, and Xiaolin Wang*, Development of a High Throughput Micro-Heater Array with Controllable Temperature for Each Heating Unit, Microsystem Technologies, 2020, 26(3), 787-792.
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[J12] Qiyue Sun, Jianghua Pei, Qinyu Li, Kai Niu, Xiaolin Wang*,Reusable standardized universal interface module (RSUIM) for generic organ-on-a-chip applications, Micromachines, 2019, 10(12), 849.
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[J11] Longjun Tang, Wen Hong, Xiaolin Wang, Wenxi Sun, Bin Yang, Meng Wei, Jingwei Pan, and Jingquan Liu, Ultraminiature and Flexible Sensor Based on Interior Corner Flow for Direct Pressure Sensing in Biofluids, Small, 2019, 1900950.
[J10] Xiaolin Wang*, Qiyue Sun, Jianghua Pei, Microfluidic-based 3D engineered microvascular networks and their applications in vascularized microtumor models, Micromachines, 2018, 9(10),493. (Review paper) (Times Cited: 90)
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[J9] Xiaolin Wang#, Da Zhao#, Duc T.T. Phan, Jingquan Liu, Xiang Chen, Bin Yang, Christopher C.W. Hughes, Weijia Zhang * and Abraham P. Lee *, A hydrostatic pressure-driven passive micropump enhanced with siphon-based autofill function, Lab on a Chip, 2018, 18(15), 2167-2177. (Back cover) (Times Cited: 42)
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[J8] Duc T. T. Phan#, Xiaolin Wang#, Brianna M Craver, Agua Sobrino, Da Zhao, Jerry C Chen, Lilian Y.N. Lee, Steven C George, Abraham Lee* and Christopher Hughes*, A vascularized and perfused organ-on-a-chip platform for large-scale drug screening applications, Lab on a Chip, 2017, 17(3), 511-520.(Selected as thematic collection of "Organ-,body-, and disease-on-a-chip systems" as well as "Top 10 most downloaded articles published in Lab on a Chip in 2017") (Times Cited: 279)
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[J7] Xiaolin Wang, Duc T. T. Phan, Da Zhao, Steven C. George, Christopher C. W. Hughes*, and Abraham P. Lee*, An on-chip microfluidic pressure regulator that facilitates reproducible loading of cells and hydrogels into microphysiological system platforms, Lab on a Chip, 2016, 16(5), 868-876.(Times Cited: 41)
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[J6] Xiaolin Wang#, Duc T. T. Phan#, Agua Sobrino, Steven C. George, Christopher C. W. Hughes*, and Abraham P. Lee*, “Engineering anastomosis between living capillary networks and endothelial cell-lined microfluidic channels,” Lab on a Chip, 2016, 16(2), 282-290. (Back cover) (Times Cited: 225)
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[J5] Agua Sobrino#, Duc T. T. Phan#, Rupsa Datta, Xiaolin Wang, Stephanie J. Hachey, Mónica Romero-López, Enrico Gratton, Abraham P Lee, Steven C. George and Christopher C.W. Hughes, "3D microtumors in vitro supported by perfused vascular networks," Scientific Reports, 2016, 6: 31589. (Times Cited: 242)
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[J4] Shuxun Chen, Jinping Cheng, Chi-wing Kong, Xiaolin Wang, Shuk Han Cheng, Ronald A. Li and Dong Sun, “Laser-induced fusion of human embryonic stem cells with optical tweezers,” Applied Physics Letters, 2013, 103(3): 033701.
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[J3] Xiaolin Wang, Shuxun Chen, Yu Ting Chow, Chi-wing Kong, Ronald A. Li and Dong Sun, “A microengineered cell fusion approach with combined optical tweezers and microwell array technologies,” RSC Advances, 2013, 3: 23589-23595.
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[J2] Xiaolin Wang, Xue Gou, Shuxun Chen, Xiao Yan, and Dong Sun, “Cell manipulation tool with combined microwell array and optical tweezers for cell isolation and deposition,” Journal of Micromechanics and Microengineering, 2013, 23(7): 075006. (Times Cited: 49)
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[J1] Xiaolin Wang, Shuxun Chen, Marco Kong, Zuankai Wang, Kevin D. Costa, Ronald A. Li, and Dong Sun, “Enhanced cell sorting and manipulation with combined optical tweezer and microfluidic chip technologies,” Lab on a Chip, 2011,11(21): 3656-3662. (Publishing a top 5 2013 cited Lab on a Chip) (Times Cited: 437)
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Conference papers
[C18] Feifan Wang, Qinyu Li, and Xiaolin Wang*, Sliding microfluidic device for vascularized organ-on-a-chip applications, The 26th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2022), pp.420-421, Hangzhou, China, 2022.
[C17] Ding Wang, Qinyu Li, Kai Niu and Xiaolin Wang*, Dissolvable temporary barrier for robust hydrogel patterning and uniform medium perfusion in organ-on-a-chip applications, The 25th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2021), pp.439-440, Palm Springs, California, USA, 2021.
[C16] Kai Niu, Ding Wang, Qinyu Li, and Xiaolin Wang*, Multi-functional cardiac microphysiological chip for cardiotoxicity applications, The 25th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2021), pp.419-420, Palm Springs, California, USA, 2021.
[C15] Qinyu Li, Kai Niu, and Xiaolin Wang*, Low-cost open microfluidic device for vascularized spheroid-on-a-chip, The 24th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2020), pp. 935-936, Virtual Conference, 2020. (Art in Science Award, Lab on a Chip Report, Front Cover, Wechat Official Account)
[C14] Qiyue Sun, Jianghua Pei, Qinyu Li, Xiang Chen and Xiaolin Wang*, Novel microfluidic perfusion bioreactor for vascularized organ-on-a-Chip, IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM 2019), pp. 1630-1634, Hong Kong, China, 2019.
[C13] Jianghua Pei, Qiyue Sun, and Xiaolin Wang*, A plug-n-play hydrostatic pressure-driven pump module for high-throughput organ-on-a-chip applications, The 22nd International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2018), pp. 1655-1657, Kaohsiung, Taiwan, 2018.
[C12] Xiaolin Wang*, Da Zhao, and Abraham P. Lee*, Enhanced hydrostatic pressure-driven passive micropump with siphon-based autofill function, The 21st International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2017), pp.643-644, Savannah, Georgia, 2017.
[C11] Xiaolin Wang, Duc Phan, Steven C. George, Christopher C. W. Hughes, and Abraham P. Lee, Well plate-based microfluidic platform for high throughput screening of 3D perfused vascularized microtissue, The 6th International Multidisciplinary Conference on Optofluidics (IMCO 2016), Beijing, China, 2016. (Best Paper Award)
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[C10] Xiaolin Wang, Duc Phan, Steven C. George, Christopher C. W. Hughes, and Abraham P. Lee, Pressure regulator for roust gel injection in coupling microfluidic chip for 3D microvascular tissue, The 19th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2015), pp. 740-742, Gyeongju, Korea, 2015.
[C9] Duc Phan, Xiaolin Wang, Abraham Lee, LF. Flanagan, CL. Limoli, Christopher Hughes, Development of a 3D in vitro perfused human neurovascular unit-on-chip, 4th Tissue Engineering and Regenerative Medicine International Society (TERMIS2015) World Congress, pp. S-326, Boston, Massachusetts, 2015.
[C8] Xiaolin Wang, Duc Phan, Steven C. George, Christopher C. W. Hughes, and Abraham P. Lee, Engineering anastomosis between biological perfused vessel network and endothelial cell-lined microfluidic channel, The 18th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2014), pp. 748-750, San Antonio, TX, 2014.
[C7] Duc Phan, Xiaolin Wang, Abraham Lee, Steven George, Christopher Hughes, Improving anastomosis between microfluidic channels and perfused capillary networks in cultured 3D human microtissues, Annual Fall Meeting of Biomedical Engineering Society (BMES2014), pp. 124, San Antonio, TX, 2014.
[C6] Xiaolin Wang, Shuxun Chen, Chi-wing Kong, Ronald A. Li and Dong Sun, “Automatic laser-induced cell fusion based on microwell array,” IEEE International Conference on Robotics and Automation(ICRA2013), Karlsruhe, Germany, pp. 2780-2785, 2013.
[C5] Shuxun Chen, Xiaolin Wang, Jinping Cheng, Chi-wing Kong, Shuk Han Cheng, Ronald A. Li and Dong Sun, “Artificially induced cell fusion by optical tweezers manipulation,” 13th International Conference on Nanotechnology (IEEE-NANO 2013), Beijing, China, pp.333-336, 2013.
[C4] Xiaolin Wang, Xiao Yan, Shuxun Chen and Dong Sun, “Automated parallel cell isolation and deposition using microwell array and optical tweezers,” IEEE International Conference on Robotics and Automation(ICRA2012), Saint Paul, MN , pp. 4571-4576, 2012.
[C3] Xue Gou, Xiaolin Wang, Hao Yang, Xiao Yan, Yong Wang, Tarek M Fahmy and Dong Sun, “Dynamic control of cell migration using optical tweezers and microfluidic channel,” 12th International Conference on Nanotechnology (IEEE-NANO 2012), Birmingham, UK, pp. 1-5, 2012.
[C2] Xiaolin Wang, Shuxun Chen and Dong Sun, “Robot-assisted automatic cell sorting with combined optical tweezer and microfluidic chip technologies,” IEEE International Conference on Robotics and Automation (ICRA2011), Shanghai, China, pp. 6003-6008, 2011.
[C1] Xiaolin Wang, Zuankai Wang and Dong Sun, “Cell sorting with combined optical tweezers and microfluidic chip technologies,” 11th International Conference on Control Automation Robotics & Vision (ICARCV2010), Singapore, pp. 201-206, 2010.
[C17] Ding Wang, Qinyu Li, Kai Niu and Xiaolin Wang*, Dissolvable temporary barrier for robust hydrogel patterning and uniform medium perfusion in organ-on-a-chip applications, The 25th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2021), pp.439-440, Palm Springs, California, USA, 2021.
[C16] Kai Niu, Ding Wang, Qinyu Li, and Xiaolin Wang*, Multi-functional cardiac microphysiological chip for cardiotoxicity applications, The 25th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2021), pp.419-420, Palm Springs, California, USA, 2021.
[C15] Qinyu Li, Kai Niu, and Xiaolin Wang*, Low-cost open microfluidic device for vascularized spheroid-on-a-chip, The 24th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2020), pp. 935-936, Virtual Conference, 2020. (Art in Science Award, Lab on a Chip Report, Front Cover, Wechat Official Account)
[C14] Qiyue Sun, Jianghua Pei, Qinyu Li, Xiang Chen and Xiaolin Wang*, Novel microfluidic perfusion bioreactor for vascularized organ-on-a-Chip, IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM 2019), pp. 1630-1634, Hong Kong, China, 2019.
[C13] Jianghua Pei, Qiyue Sun, and Xiaolin Wang*, A plug-n-play hydrostatic pressure-driven pump module for high-throughput organ-on-a-chip applications, The 22nd International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2018), pp. 1655-1657, Kaohsiung, Taiwan, 2018.
[C12] Xiaolin Wang*, Da Zhao, and Abraham P. Lee*, Enhanced hydrostatic pressure-driven passive micropump with siphon-based autofill function, The 21st International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2017), pp.643-644, Savannah, Georgia, 2017.
[C11] Xiaolin Wang, Duc Phan, Steven C. George, Christopher C. W. Hughes, and Abraham P. Lee, Well plate-based microfluidic platform for high throughput screening of 3D perfused vascularized microtissue, The 6th International Multidisciplinary Conference on Optofluidics (IMCO 2016), Beijing, China, 2016. (Best Paper Award)
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[C10] Xiaolin Wang, Duc Phan, Steven C. George, Christopher C. W. Hughes, and Abraham P. Lee, Pressure regulator for roust gel injection in coupling microfluidic chip for 3D microvascular tissue, The 19th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2015), pp. 740-742, Gyeongju, Korea, 2015.
[C9] Duc Phan, Xiaolin Wang, Abraham Lee, LF. Flanagan, CL. Limoli, Christopher Hughes, Development of a 3D in vitro perfused human neurovascular unit-on-chip, 4th Tissue Engineering and Regenerative Medicine International Society (TERMIS2015) World Congress, pp. S-326, Boston, Massachusetts, 2015.
[C8] Xiaolin Wang, Duc Phan, Steven C. George, Christopher C. W. Hughes, and Abraham P. Lee, Engineering anastomosis between biological perfused vessel network and endothelial cell-lined microfluidic channel, The 18th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS 2014), pp. 748-750, San Antonio, TX, 2014.
[C7] Duc Phan, Xiaolin Wang, Abraham Lee, Steven George, Christopher Hughes, Improving anastomosis between microfluidic channels and perfused capillary networks in cultured 3D human microtissues, Annual Fall Meeting of Biomedical Engineering Society (BMES2014), pp. 124, San Antonio, TX, 2014.
[C6] Xiaolin Wang, Shuxun Chen, Chi-wing Kong, Ronald A. Li and Dong Sun, “Automatic laser-induced cell fusion based on microwell array,” IEEE International Conference on Robotics and Automation(ICRA2013), Karlsruhe, Germany, pp. 2780-2785, 2013.
[C5] Shuxun Chen, Xiaolin Wang, Jinping Cheng, Chi-wing Kong, Shuk Han Cheng, Ronald A. Li and Dong Sun, “Artificially induced cell fusion by optical tweezers manipulation,” 13th International Conference on Nanotechnology (IEEE-NANO 2013), Beijing, China, pp.333-336, 2013.
[C4] Xiaolin Wang, Xiao Yan, Shuxun Chen and Dong Sun, “Automated parallel cell isolation and deposition using microwell array and optical tweezers,” IEEE International Conference on Robotics and Automation(ICRA2012), Saint Paul, MN , pp. 4571-4576, 2012.
[C3] Xue Gou, Xiaolin Wang, Hao Yang, Xiao Yan, Yong Wang, Tarek M Fahmy and Dong Sun, “Dynamic control of cell migration using optical tweezers and microfluidic channel,” 12th International Conference on Nanotechnology (IEEE-NANO 2012), Birmingham, UK, pp. 1-5, 2012.
[C2] Xiaolin Wang, Shuxun Chen and Dong Sun, “Robot-assisted automatic cell sorting with combined optical tweezer and microfluidic chip technologies,” IEEE International Conference on Robotics and Automation (ICRA2011), Shanghai, China, pp. 6003-6008, 2011.
[C1] Xiaolin Wang, Zuankai Wang and Dong Sun, “Cell sorting with combined optical tweezers and microfluidic chip technologies,” 11th International Conference on Control Automation Robotics & Vision (ICARCV2010), Singapore, pp. 201-206, 2010.
Patents
[P14] 王晓林,王非凡,周晨阳,轩连,“基于印章微结构图案化的血管化类器官芯片及其制备方法”,公开号:CN119432597A
[P13] 王晓林,周晨阳,轩连,“用于血管化肿瘤类器官培养的高通量器官芯片及制备方法”,公开号:CN119060843A
[P12] 王晓林,李彰杰,周晨阳,王非凡,刘沂军,路康怡,轩连,“用于体外培养的多功能微流控心脏器官芯片及其制备方法”,公开号:CN117327581A
[P11] 王晓林,路康怡,周晨阳,李彰杰,刘沂军,王非凡,轩连,“ 一种微纳机器人磁控递送装置”,公开号:CN118285911A
[P10] 王晓林,路康怡,周晨阳,李彰杰,刘沂军,轩连,“一种层级血管化微流控器官芯片及其制备方法”,公开号:CN116966943A
[P9]王晓林,路康怡,刘沂军,李彰杰,周晨阳,轩连,“一种CO2培养箱内使用的器官芯片摇床装置”,公开号:CN116463215A
[P8]赵宁,王晓林,“一种微流控3D仿生牙齿周围组织类器官芯片及其构建方法”,公开号:CN115386492A
[P7]王晓林,李钦宇,王丁,轩连,“具有可溶临时屏障的微流控器官芯片及其制备方法”,公开号:CN115074246A
[P6] 王晓林,李钦宇,“一种滑动式微流控器官芯片及其制备方法”, 授权公告号:CN112358966B, 2022.03.22.
[P5] 王晓林,李钦宇,“用于体外培养的血管化肿瘤微流控器官芯片及其制备方法”,授权公告号:CN 112143642 B, 2022.06.14.
[P4] Abraham P. Lee, Tao Yue, Da Zhao, Xiaolin Wang, Multi-layered Microfluidic Systems for In Vitro Large-scale Perfused Capillary Networks, US Patent, Grant No.: US11499127B2, 2022.11.15.
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[P3] Abraham P. Lee, Xiaolin Wang, Duc T. T. Phan, Christopher C. W. Hughes, and Steven C. George, Microfluidic Pressure Regulator for Robust Hydrogel Loading without Bursting, US Patent, Grant No. : US11180724B2, 2021.11.23.
[P2] Dong Sun, and Xiaolin Wang, “Methods and Means for Manipulating Particles.” US Patent. Grant No.: US8723104 B2, 2014.05.13.
[P1] 孙东, 王晓林, "用于操作粒子的方法与装置", 授权公告号:CN103674814B, 2018.05.11.
[P13] 王晓林,周晨阳,轩连,“用于血管化肿瘤类器官培养的高通量器官芯片及制备方法”,公开号:CN119060843A
[P12] 王晓林,李彰杰,周晨阳,王非凡,刘沂军,路康怡,轩连,“用于体外培养的多功能微流控心脏器官芯片及其制备方法”,公开号:CN117327581A
[P11] 王晓林,路康怡,周晨阳,李彰杰,刘沂军,王非凡,轩连,“ 一种微纳机器人磁控递送装置”,公开号:CN118285911A
[P10] 王晓林,路康怡,周晨阳,李彰杰,刘沂军,轩连,“一种层级血管化微流控器官芯片及其制备方法”,公开号:CN116966943A
[P9]王晓林,路康怡,刘沂军,李彰杰,周晨阳,轩连,“一种CO2培养箱内使用的器官芯片摇床装置”,公开号:CN116463215A
[P8]赵宁,王晓林,“一种微流控3D仿生牙齿周围组织类器官芯片及其构建方法”,公开号:CN115386492A
[P7]王晓林,李钦宇,王丁,轩连,“具有可溶临时屏障的微流控器官芯片及其制备方法”,公开号:CN115074246A
[P6] 王晓林,李钦宇,“一种滑动式微流控器官芯片及其制备方法”, 授权公告号:CN112358966B, 2022.03.22.
[P5] 王晓林,李钦宇,“用于体外培养的血管化肿瘤微流控器官芯片及其制备方法”,授权公告号:CN 112143642 B, 2022.06.14.
[P4] Abraham P. Lee, Tao Yue, Da Zhao, Xiaolin Wang, Multi-layered Microfluidic Systems for In Vitro Large-scale Perfused Capillary Networks, US Patent, Grant No.: US11499127B2, 2022.11.15.
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[P3] Abraham P. Lee, Xiaolin Wang, Duc T. T. Phan, Christopher C. W. Hughes, and Steven C. George, Microfluidic Pressure Regulator for Robust Hydrogel Loading without Bursting, US Patent, Grant No. : US11180724B2, 2021.11.23.
[P2] Dong Sun, and Xiaolin Wang, “Methods and Means for Manipulating Particles.” US Patent. Grant No.: US8723104 B2, 2014.05.13.
[P1] 孙东, 王晓林, "用于操作粒子的方法与装置", 授权公告号:CN103674814B, 2018.05.11.
Invited talks
[T15]特邀报告, 类器官高通量制备与智能化分析系统, 2025(第五届)类器官大会-类器官与新药研发,中国/上海,3/8/2025.
[T14]特邀报告, 基于微流控的类器官芯片构建与类器官工程化制备, 2024第一届中国类器官转化医学大会,中国/上海,11/16/2024.
[T13]特邀报告, 基于微流控的器官芯片构建与类器官工程化制备, 第十一届中国微流控高端学术论坛暨第四届国际微流控产业论坛,中国/杭州,22 September, 2024.
[T12]特邀报告, 基于微流控的类器官/器官芯片构建及其药物测试应用, 2024类器官医学应用与蛋白质组学技术研讨会,中国/杭州,15 June, 2024.
[T11]特邀报告, 基于微流控的类器官芯片构建及其药物筛选应用, 2024(第四届)类器官大会暨ISoOR 2024国际类器官高峰论坛,中国/上海,7-8 March, 2024.
[T10]特邀报告, 基于微流控的血管化器官/类器官芯片构建及其应用, 珠江国际胃肠肿瘤论坛—“类器官芯片智造和肿瘤微环境”分会,中国/深圳,9 December, 2023.
[T9] Invited talk, Engineered 3D vascularized microtissue and its application in anti-cancer drug screening, microTAStic seminar, 1 December, 2023.
[T8] 特邀报告,基于微流控的血管化器官/类器官芯片构建及其应用,OTC2023类器官前沿应用与3D培养论坛,中国/上海,26 October 2023.
[T7] 特邀报告,微流控血管化器官/类器官芯片构建及其应用,第十一届慕尼黑上海分析生化展“类器官前沿技术开发与应用” 分论坛,中国/上海,12 July 2023.
[T6] 特邀报告,基于微流控的器官芯片构建及其药物筛选应用,2023 年第二届团泊湖中医药现代化论坛,中国/天津,2 June 2023.
[T5] 特邀报告,基于微流控的器官芯片/类器官构建及其在药物筛选中的应用,2023 年复旦类器官高峰论坛,中国/上海,13-14 May, 2023.
[T4] 特邀报告,基于微流控的器官芯片构建及其在药物筛选中的应用, 2022(第二届) 3D 细胞培养与类器官研讨会,中国/上海,29-30 September,2022.
[T3] 特邀报告,Engineered 3D vascularized microtissue and its application in anticancer drug screening,中国细胞生物学学会 2020 年全国学术大会,中国/苏州,4-7 August,2020.
[T2] 特邀报告, A Hydrostatic Pressure-driven Passive Micropump Enhanced with Siphon-based Autofill Function, IEEE 3M-NANO, 中国/镇江,4-8 August,2019.
[T1] 特邀报告, 3D Perfused Vascularized Organ-on-a-Chip and its Application in Anticancer Drug Screening, IEEE 3M-NANO, 中国/杭州,13-17 August,2018.
[T14]特邀报告, 基于微流控的类器官芯片构建与类器官工程化制备, 2024第一届中国类器官转化医学大会,中国/上海,11/16/2024.
[T13]特邀报告, 基于微流控的器官芯片构建与类器官工程化制备, 第十一届中国微流控高端学术论坛暨第四届国际微流控产业论坛,中国/杭州,22 September, 2024.
[T12]特邀报告, 基于微流控的类器官/器官芯片构建及其药物测试应用, 2024类器官医学应用与蛋白质组学技术研讨会,中国/杭州,15 June, 2024.
[T11]特邀报告, 基于微流控的类器官芯片构建及其药物筛选应用, 2024(第四届)类器官大会暨ISoOR 2024国际类器官高峰论坛,中国/上海,7-8 March, 2024.
[T10]特邀报告, 基于微流控的血管化器官/类器官芯片构建及其应用, 珠江国际胃肠肿瘤论坛—“类器官芯片智造和肿瘤微环境”分会,中国/深圳,9 December, 2023.
[T9] Invited talk, Engineered 3D vascularized microtissue and its application in anti-cancer drug screening, microTAStic seminar, 1 December, 2023.
[T8] 特邀报告,基于微流控的血管化器官/类器官芯片构建及其应用,OTC2023类器官前沿应用与3D培养论坛,中国/上海,26 October 2023.
[T7] 特邀报告,微流控血管化器官/类器官芯片构建及其应用,第十一届慕尼黑上海分析生化展“类器官前沿技术开发与应用” 分论坛,中国/上海,12 July 2023.
[T6] 特邀报告,基于微流控的器官芯片构建及其药物筛选应用,2023 年第二届团泊湖中医药现代化论坛,中国/天津,2 June 2023.
[T5] 特邀报告,基于微流控的器官芯片/类器官构建及其在药物筛选中的应用,2023 年复旦类器官高峰论坛,中国/上海,13-14 May, 2023.
[T4] 特邀报告,基于微流控的器官芯片构建及其在药物筛选中的应用, 2022(第二届) 3D 细胞培养与类器官研讨会,中国/上海,29-30 September,2022.
[T3] 特邀报告,Engineered 3D vascularized microtissue and its application in anticancer drug screening,中国细胞生物学学会 2020 年全国学术大会,中国/苏州,4-7 August,2020.
[T2] 特邀报告, A Hydrostatic Pressure-driven Passive Micropump Enhanced with Siphon-based Autofill Function, IEEE 3M-NANO, 中国/镇江,4-8 August,2019.
[T1] 特邀报告, 3D Perfused Vascularized Organ-on-a-Chip and its Application in Anticancer Drug Screening, IEEE 3M-NANO, 中国/杭州,13-17 August,2018.