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柔性微流控技术是微流控技术的一个重要分支,近年来微流控装置的柔性属性得到越来越多的关注。目前相关研究聚焦于将具有柔韧性和延展性的各类材料应用于传统微流控技术中,其柔性特性使流体在柔性通道中的流动特性与在传统刚性流道中的流动特性有一定差异,便于构建除了流体输运功能之外的功能性结构,或拓展芯片的使用场景。对近年来柔性微流控技术相关研究进行了总结和评述,分别介绍了目前主流的柔性芯片加工制造技术和其在生物医学、可穿戴设备、环境检测、食药品检测等领域的应用,并讨论了柔性微流控技术目前的技术短板和未来发展方向。
Abstract:Flexible microfluidic technology is an important branch of microfluidic technology. In recent years, people pay more and more attention to the flexible properties of microfluidic devices. At present, relevant research focuses on the application of various materials with flexibility and malleability to traditional microfluidic technology, its flexible characteristics make the flow characteristics of fluid in the flexible channel different from that in the traditional rigid channel, which is convenient to construct functional structures in addition to the fluid transport function, or expand the application scenario of chips. This paper summarizes and reviews the relevant research on flexible microfluidic technology in recent years, introduces the current mainstream flexible chip processing and manufacturing technologies and their applications in biomedicine, wearable devices, environmental testing, food and drug testing and other fields, and discusses the current technical shortcomings and future development directions of flexible microfluidic technology.
[1] CHI C W,AHMED A R,DERELI-KORKUT Z,et al.Microfluidic cell chips for high-throughput drug screening [J].Bioanalysis,2016,8(9):921-937.
[2] SHEN J,SHAFIQ M,MA M,et al.Synthesis and surface engineering of inorganic nanomaterials based on microfluidic technology [J].Nanomaterials,2020,10(6):1177.
[3] KOH A,KANG D,XUE Y G,et al.A soft,wearable microfluidic device for the capture,storage,and colorimetric sensing of sweat [J].Science Translational Medicine,2016,8(366):366ra165.
[4] TRUCKENMüLLER R,GISELBRECHT S,van BLITTERSWIJK C,et al.Flexible fluidic microchips based on thermoformed and locally modified thin polymer films [J].Lab on a Chip,2008,8(9):1570-1579.
[5] YUAN M,LI C,ZHENG Y Z,et al.A portable multi-channel fluorescent paper-based microfluidic chip based on smartphone imaging for simultaneous detection of four heavy metals [J].Talanta,2024,266(Pt 2):125112.
[6] ZHAO Z Q,LI Q J,CHEN L N,et al.A thread/fabric-based band as a flexible and wearable microfluidic device for sweat sensing and monitoring [J].Lab on a Chip,2021,21(5):916-932.
[7] FALLAHI H,ZHANG J,PHAN H P,et al.Flexible microfluidics:fundamentals,recent developments,and applications [J].Micromachines,2019,10(12):830.
[8] REN K N,ZHOU J H,WU H K.Materials for microfluidic chip fabrication [J].Accounts of Chemical Research,2013,46(11):2396-2406.
[9] ASRI M A M,MAK W C,NORAZMAN S A,et al.Low-cost and rapid prototyping of integrated electrochemical microfluidic platforms using consumer-grade off-the-shelf tools and materials [J].Lab on a Chip,2022,22(9):1779-1792.
[10] WANG H,CHEN L G.Electrowetting-on-dielectric based economical digital microfluidic chip on flexible substrate by inkjet printing [J].Micromachines,2020,11(12):1113.
[11] GHADERINEZHAD F,AMIN R,TEMIREL M,et al.High-throughput rapid-prototyping of low-cost paper-based microfluidics [J].Scientific Reports,2017,7(1):3553.
[12] LIU J J,KONG X P,WANG H L,et al.Roll-to-roll wax transfer for rapid and batch fabrication of paper-based microfluidics [J].Microfluidics and Nanofluidics,2019,24(1):6.
[13] M?NNEL M J,BAYSAK E,THIELE J.Fabrication of microfluidic devices for emulsion formation by microstereolithography [J].Molecules,2021,26(9):2817.
[14] LEBEDEV D,MALYSHEV G,RYZHKOV I,et al.Focused ion beam milling based formation of nanochannels in silicon-glass microfluidic chips for the study of ion transport [J].Microfluidics and Nanofluidics,2021,25(6):51.
[15] MALI P,SARKAR A,LAL R.Facile fabrication of microfluidic systems using electron beam lithography [J].Lab on a Chip,2006,6(2):310-315.
[16] HSIEH Y K,CHEN S C,HUANG W L,et al.Direct micromachining of microfluidic channels on biodegradable materials using laser ablation [J].Polymers,2017,9(7):242.
[17] NIE C,FRIJNS A,ZEVENBERGEN M,et al.An integrated flex-microfluidic-Si chip device towards sweat sensing applications [J].Sensors and Actuators:B,2016,227:427-437.
[18] CAI J C,JIANG J X,JIANG J Y,et al.Fabrication of transparent and flexible digital microfluidics devices [J].Micromachines,2022,13(4):498.
[19] MUR J,MIKELJ A,PODOBNIK B,et al.Precision fabrication of flexible microfluidic circuits using direct laser rapid prototyping solution [J].Journal of Micromechanics and Microengineering,2020,30(11):115005.
[20] MAHMUD M A,BLONDEEL E J M,KADDOURA M,et al.Features in microfluidic paper-based devices made by laser cutting:how small can they be?[J].Micromachines,2018,9(5):220.
[21] ABGRALL P,LATTES C,CONéDéRA V,et al.A novel fabrication method of flexible and monolithic 3D microfluidic structures using lamination of SU-8 films [J].Journal of Micromechanics and Microengineering,2006,16(1):113-121.
[22] GOWERS S A N,CURTO V F,SENECI C A,et al.3D printed microfluidic device with integrated biosensors for online analysis of subcutaneous human microdialysate [J].Analytical Chemistry,2015,87(15):7763-7770.
[23] CHEN X J,MO D Y,GONG M F.A flexible method for nanofiber-based 3D microfluidic device fabrication for water qua-lity monitoring [J].Micromachines,2020,11(3):276.
[24] UNGER M A,CHOU H P,THORSEN T,et al.Monolithic microfabricated valves and pumps by multilayer soft lithography [J].Science,2000,288(5463):113-116.
[25] WANG J Y,CHEN X Y,LIU H,et al.A method for manufacturing flexible microfluidic chip based on soluble material [J].Journal of Nanomaterials,2021,2021:1280338.
[26] KOJIC S P,STOJANOVIC G M,RADONIC V.Novel cost-effective microfluidic chip based on hybrid fabrication and its comprehensive characterization [J].Sensors,2019,19(7):1719.
[27] XU B,QIN T T,ZHANG J,et al.Cloth-based microflui-dic analytical devices by laser-induced hydrophilization technique [J].Sensors and Actuators:B,2021,341:129998.
[28] LIU M,ZHANG C S,LIU F F.Understanding wax screen-printing:a novel patterning process for microfluidic cloth-based analytical devices [J].Analytica Chimica Acta,2015,891:234-246.
[29] TASAENGTONG B,SAMEENOI Y.A one-step polymer screen-printing method for fabrication of microfluidic cloth-based analytical devices [J].Microchemical Journal,2020,158:105078.
[30] ATABAKHSH S,JAFARABADI ASHTIANI S.Programmable paper-based microfluidics device with prefabricated patterns for prototyping of μPADs [J].Microfluidics and Nanofluidics,2019,23(5):69.
[31] SOUM V,PARK S,BRILIAN A I,et al.Programmable paper-based microfluidic devices for biomarker detections [J].Micromachines,2019,10(8):516.
[32] CHEN J H,ZHOU Y L,WANG D H,et al.UV-nano-imprint lithography as a tool to develop flexible microfluidic devices for electrochemical detection [J].Lab on a Chip,2015,15(14):3086-3094.
[33] MCMILLAN A H,THOMéE E K,DELLAQUILA A,et al.Rapid fabrication of membrane-integrated thermoplastic elastomer microfluidic devices [J].Micromachines,2020,11(8):731.
[34] GARMASUKIS R,HACKL C,CHARVAT A,et al.Rapid prototyping of microfluidic chips enabling controlled biotechnology applications in microspace [J].Current Opinion in Biotechnology,2023,81:102948.
[35] SUN M M,PEI X Y,XIN T,et al.A flexible microfluidic chip-based universal fully integrated nanoelectronic system with point-of-care raw sweat,tears,or saliva glucose monitoring for potential noninvasive glucose management [J].Analytical Chemistry,2022,94(3):1890-1900.
[36] CHEN J,WANG W S,FANG J,et al.Variable-focusing microlens with microfluidic chip [J].Journal of Micro-mechanics and Microengineering,2004,14(5):675-680.
[37] RAOUFI M A,RAZAVI BAZAZ S,NIAZMAND H,et al.Fabrication of unconventional inertial microfluidic channels using wax 3D printing [J].Soft Matter,2020,16(10):2448-2459.
[38] BRIONES J,ESPULGAR W,KOYAMA S,et al.A design and optimization of a high throughput valve based microfluidic device for single cell compartmentalization and analysis [J].Scientific Reports,2021,11(1):12995.
[39] QAMAR A Z,AMAR K,KOHLI P,et al.Wax patterned microwells for stem cell fate study [J].RSC Advances,2016,6(106):104919-104924.
[40] STANLEY C E,GROSSMANN G,i SOLVAS X C,et al.Soil-on-a-chip:microfluidic platforms for environmental organismal studies [J].Lab on a Chip,2016,16(2):228-241.
[41] METZ S,TRAUTMANN C,BERTSCH A,et al.Polyimide microfluidic devices with integrated nanoporous filtration areas manufactured by micromachining and ion track technology [J].Journal of Micromechanics and Microengineering,2004,14(3):324-331.
[42] SRINIVASAN B,KOLLI A R,ESCH M B,et al.TEER measurement techniques for in vitro barrier model systems [J].Journal of Laboratory Automation,2015,20(2):107-126.
[43] GUO J H,YU Y R,CAI L J,et al.Microfluidics for flexible electronics [J].Materials Today,2021,44:105-135.
[44] HE Z Z,ELBAZ A,GAO B B,et al.Disposable morpho Menelaus based flexible microfluidic and electronic sensor for the diagnosis of neurodegenerative disease [J].Advanced Healthcare Materials,2018,7(5):1701306.
[45] REWATKAR P,KOTHURU A,GOEL S.PDMS-based microfluidic glucose biofuel cell integrated with optimized laser-induced flexible graphene bioelectrodes [J].IEEE Transactions on Electron Devices,2020,67(4):1832-1838.
[46] LI R Y,NIE B Q,DIGIGLIO P,et al.Microflotronics:a flexible,transparent,pressure-sensitive microfluidic film [J].Advanced Functional Materials,2014,24(39):6195-6203.
[47] VOGT D M,PARK Y L,WOOD R J.Design and characterization of a soft multi-axis force sensor using embedded microfluidic channels [J].IEEE Sensors Journal,2013,13(10):4056-4064.
[48] LIN D,LI B W,QI J,et al.Low cost fabrication of microfluidic paper-based analytical devices with water-based polyurethane acrylate and their application for bacterial detection [J].Sensors and Actuators:B,2020,303:127213.
[49] RACICOT J M,MAKO T L,OLIVELLI A,et al.A paper-based device for ultrasensitive,colorimetric phosphate detection in seawater [J].Sensors,2020,20(10):2766.
[50] QUINN C W,CATE D M,MILLER-LIONBERG D D,et al.Solid-phase extraction coupled to a paper-based technique for trace copper detection in drinking water [J].Environmental Science & Technology,2018,52(6):3567-3573.
[51] PETERS J J,ALMEIDA M I G S,O′CONNOR ?RAJ L,et al.Development of a micro-distillation microfluidic paper-based analytical device as a screening tool for total ammonia monitoring in freshwaters [J].Analytica Chimica Acta,2019,1079:120-128.
[52] PAL A,DUBEY S K,GOEL S.IoT enabled microfluidic colorimetric detection platform for continuous monitoring of nitrite and phosphate in soil [J].Computers and Electronics in Agriculture,2022,195:106856.
[53] LIU X J,HU S W,XU B Y,et al.Microfluidic liquid-air dual-gradient chip for synergic effect bio-evaluation of air pollutant [J].Talanta,2018,182:202-209.
[54] POUYANFAR N,HAROFTE S Z,SOLTANI M,et al.Artificial intelligence-based microfluidic platforms for the sensitive detection of environmental pollutants:recent advances and prospects [J].Trends in Environmental Analy-tical Chemistry,2022,34:e00160.
[55] FOCKE M,KOSSE D,MüLLER C,et al.Lab-on-a-foil:microfluidics on thin and flexible films [J].Lab on a Chip,2010,10(11):1365-1386.
[56] SANKAR K,LENISHA D,JANAKI G,et al.Digital image-based quantification of chlorpyrifos in water samples using a lipase embedded paper based device [J].Talanta,2020,208:120408.
[57] FAN Y Q,WANG H L,LIU S C,et al.Milk carton with integrated paper-based microfluidics for milk quality rapid test [J].Journal of Food Safety,2018,38(2/3):e12548.
[58] YUAN M Q,ALOCILJA E C,CHAKRABARTTY S.Self-powered wireless affinity-based biosensor based on integration of paper-based microfluidics and self-assembled RFID antennas [J].IEEE Transactions on Biomedical Circuits and Systems,2016,10(4):799-806.
基本信息:
DOI:10.13250/j.cnki.wndz.25040104
中图分类号:TN492
引用信息:
[1]倪志林,季建军,彭名顺,等.柔性微流控技术的研究进展[J].微纳电子技术,2025,62(04):76-87.DOI:10.13250/j.cnki.wndz.25040104.
基金信息:
江阴中达软塑新材料股份有限公司-南京理工大学产学研合作资助项目(1224021281746)
2025-02-27
2025-02-27
2025-02-27