Purdue University Purdue e-Pubs Birck and NCN Publications Birck Nanotechnology Center 2011 Hybrid opto-electric manipulation in microfluidics- opportunities and challenges Aloke Kumar Oak Ridge Natl Lab, Oak Ridge, TN Stuart J. Williams University of Louisville Han-Sheng Chuang University of Pennsylvania Nicolas G. Green University of Southhampton Steven T. Wereley Birck Nanotechnology Center - Purdue University, [email protected] Follow this and additional works at:http://docs.lib.purdue.edu/nanopub Part of theNanoscience and Nanotechnology Commons Kumar, Aloke; Williams, Stuart J.; Chuang, Han-Sheng; Green, Nicolas G.; and Wereley, Steven T., "Hybrid opto-electric manipulation in microfluidics-opportunities and challenges" (2011).Birck and NCN Publications.Paper 767. http://dx.doi.org/10.1039/c1lc20208a This document has been made available through Purdue e-Pubs, a service of the Purdue University Libraries. Please contact [email protected] for additional information. View Online V o lu m e 1 Lab on a Chip 1 | N u m b e r 1 3 | 2 0 1 1 Micro- & nano- fluidic research for chemistry, physics, biology, & bioengineering www.rsc.org/loc Volume 11 | Number 13 | 7 July 2011 | Pages 2121–2296 A La 20208 b on 1LC a C 39/C hip 10 11 ust 20oi:10. gd Aug | 1 or y on 3bs.rsc. sitpu Univerhttp:// due 1 on d by PurMay 201 de0 a2 nloon wd oe Dh s bli Pu Featuring research from the group of Professor As featured in: Seok (Sid) Chung at Korea University, Seoul, Korea. Title: In vitro 3D collective sprouting angiogenesis under orchestrated ANG-1 and VEGF gradients A hydrogel incorporating microfl uidic platform is able to generate precisely orchestrated gradient of multiple angiogenic factors, VEGF and ANG-1, to induce 3D cooperative endothelial cell sprouting angiogenesis, which can contribute to exploring cancer treatment, drug discovery and vascularization of engineered tissues. See Seok Chung et al., Lab Chip, 2011, 11, 2175. P www.rsc.org/loc ag ISSN 1473-0197 e s 2 Registered Charity Number 207890 1 CRITICAL REVIEW 2 1 Aloke Kumar et al. – 2 Hybrid opto-electric manipulation in microfl uidics—opportunities 2 9 and challenges 1473-0197(2011)11:13;1-3 6 View Online Lab on a Chip C Dynamic Article Links < Cite this: Lab Chip, 2011, 11, 2135 CRITICAL REVIEW www.rsc.org/loc Hybrid opto-electric manipulation in microfluidics—opportunities and challenges *a b c d e Aloke Kumar, Stuart J. Williams, Han-Sheng Chuang, Nicolas G. Green and Steven T. Wereley A 8 0 02 Received8thMarch2011,Accepted20thApril2011 2 C L DOI:10.1039/c1lc20208a 1 C 9/ 3 10 Hybridopto-electricmanipulationinmicrofluidics/nanofluidicsreferstoasetofmethodologies 11 ust 20oi:10. emmicprloo-yainngdonpatnicoa-lsmcaoled.uOlavteiornthoeflealestctdreockaidnee,tiacsscehteomfemsettohaocdhoileovgeiepsa,rwtihcliechordflifufeidrimnatnhiepiurlmatoiodnulaattitohne gd Aug | strategyand/orthelengthscaleofoperation,haveemerged.Thesetechniquesoffernewopportunities 1 or y on 3bs.rsc. wdeitvhictehs.eiHrydbyrniadmoipctnoa-etluercet,riacntdecthhneiiqruaebsilhitayvfeobrepeanraultliellizoepdetroatmioannhipauslacrteeaotebdjecntosvrealnagpinpgliciantidoinvserasnitdy sitpu frommillimetre-sizeddropletstonano-particles.Thisreviewarticlediscussestheunderlyingprinciples, Univerhttp:// applicationsandfutureperspectivesofvarioushybridopto-electrictechniquesthathaveemergedover due 1 on thelastdecadeunderaunifiedumbrella. d by PurMay 201 1. Introduction de0 wnload on 2 EaB-imosacili:enkcuemsaDraiv1is@ioonr,nOl.gaokv;RFidagxe:N+1at8io6n5a-5l7L4a-b5o3r4a5t;oTrye,l:O+a1k8R65id-g5e7,4U-8S66A1. The ability to control matter at all length scales, for various Dohe bDepartment of Mechanical Engineering, University of Louisville, applications, has been mankind’s relentless goal. The delicate blis Louisville,USA.E-mail:[email protected];Tel:+1502-852- nature of objects involved in lab-on-a-chip devices and micro- Pu 6340 fluidicplatformstypicallynecessitatenon-invasivemanipulation cMechanical Engineering and Applied Mechanics, University of ofmatter.Progressinmicrofluidicsandlab-on-a-chipdevicesin Pennsylvania, Philadelphia, PA, USA. E-mail: [email protected]; Tel:+1215-746-2993 the last few decades saw a concurrent, vigorous activity in the dSchoolofElectronicsandComputerScience,UniversityofSouthampton, fieldofnon-invasivemanipulationofmatterandseveralschemes Southampton,UK.E-mail:[email protected];Tel:+44(0)2380593778 of manipulation at the micro- and nano-scale have emerged. eBirckNanotechnologyCenter,PurdueUniversity,WestLafayette,USA. Today tools exist which employ either light waves,1,2 electric E-mail: [email protected]; Fax: +1 765-496-6443; Tel: +1 765-494- 5624 fields,3magneticfields,4oracousticwaves5forthenon-invasive AlokeKumarreceivedhisbach- Stuart J. Williams received his elors and masters degrees from BS and MEng degrees in the Indian Institute of Tech- Mechanical Engineering from nology, Kharagpur, India in the University of Louisville in 2005 and his doctoral degree 2005andhisPhDinMechanical from Purdue University, West Engineering from Purdue Lafayette,USAin2010.During University in 2009 with the his doctoral career he was support of the NSF Graduate awarded several fellowships, Research Fellowship. Currently including the prestigious Jose- he is an Assistant Professor in phine DeKa(cid:1)rma(cid:1)n fellowship. the Department of Mechanical Currently,heisaWignerFellow EngineeringattheUniversityof and staff member at the Oak Louisville where he is the AlokeKumar Ridge National Laboratory StuartJ:Williams director of the Integrated (ORNL). At ORNL his Microfluidic Systems Labora- research focuses on phenomena tory where his research focuses at the microfluidic length scales, particularly lab-on-a-chip elec- on applications of microfluidics for biology and lab-on-a-chip trokineticsanddynamicsofmicrobialaggregations. samplepreparation,includingopticalandelectrokineticmethods. ThisjournalisªThe RoyalSociety ofChemistry 2011 LabChip, 2011,11,2135–2148 | 2135 View Online manipulationofmatteratthisscale.Forexample,electricfields ahigherdegreeoffreedom.Thisfreedomenablesreconfigurable generated from patterned electrodes have been employed to and programmable lab-on-a-chip devices driven through illu- movevariousobjectsfrommillimetre-sizedaqueousdroplets6to mination displays such as a LCD screen or simply with a laser nanometre-sizedbeads.3 pointer.Avarietyofopticallyinducedelectrokinetictechniques Innovationsinthelastdecadehaveresultedinthecreationof spanningarangeoflengthscaleshaveemerged. a new class of non-invasive manipulation techniques—hybrid Astructureddiscussiononthediverseopto-electrictechniques opto-electric tools. As the name suggests, these techniques is facilitated by a classification based on the operational length employ simultaneous light waves and electric fields to achieve scale (l) of the technique. Attempting such a classification, one fluid or particle manipulation at the micro- and nano-scale. finds that the operational length scales can bedivided into two Unlike, optical tweezing,7 hybrid tools do not rely on optical broadgroups.Oneclasscomprisesoftechniquesthatmanipulate A pressure for non-invasive manipulation. Instead, these tech- liquid-suspended particulates whose dimensions range from 08 niques use light to activate and control electrokinetic manipu- nanometrestomicrometres i.e.lz10(cid:1)9to 10(cid:1)6m.Techniques 2 20 lation mechanisms. The simultaneous presence of light and suchasoptoelectronictweezers8(OET)andrapidelectrokinetic C 1L electric fields, and their non-linear interaction can result in the patterning9 (REP) would belong to this class. Another class C 9/ appearance of physical phenomena unique to opto-electric consists of techniques dealing with object dimensions in the 11103 systemscomparedtotraditionalelectrokineticsystems.Theuse millimetre scale i.e. l z 10(cid:1)4 to 10(cid:1)3 m. Optoelectrowetting10 gust 20doi:10. oflightalsobestowsonthesetechniquesadynamicnatureand ((OOE-OWE)Wa1n1)d aintsddesirnivgaleti-vsiedsedsucchonatsinuoopuesn ooppttooeelleeccttrroowweettttiinngg Aug | (SCOEW12) comprise this class of hybrid techniques. Unlike 1 or Han-ShengChuangreceivedhis y on 3bs.rsc. PhD degree in department of RacEtuPatoironOEofTd,rOoEplWetsa.nMduitltsi-dsecrailveamtivaensipduelaaltwiointhutshinegcoanctoromllbeid- sitpu mechanical engineering from nation of different techniques is also possible and will be due Univer1 on http:// PLcuuarrfradeyuneettlyte, UINnaivienrs2ipt0yo1,s0td.oHcWteoerasistl deliesSccuturcsihcsetdheychhbenrrieidq.uFteeigsch.t1nhiadqteupheiascvtaesraeemcehenarggretendodfoetrvhienergdtihnffeeewrpeanastpthpdyleibccaraitddioeo.npstoin- ded by Pur0 May 201 rHPeesaneimnasrychlBveaarnuiaw.aotrkHiUnignsivewrrisetishteyarDcohrf lipanhbve-enosotnimg-aae-tnciohani.pGsaiyvnsedtnemtahspe,parleniccdaentaitoreenmeneoarfgbelfinnucgnednoaofmvtheelnesateapltperceohlaenccithqreuosektsio,nteththiices wnload on 2 innatneore-flstusidairces,focMusEedMoSn/NmEicMroS/ aprrtoicploesewdililntdhisecluassstdtehceadveaurinoduesrtthecehunnoilfioegdieusmtbhraetllahaovfehybbereidn oe Dh technologies and optical diag- ublis nostics.In2005,hewasawarded onpiqtuoe-es,lewcthriocsetetcyhpniciqalueosp.erWateiosntaalrtlenwgitthh sacadleisscluiessbioentwoeefntelczh- P Han-ShengChuang a competitive fellowship from 10(cid:1)9and10(cid:1)6m,subsequentlywewilldiscusstechniqueswithlz Ministry of Education in Tai- 10(cid:1)4to10(cid:1)3m.Wewillconcludebydiscussingcurrentchallenges wan.Heandhisresearchfellows andopportunitiesforcontinuedresearchinhybridtechniques. werealsothefinalistsoftheprestigiousBurtonD.MorganBusi- nessCompetitionin2008and2009,respectively.Inaddition,heis aco-founderofaUSbasedtechnicalstart-up,MicrofluidicInno- vations,foundedin2009. Professor Wereleyhasbachelor degrees in Physics (Lawrence NicolasGreenisaReaderinthe University, 1990) and Mechan- Nano Group and the South- ical Engineering (Washington amptonNanofabricationCentre University, StLouis,1990)fol- in ECS at the University of lowed by masters and doctoral Southampton. He studied for degrees from Northwestern aPhDfromUniversityofGlas- University(1992and1997).He gow from 1994 until 1997 and is currently Professor of then worked as a Marie Curie Mechanical Engineering at Research Fellow at the Univer- PurdueUniversityandaFellow sity of Sevilla, Spain and at the Center of Smart Inter- a Royal Academy of Engi- faces, Technische Universita€t neering Fellow at the Universi- StevenT:Wereley Darmstadt (Germany). ties of Glasgow and Professor Wereley served as an NicolasG:Green Southampton.Hewasappointed AlexandervonHumboldtFellow toalectureshipattheUniversity at Technische Universita€t Darmstadt (2007) and Universita€t der of Southampton in 2005. His Bundeswehr (2009). Professor Wereley is the co-author of the research interests are in the areas of Bioelectronics and Micro- monographs Fundamentals and Applications of Microfluidics fluidics examining fundamental physics and applications of elec- (ArtechHouse,2002and2006)andParticleImageVelocimetry: trokineticsinlab-on-a-chipsystems. APracticalGuide(Springer,2007). 2136 | LabChip,2011,11, 2135–2148 Thisjournal isªTheRoyalSociety ofChemistry2011 View Online A 8 0 2 0 2 C L 1 C 9/ 3 10 11 ust 20oi:10. gd Aug | 1 or y on 3bs.rsc. Fig.1 Achartclassifyingnewlydevelopedopto-electrictechniques.Thetextbelowtheboxesindicatestheyearinwhichthetechniquewasfirstreported Universithttp://pu intheliterature. due 1 on 2. Hybrid techniques with l z 10(cid:1)9 to 10(cid:1)6 m that the illuminated regions on the ITO surface had a higher wnloaded by Purd on 20 May 201 TvNniihzoq.etu,roeeospnatvlroyee-repaylrreidecmitftrafhoerehrileyyondrttrih,gortidehneyeantlueaicnmmhdnpiecilrqealymusiseneesngmtthpabathliytyofs(naOiscllaEowlAfpit)trh,hinOiencsEietphTltiehsasrcneaadenteRdtgeEocthrhPye-. caHcwrunoyardrsyrktewalnaolatsfrfeddoHreremna(ts5yaia3wttyl2ia.o1rt3nnhdtmabhenyt)eattashhlcs.ee,as1en3dumnaGseerbokdloenfrdgpeAagcatiCrnotyednssrtsinMag.slnF.saaorJrlrleub1lso4sietawdmseiaenbmsdgleoIidtnnThstOetthrhpeaeeitloseehcndcaaterrspeoaeredpinooeidgsff Dohe abilities are also distinct. Table 1 provides a quick overview of thelaserscans.GongandMarr14showedtheexistenceofpoly- s bli thesetechniques before we proceedon anindividual discussion crystallinity in the assembled structures, and that not only can u P ofeach. nucleation be directed with control over crystal annealing and melting. 2.1 Opto-electrohydrodynamicassembly The basis of the reported colloidal aggregation under the influenceofUVlightisnotfullyunderstood,butitisbelievedto One of the first innovations in the field of hybrid opto-electric be related to planar particle aggregation on electrode surfaces techniqueswasledbyHaywardetal.13in2000.Theyusedoptical patterns shone on an electrode surface to assemble suspended particlesintoopticallytunablecrystals.Theelectrokineticsetup consisted of a parallel plate configuration with a brass cathode andanindiumtinoxide(ITO)thinfilmastheanode.Ultra-violet (UV)lightwasfirstpassedthroughapre-fabricatedmaskandthe resulting pattern was illuminated on the ITO film. The micro- channelwasfilledwithadiluteaqueoussolutionofpolystyrene (PS) beads. Hayward et al.13 observed that over time, the PS Fig.2 (a)ThefigureshowstheassemblyofPSbeadsonITOsurface beadsaggregatedontheITOsurface,undertheinfluenceofan using optical motifs, as outlined in Hayward et al.13 Reprinted with applied DC field, and the aggregation resulted in dense packed permission from Macmillan Publishers Ltd: Nature, Hayward et al.,13 assembles in patterns similar to the pattern of UV irradiation copyright2000.(b)Non-uniformcurrentsdriveflow,whichinturncan (Fig.2a).Haywardetal.’s13processofassemblingsuchoptically entrain particles leading to an aggregation. Reprinted with permission tunablecrystalstookseveralhoursandtheresearchersproposed fromRistenpartetal.33Copyright2008AmericanChemicalSociety. Table1 Tablelistingthepredominanthybridtechniqueswithlz10(cid:1)9to10(cid:1)6m Notabledeviations Technique Originalsetup Distinguishingfeature frominitialsetup OEA Parallelplate,UVlightsourcewithstaticmask(ref.13) Useofnon-uniformcurrents Ref.14 OET Useofa-Si,DMDwithnear-redlightemittingdiodelaser(ref.8) Useofvirtualelectrodes Ref.40–42 REP Parallelplate,useof1064nmholographiclightsource(ref.9) Useofopticallydrivenelectrothermalflows Ref.72and92 ThisjournalisªThe RoyalSociety ofChemistry 2011 LabChip, 2011,11,2135–2148 | 2137 View Online due to the action of both DC and AC fields.15–18 The latter todynamicallyreconfigurelightpatterns.Thesedynamicsystems phenomena first reported by Richetti et al.,16 were modeled by are driven by a digital micromirror device (DMD),8,39 liquid Trau et al.17,18 as a perturbation of the local electric field by crystaldisplay(LCD),40,41orabeamprojector.42Thesesystems particlesandthesubsequentactionofthesameperturbationson require the integration of optical components to focus the the electrode polarization layer. This model proposed by Trau illumination ona microscope stageand providea resolutionof etal.18isactuallyaninstanceofinduced-chargeelectro-osmosis 1–20 mm. However, an LCD-based system without integrated (ICEO)flows.19–21Later,Ristenpartetal.22providedscalinglaws opticshasbeendemonstratedthatgrantsmoreportabilityatthe forsuchflowswithACfrequency((cid:3)1/u)andACfieldstrength cost ofincreased electroderesolution(200mm).40Regardless of ((cid:3)|E|2).However,theinversedependenceonACfrequencyleads the illumination scheme, OET illumination intensity is over tounrealisticpredictionsinthelimitoflowACfrequencies(u/ 100000timeslessthantraditionalopticaltweezingsystemsand A 0+). For steady or DC fields, Solomentsev et al.23,24 proposed hasamuchlargerworkingarea.8 8 0 alternatemechanismsbasedonelectro-osmoticslipflows(EOFs) The electrode configuration for a traditional OET device is 2 0 2 ontheparticles’surfacewithnopolarizationchange.Eachmodel similar to of Fig. 3, which illustrates a closed system with the C 1L hasitsowndrawbacksandapossibilityisthatacombinationof photoconductivematerialononesidewithparticlemanipulation C 9/ models can satisfactorily explain the diversity of observed occurring on the photoconductive substrate surface. However, 3 1110 phenomena.InfactarecentinvestigationbyRistenpartetal.25 a three-dimensional manipulation scheme has been demon- gust 20doi:10. hmaosdineldinceaetdedttohabtebointvhoTkreaduientaol.r’ds1e8ratnodeSxoplolaminenatgsegvreegtaatli.o’sn23,i2n4 sbtoratttoemd welietchtrpohdoesto.4c3oSnidnugcleti-vsiedemdaOteEriTalsdeovnicbesothhavtheealtsoopbaenedn Aug | steadyfields.Acompletereviewofaggregationonelectrodesand developed with a single ITO substrate patterned with interdigi- y on 31 bs.rsc.or ereffveicetws,obfuvtawrieowusouinldholimkeogteonneiotiteesthisatousetvsiedrealtrheesesacrocpheerosfhtahvies atastiemdpelleecat-rSoid:Hesfianlmdcisoathteedrewsittrhicati-oSni:Hof.4p4aTrhtieclleimmitaantiiopnuloaftiuosnining sitpu reported significant findings and readers might wish to refer to lowconductivity(<100mSm(cid:1)1)solutions;biologicalmedialike due Univer1 on http:// oitnhpetriescgoaimlomnesootafifdtshjaiescefboneltllioetowveitdnhgetorielilpnuodmruticsne.a26ht–ii3og5nhHepraryioowmnaipcrdtcinuegrtraeflnlo.’twsd1s3enousfsiettihoeesf pMohveeodrscipuohmmate(eDt-hbMiusfEfiseMsrue)de,hspaahlvioentecoo(tPrnaBdnSus)cistativonirdtsieDwsueflrrbeoemicncco1o’rstpoMo2roaSdteifimde(cid:1)wd1.iE4t5haTgalone d by PurMay 201 aubltoimveatdeelyscrliebaeddsnattourea,nwhaigcghreingattuiornnenretsreaminbsltihnegptahreticloepstaicnadl OwiEthThsyigsthemcoanndducthtievistyystmemeddiaem(>on1stSramte(cid:1)d1)p.4a6r,4t7icTlehmisacnaippualbaitliiotyn, de0 motif13,33(Fig.2b). though, comes with the added expense of fabricating complex a2 nloon structuresinsteadofthetraditionala-Si:Hfilm. wd OETs can generate a variety of electrokinetic particle and Doublishe 2Il.l2ustrOatpetdoeliencttrhoenicprtewveieozuesrssection, Hayward et al.13 laid the hwyidderloyduysneadmeilcectfroorkceins.e4t8icDmieeclehcatnroispmhoinreOsiEsT(Ds.EDPE)Pirseftehrestmotohset P foundations of electric field perturbations by local increase of translation of polarizable neutral particles in the presence of conductivity of a substrate. Chiou et al.8,36 explored materials a non-uniform electric field, typically an AC field.3 The magni- whosephotoconductivitylayinadifferentregime.Bytheuseof tude and direction of the DEP force are proportional to the ahighlyefficientphotoconductivematerialdepositedonaplanar volumeoftheparticle,thesignalvoltageandfrequency,andthe surfacealongwithaprogrammableilluminationsystem,Chiou gradientoftheappliedfield;it’salsoafunctionofthedielectric et al.8,36 demonstrated that illuminated areas generate ‘virtual’ properties (permittivity, conductivity) of the fluid and particle. electrodes, which are dynamically reconfigurable to electro- DEP forces are categorized as positive, being attracted to field kineticallymanipulateparticlesandfluid.Thistoolcalledopto- gradients, or negative, being repelled from these regions. With electronic tweezers (OET) made possible the use of standard regards to OETs, particles are attracted to illuminated regions electrokinetictechniqueswithouttheuseofpatternedelectrodes. under positive DEP but are repelled from them with negative TheoperationofOETswasdemonstratedbyChiouetal.8and DEP.Fig.4aandbprovideexamplesofparticletrappingusing is illustrated in Fig. 3. This device consisted of unpatterned bothtypesofDEPforces. parallel ITO electrodes with one of them being coated with Whenaparticleispolarizedthetwooppositelychargedpoles hydrogenated amorphous silicon (a-Si:H) serving as the photo- arealignedinthedirectionoftheelectricfield.Ifanon-spherical conductivematerial.Amorphoussiliconisawidelyusedmaterial particle undergoes polarization, the poles will tend to concen- in the solar cell industry; when light illuminates a-Si:H its elec- trateattheendsofthelongaxisoftheparticle.Thiswillinduce trical conductivity increases several orders of magnitude, a torque force on the particle to orient its long axis with the depending on the illumination intensity.37 The increased directionoftheelectricfield.Thisphenomenoniscalledelectro- conductivitywillleadtoalocalizedincreaseinfieldstrengthat orientationandcanbeusedtoextractdielectricpropertiesfrom the substrate surface, enabling dynamic virtual electrode the particle.4 OET devices have applied this technique to align configurations.OETcanbeactivatedwithawhitelightsource, nanowires49 and bacteria.50 Particle’s charged poles will also although a-Si:H absorption is most efficient from red to near- interact with neighboring particles. Similarly charged particles infraredwavelengths.38 willform‘chains’andaligninthedirectionoftheelectricfield. The types of illumination sources and its delivery to the However,ifadjacentparticlesareperpendiculartothedirection photoconductivesurfacesvary.Astaticilluminationpatterncan of the electric field they are repelled from each other. These besimplyappliedbytheuseofasinglelaserspot39oraphoto- particle–particleinteractionshavealsobeenobservedinanOET mask.13However,OETsystemsarecharacterizedbytheirability device.51 2138 | LabChip,2011,11, 2135–2148 Thisjournal isªTheRoyalSociety ofChemistry2011 View Online A 8 0 2 0 2 C L 1 C 9/ 3 10 11 ust 20oi:10. gd Aug | 1 or y on 3bs.rsc. sitpu Univerhttp:// due 1 on d by PurMay 201 de0 a2 nloon wd oe Dh s bli u P Fig.3 IllustrationofatypicalOETplatformcharacterizedbyaphotoconductivefilm(a-Si:H)andaprojectionofdynamiclightpatters,inthiscase fromaDMD.ReprintedwithpermissionfromMacmillanPublishersLtd:Nature,Chiouetal.,8copyright2005. OETscanalsoinducetwoelectrohydrodynamicmechanisms, electrokineticforcesonlyatilluminationsgreaterthanfortypical AC electroosmosis (ACEO) and electrothermal (ETH) motion. OETuse.48Jamshidi,etal.55demonstratedaggregationof90nm ACEOisinducedwhenthetangentialcomponentoftheelectric diameter gold nanoparticles with OET-induced ETH flows. field moves ions within the substrate’s electric double layer, Fig. 4c provides an example of particle manipulation using generatingaslipvelocity.52Thisfrequency-dependentbehavioris ACEOandETHelectrohydrodynamicsdrivenbyOETs. dominant at low frequencies (<10 kHz) and at large Debye OETs in its various forms has used electrokinetic mecha- lengths(i.e.lowconductivitymedia).ACEOisparticularlyuseful nisms for trapping, patterning, and sorting a variety of parti- in the trapping of sub-micrometre particles where Brownian cles.Manipulatednon-biologicalparticlesoutsideoftraditional motion overcomes DEP forces. In OETs, the illuminated area polystyrene/silica beads include quantum dots,39 silver nano- cangenerateACEOflows,carryingsuspendedparticlestowards rods,49goldnanoparticles,55andcarbonnanotubes.56Biological these regions. Such flows have captured particles ranging from sorting demonstrations with OET include motile and non- 50nmto2mm.39Selectiveandrapidconcentrationof1mmand motile sperm,57 erythrocytes and leukocytes,58 live and dead 6 mm polystyrene particles was demonstrated utilizing simulta- human B cells,8 and normal and abnormal oocytes.59 Addi- neouslyappliedACEOandDEP.53ETHhydrodynamicsoccur tional biologicalentities thathavebeenmanipulatedwithOET when the applied electric field acts upon fluid dielectric inho- include HeLa cells,60 E. coli,61 yeast,42 protozoa,39 DNA,62 and mogeneities resulting from non-uniform temperature fields.9 HepG2 cells.63 To reduce non-specific adhesion an operational Such temperature gradients can be generated through Joule OET device coated with poly (ethylene glycol) was demon- heating or with applied external illumination.54 The photocon- strated.64 For an expanded discussion on the applications of ductive material in OETs absorb the applied illumination OET, readers are referred to a recent review article by Hwang resultinginETHflows,butsuchflowsgenerallyovercomeother and Park.65 ThisjournalisªThe RoyalSociety ofChemistry 2011 LabChip, 2011,11,2135–2148 | 2139 View Online A 8 0 2 0 2 C L 1 C 9/ 3 10 11 ust 20oi:10. gd Aug | 1 or y on 3bs.rsc. sitpu Univerhttp:// due 1 on d by PurMay 201 de0 a2 nloon wd oe Dh s bli u P Fig.4 (a)PositiveDEPtrappingofE.coliwithOETsisdemonstratedwhentheyareattractedtoanilluminated17mmspot-size.FromChiouetal.61 ReproducedwithpermissionofIEEE,ª2004IEEE.(b)45mmparticlesareaggregatedindarkregionsofthedynamicilluminatedpatternwithnegative DEP.FromChoietal.40ReproducedwithkindpermissionofSpringerScience+BusinessMedia.(c)Trappingof90nmgoldnanoparticleswith acombinationofACEOandETHhydrodynamics.ReprintedwithpermissionfromJamshidietal.55Copyright2009AmericanChemicalSociety. 2.3 Rapidelectrokineticpatterning Rapid electrokinetic patterning (REP) is a more recent hybrid opto-electrictechniqueintroducedbyWilliamsetal.9in2008as a real time dynamic particle manipulation technique. The orig- inal chip configuration utilized by Williams et al.9 consisted of ITOcoatedparallelelectrodesbiasedwithanACsignal(Fig.5). Williams et al.9 showed that in a low frequency regime (<200 kHz), micrometre dimension particles could be trapped and dynamically configured into various shapes on the electrode surface by using various optical landscapes produced from alaseroperatingatawavelengthof1064nm.REPisaversatile techniqueandparticlesasdiverseasgoldparticles(200,250nm) (unpublished data), silica particles,66 and polystyrene particles Fig.5 AnexampleoftheREPmanipulationtechnique.Anintenselaser (50 nm (ref. 67) to 3 mm) have been successfully aggregated. A hologramisshoneonanITOsurfaceandthe690nmredfluorescentPS video demonstrating REP and highlighting its features is beadstaketheshapeofthehologram.Williamsetal.9Reproducedby available.68,69 permissionofTheRoyalSocietyofChemistry. 2140 | LabChip,2011,11, 2135–2148 Thisjournal isªTheRoyalSociety ofChemistry2011 View Online NosingleelectrokineticmechanismdrivesREP-basedparticle aggregations, similar to those demonstrated with an ITO elec- aggregation and research has shown that it is actually brought trodeusing1064nmlaserbeam.Thisfeatureissignificantasit about by the concerted action of a variety of electrokinetic allows REP to be replicated at different optical wavelengths, forces.An understandingofthe REPprocesscanbefacilitated provided that the proper combination of electrode-laser wave- by seeking answers to these distinct questions: (i) What causes length is chosen to generate the necessary optically induced rapid particle transport to illuminated regions on the electrode temperaturegradients. surface? (ii) What keeps the particles on the electrode surface? Oncetransportedtotheilluminatedsite(s),particle–electrode (iii)Whatisthestructureoftheaggregatedparticles?Whilethese interactionforcesallowtheparticlestobe‘trapped’.Asthedrag questions are interrelated, the following will approach these from the toroidal EMV would tend to ‘pluck’ the transported questionsindividually. Firstto beaddressed will bethe driving particles away from the electrodes, the particle–electrode inter- A forces for particle transport to the illuminated regions. Kumar actionforcesareattractiveintheREPregime,butareafunction 8 0 etal.70demonstratedthatahighlyfocused1064nmlaserbeam of frequency, medium conductivity and possibly even the elec- 2 0 2 shoneonanITOsurfacecancausehighlylocalizedtemperature trolyticspecies,butareexpectedtobeindependentofillumina- C 1L gradients by the heating of the substrate (Fig. 6a). For a laser tion.Faganetal.’s75–77workcomprisestheveryselectstudiesthat C 9/ powerof20mWtheabsolutetemperaturechangeitselfwasnot have concentrated their efforts on localized particle–electrode 11103 very significant ((cid:3)5 K), but this change occurred at the length forces. By measuring the temporal variations in a particle’s gust 20doi:10. s((cid:3)ca1le05oKfmm(cid:1)ic1)r.oSnus,chrehsiuglhtitnegmipnervaetruyrehgigrahdtieenmtpseinratthuereprgersaedniceenotsf mheiicgrhotscaobpoyv,ethaeny ceolencctlruoddeed(thh)a,tutshinegobtosetravledintoesrcnialllatrioeflnesctinionh Aug | electricfieldscangenerateETHbodyforces3,54,71andthusresult could only be explained through the superposition of different y on 31 bs.rsc.or idnemdoonmstinraatnetdEthTaHt aflothwrse.e-Idnimaennositohneralweolerckt,roKthuemrmaarlemticarl.o7-2 mhyedcrhoadnyisnmams.icMflooswtssigpnroifidcuacnetlayvtheretyiccaolnfoclrucdeecdomthpaotntheneteloencttrhoe- sitpu vortex(EMV)formedwithinanREPdevice,whichhasa‘sink- particleforfrequenciesabove500Hz.Apartfromforcesexerted due Univer1 on http:// ttmhyipacter’otbhneerhesastvoreilounrtgintohenaoprfathtrhteiecellmeeciimtcrraoogdveeovrsteuelroxfcavicmaer.eiUtersysian(smgPtthIweVo)s-qtdhuimeayreesnhosoifowntehadel bvaeyrrottilhceaelinffloutrhicdee,spooatnrhtietchrleem–ceoelecllchotairdnoaidslempisanrtcteiarcnalecsta.iloIsnmo.a7c8g,o7e9nctIhrtiabhruagtseesactlsoaontbpheleaesnye d by PurMay 201 helyedctrroidcynfiaemldicsthtreeonrgyt.hL,at|Eer|2,,Kcuomnasirsteetnatl.7w3uitshedealenctorvoetlhtehrmreae-l sphroowxinmtithyatcbarningcirnegattewoatetrleaccttriivcealodrourbepleullasiyveersf(oErDceLs.s8)0–i8n2 cTlohsies de0 dimensional wavefront deformation particle tracking velocim- explainsthesecondquestion,thoughacompletecharacterization nloaon 2 etry(PTV)developedatUniversit€atderBundeswehrMu€nchen74 of the particle–electrode interaction forces remains elusive. wd toobtainathree-dimensionalvelocitymapoftheEMV(Fig.6b). However, onecanconceive theuseof the EMVvortexitself to oe Dh blis They also showed good agreement between experimental data measurethesenetattractiveforces. u andnumericalsimulations,whichwerebasedonETHbodyforce ThestructureofparticleaggregationsinaREPclusterhasnot P calculations. Williams et al.9 conjectured that the EMV trans- beenextensivelyinvestigated.Typically,largerparticles(>1mm) portsparticlesfrombulktotheelectrodesurface,wheretheyare tend to form a monolayer, smaller particles (<300 nm) tend to ‘captured’.Williamsetal.66characterizedcolloidalaccumulation exhibitamulti-layercharacteristic.67Itispossiblethatoscillatory inREPasafunctionoftimeandtheimposedelectricfield,and behavior of particles near the electrode75–77has an influence on foundthattherateofcolloidalaccumulationvariedasthesquare theaggregationstructure. of the electric field strength, in agreement with the hypothesis. Initsveryshortspanofdevelopment,theREPtechniquehas They went on to show that a 532 nm laser can be used in showntolenditselftoavarietyofdifferentapplications.Kumar conjunction with a gold electrode to produce particle etal.70proposedanewforcespectroscopytechniquebasedonthe Fig.6 (a)The1064nmlasercausesintensetemperaturegradientsontheITOsurface.ReprintedwithpermissionfromKumaretal.70Copyright2010 AmericanChemicalSociety.(b)TheEMVasvisualizedusingwavefrontdeformationPTV.TheEMVtransportsanalytesfromthebulktotheelectrode surface.FromKumaretal.73ReproducedwithkindpermissionfromSpringerScience+BusinessMedia. ThisjournalisªThe RoyalSociety ofChemistry 2011 LabChip, 2011,11,2135–2148 | 2141 View Online REP technique. They used REP to capture an aggregation of the applied frequency. The physical basis for such sorting has 1 mm particles, and subsequently deactivated the laser. In the beenexplainedintermsofacriticalACfrequencyphenomenon. absence of the laser heating, the electrothermal flow ceases, The critical AC frequency is the maximum AC frequency at allowing the particle–cluster to ‘explode’ due to inter-particle whichparticlescanbetrapped.Kumaretal.70usedfourdifferent repulsiveforces(Fig.7).UsingDelaunaytriangulation,Kumar particletypesandfoundthatthecriticalACfrequencybehaves et al.70 defined an ensemble-averaged inter-particle distance, as square of the particle radius ((cid:3)a2) for a given particle type. whose time rate of increase provides a measure of the average Suchabehaviorisexpectedfromnon-equilibriumdouble-layer inter-particle repulsive force. Repeating the procedure for polarization theory.85,86,89 The sorting effect demonstrated by various AC frequencies and voltages, Kumar et al.70 found an Williamsetal.66isthefirstsortingofcolloidsbasedonfrequency anomalousdecreaseinthedipole-momentoftheparticles.This dependentEDLpolarization. A anomalousbehaviorwasaccountedforonthebasisofanaddi- Apart from these applications REP has been extended to 8 0 tional dipole moment contribution from a non-equilibrium manipulate live bacteria,90 non-spherical particles91 and even 2 20 EDL.83–86Thisphenomenon arisesfrom the polarization of the nano-rods(unpublisheddata). C 1L EDL,aroundaparticle,inthepresenceofanelectricfield.79,85–88 C 9/ Kumaretal.70concludedthatthedipolemomentoftheparticle 2.4 Summary 3 1110 in the REP regime is given the combination of the Maxwell– August 20g | doi:10. pWoaAlagnrnizeaarptipionlnitc.eartfiaocniaolfpRoElaPrizfaotriosno3rtianngdofnocno-leloqiudislibwraiusmdemEDonL- OoHrEaigyAiwn,aaOlrdEimTetpalanelm.d’se1Rn3tEsaePttiuoapnppsaeenaemrddsiinstotinthhcaterifrnreousmsndneeoarnclyh-uinnogitfhoeprrrmibnitociitephsleiisnn. sity on 31 pubs.rsc.or sbbteertaawdteesdeonbfy3s8Wizaeinslldi0a1.m50,s61ektHaanlz.d6(6F2Wigmi.lml8ia).mbWyseviltaliaraylm.i6n6sgwettehraeel.a6A6bCalelstfooredsqoeumretnoPcnSy- cpfaurborrrneiconauttnioconerdbancshoeandr-geuelneicftdorirosmktriinbeeulteticcitosr.nicR, EfiwPehl,deisnremtahsiemsOiectEkuiTpngemctarpnalodyicteirodenabatyel Univerhttp:// stratedsortingbetween1mmPSand1mmsilicabeadsbyvarying tWecihllniaimqusese.t aHl.o,9wuevtielirz,esthdeosemidniasntitncEtTioHnsflaorweshuanrldiklye tahbesooltuhteer; due 1 on the techniques share some common operational principles. All d by PurMay 201 tbdhoeegtshreeeItseT.cOhFnroiaqmnudeasanu-Sseeilecoatrpreotikcpsinhteoottiocis-ncdostunacdneudcgptroiavidne,itenaatllbsofeoittrhmteoaretivocanarnyainnbdge de0 wnload on 2 suitmiliizlaersitDieEs.P7F2oarndex/oarmApCleE,OR9E2Ptoianiddpifaferrteicnlet croenlldecittiioonns.Faulrretahdeyr oe Dh research can only be expected to blur the lines between these s bli schemes. u P 3. Hybrid techniques with l z 10(cid:1)4 to 10(cid:1)3 m Theprevioussectionmainlydealswithmicron-andsub-micron sized objects. There exists another class of manipulation tech- niquesdealingwithdropletsandthe targetlengthscales inthis caserangefrom10(cid:1)4to10(cid:1)3m.Untilnow,OEW,FEOET,and some OEW derivatives are the major hybrid opto-electric tech- niques used for droplet handling. Their operating mechanisms, configurations, and performances will be discussed in the followingcontent.Informationregardingthesetechniquesisalso summarizedinTable2. 3.1 Optoelectrowetting(OEW) Electrowetting (EW) is a technique well known for aqueous dropletmanipulationbyelectricallydrivensurfacetensionandis a cornerstone in the field of digital microfluidics. The phenom- enon was first explained by Gabriel Lippmann in 1875.93 Accordingtohismodel,thecontactangleofadropofelectrolyte onanelectrodecanbereducedbyapplyinganelectricpotential across the electrolyte. The contact angle represents an equilib- rium state of the surface tensions between the liquid, solid and gasphases.Theexternalenergytriggerstheredistributionofthe Fig.7 ForcespectroscopybasedonREP.(a)AREPaggregation.(b) surfacechargesinbothsolidandliquidphases,whicheventually The aggregation ‘explodes’ when the laser is deactivated. (c) The time derivative of the ensemble averaged inter-particle distance provides reshapes the appearance of the aqueous droplet. Later, a measure of the inter-particle force. Reprinted with permission from researchers6,93,94 came up with a modification, dubbed electro- Kumaretal.70Copyright2010AmericanChemicalSociety. wettingondielectric(EWOD),byaddingadielectriclayer(e.g., 2142 | LabChip,2011,11, 2135–2148 Thisjournal isªTheRoyalSociety ofChemistry2011
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