Upload
others
View
1
Download
0
Embed Size (px)
Citation preview
µTAS 2008 • San Diego 1
Program at a GlanceSan Diego µTAS 2008
Conference Registration and Check-In
Wine & Cheese Welcome Reception
Opening Remarks
PLENARY I - Jeremy Nicholson, Imperial College, UK
Break & Exhibit Inspection
Lunch & Exhibit Inspection
PLENARY II - Harold Craighead, Cornell University, USA
Innovation In Science Award
Poster Session 1
PLENARY III - Teruo Fujii, University of Tokyo, JAPAN
Break & Exhibit Inspection
Lunch & Exhibit Inspection
PLENARY IV - Andrew Griffiths, Institut de Science et d’Ingenierie Supermoleculaires, FRANCE
Poster Session 2
Conference Banquet at the San Diego Zoo
Announcement of MicroTAS 2009
PLENARY V - Tomokazu Matsue, Tohoku University, JAPAN
Break & Exhibit Inspection
Lunch & Exhibit Inspection
PLENARY VI - Julio M. Ottino, Northwestern University, USA
Art In Science Award
Poster Session 3
Poster Awards Ceremony
Break & Exhibit Inspection
Conference Adjourns
16:00 - 19:00
17:00 - 19:00
08:00 - 08:20
08:20 - 09:00
09:15 - 10:15
10:15 - 10:45
10:45 - 11:45
11:45 - 13:00
13:00 - 13:40
13:40 - 14:00
14:00 - 16:20
16:20 - 17:20
08:00 - 08:40
08:55 - 09:55
09:55 - 10:25
10:25 - 11:25
11:25 - 12:40
12:40 - 13:20
13:20 - 15:40
15:40 - 16:40
18:00 - 22:00
08:00 - 08:20
08:20 - 09:00
09:15 - 10:15
10:15 - 10:45
10:45 - 11:45
11:45 - 13:00
13:00 - 13:40
13:40 - 14:00
14:00 - 16:20
16:20 - 17:20
08:00 - 08:40
09:00 - 10:00
10:00 - 10:30
10:30 - 11:30
11:30
Monday
Sunday
Tuesday
Wednesday
Thursday
Session 1A1Single Cell Analysis
Session 1B1Sample Preparation & Separation
Session 1A2Cell Interactions
Session 1B2Single Molecular Manipulation & Measurement
Session 1A3Tools for Nucleic Acid Research & Discovery
Session 1B3Mapping & Imaging
Session 2A1Fluidic Design & Assembly
Session 2B1Channels, Tubes and Pores on the Nanoscale
Session 2A2Clinical Diagnostic 1
Session 2B2On Chip Synthesis and Production
Session 2A3Extreme Multiplexed Analysis
Session 2B3Analyzing Blood Components
Session 3A1Cell Sorting
Session 3A1Innovative Chemistries for Microfluidics
Session 3A2Sample Preparation
Session 3B2Tools for Controlled Cell Culture I
Session 3A3Protein Expression & Characterization
Session 3B3Clinical & Biomolecular Analysis
Session 4A1Microfluidic Integrated Optics
Session 4B1In Vivo & Cellular Screening
Session 4A2Tools for Controlled Cell Culture II
Session 4B2Innovative Microfluidic Applications
µTAS 2008 • San Diego2
MONDAY Program µTAS 2008 San Diego
Technical Program
USING MICROFLUIDICS TO CONTROL THE EXTRACELLULAR ENVIRONMENT AND TO MEASURERELEASE FROM SELECTED NEURONSJ.V. Sweedler1, M. Zhong1, J.N. Hanson1, K. Jo2, L. Millet1, S.S. Rubakhin1,M.U. Gillette1 and R.G. Nuzzo11University of Illinois, Urbana-Champaign, USA and 2Songang University, KOREA
QUANTIFICATION OF AMYLOID SECRETION IN ISOLATED OPTOFLUIDIC CHAMBER ARRAYL.Y. Wu, Y. Choi, S.G. Hong, H. Wu, M. Dueck, and L.P. LeeUniversity of California, Berkeley, USA
HYBRID DIGITAL-CHANNEL MICROFLUIDICS FOR PRE-PROCESSING AND SEPARATIONSA.R. Wheeler, M. Abdelgawad, and M.W. WatsonUniversity of Toronto, CANADA
09:15 - 09:35
09:35- 09:55
Session 1B1Sample Preparation & Separation
INTEGRATED FLUORESCENCE-LABELING AND POLYACRYLAMIDE GEL ELECTROPHORESIS FORANALYSIS OF PROTEIN ISOFORMSA. Apori and A.E. HerrUniversity of California, Berkeley, USA
Session 1A1Single Cell Analysis
Grand Ballroom A-B Grand Ballroom C
Monday, October 13, 2008
08:00 – 08:20 Opening Remarks
08:20 - 09:00 Plenary ISTATISTICAL SPECTROSCOPY AND METABOLOME-WIDE ASSOCIATION APPROACHESIN PERSONAL AND PUBLIC HEALTH INVESTIGATIONSJ. NicholsonImperial College London, UK
10:15 – 10:45 Break & Exhibit Inspection
SINGLE-CELL LEVEL GENE EXPRESSION PROFILING USING MICROFLUIDIC LINEAR AMPLIFICATIONJ.G. Kralj1, A. Player2, M.S. Munson1, S.P. Forry1, D. Petersen2, D. Edelman2, E. Kawasaki2,P. Meltzer2, and L.E. Locascio1
1National Institute of Standards and Technology (NIST), USA and2National Cancer Institute, National Institute of Health (NIH), USA
09:55- 10:15A MICROFLUIDIC MOLECULAR TRACKING SYSTEM DETECTS A TIME-TO-SEARCH DNASEQUENCE TO BE CLEAVED BY RESTRICTION ENZYMESD. Onoshima1, N. Kaji1, M. Tokeshi1, and Y. Baba1,2,3
1Nagoya University, JAPAN, 2National Institute of Advanced Industrial Science and Technology (AIST), JAPAN and 3Institute for Molecular Science, JAPAN
Grand Ballroom A-B Grand Ballroom C
A CHIP-BASED IN VITRO MODEL FOR CYTOTOXICITY TEST USING CACO-2 AND HEP G2H. Kimura, T. Yamamoto, Y. Sakai, and T. FujiiUniversity of Tokyo, JAPAN
MICROFLUIDIC PLATFORM TO STUDY THREE DIMENSIONAL CELL MIGRATION & CAPILLARYMORPHOGENESISS. Chung, R. Sudo, I. Zervantonakis, T. Rimchala, P.J. Mack, C.-R. Wan, V. Vickerman, and R.D. KammMassachusetts Institute of Technology, USA
THE TOMO-TWEEZERS: A NEW INSTRUMENT COMBINING MAGNETIC TWEEZERS ANDMICROCHIP TECHNOLOGY FOR SINGLE MOLECULE STUDIESL. Disseau1, J. Miné1, M. Dilhan2, H. Camon2, G. Cappello1, and J.-L. Viovy1
1Institut Curie, FRANCE and 2LAAS, FRANCE
10:45 - 11:05
11:05- 11:25
Session 1B2Single Molecule Manipulation & Measurement
A MICROFLUIDIC NANOPORE SYSTEM FOR SINGLE MOLECULE MASS DISCRIMINATIONL.P. Hromada, Jr.1, B.J. Nablo2, J.J. Kasianowicz2, M.A. Gaitan2, D.L. DeVoe1, and J.W.F. Robertson2
1University of Maryland, USA and 2National Institute of Standards and Technology, USA
Session 1A2Cell Interactions
HYDRODYNAMIC CELLULAR PATTERNING FOR 3D CO-CULTUREY.-S. Torisawa, B. Mosadegh, G.D. Luker, and S. TakayamaUniversity of Michigan, USA
11:25- 11:45ISOLATION OF SINGLE DNA MOLECULE IN A PICOLITRE-SIZED DROPLET FORMEDBY LIQUID DIELECTROPHORESISB. Wee, M. Kumemura, D. Collard, and H. FujitaUniversity of Tokyo, JAPAN
11:45 – 13:00 Lunch & Exhibit Inspection
13:00 - 13:40 Plenary IINANOSTRUCTURE INCORPORATION IN MICROANALYTICAL SYSTEMSH. CraigheadCornell University, USA
13:40 - 14:00 Innovation In Science AWARD sponsored by Analytical Chemistry
14:00 - 16:20 Poster Session I
µTAS 2008 • San Diego 3
MONDAY ProgramSan Diego µTAS 2008
M1AA FAST AND ACCURATE ISOTACHOPHORESIS SIMULATION CODEM. Bercovici, S.K. Lele, and J.G. SantiagoStanford University, USA
M2AMATHEMATICAL AND EXPERIMENTAL STUDY ON BACKWARD FLOW IN A SURFACE TENSIONDRIVEN MICROPUMPJ. Ju1, J.Y. Park1, E. Berthier2, D.J. Beebe2, and S.H. Lee1
1Korea University, KOREA and 2University of Wisconsin, USA
M3AFLUID FLOW SIMULATIONS AND MEASUREMENT OF OXYGEN CONSUMPTION OFHEPATOCYTES IN PERFUSED MULTIWELL BIOREACTORK. Domansky1, M.H.M. Lim2, A. Dash1, J.R. Llamas Vidales1, and L.G. Griffith1
1Massachusetts Institute of Technology, USA and 2University of Cambridge, UK
M4AJOULE HEATING EFFECTS ON INSULATOR-BASED DIELECTROPHORESISP. Sabounchi1, D.E. Huber2, M.P. Kanouff1, A.E. Harris1, and B.A. Simmons1
1Sandia National Laboratories, USA, and 2Stanford University, USA
M5AMICROFLUIDIC DRIFTING: THREE DIMENSIONAL HYDRODYNAMIC FOCUSING OFMICROPARTICLESX. Mao and T.J. HuangPennsylvania State University, USA
M6ASINGLE-PHASE DIGITAL MICROFLUIDICS BASED ON ISOTACHOPHORETIC TRANSPORTF. Schönfeld1, G. Goet1, K.S. Drese1, and S. Hardt21Institut für Mikrotechnik Mainz GmbH, GERMANY and 2Leibniz Universität Hannover, GERMANY
M7ATHREE-DIMENSIONAL HYDRODYNAMICALLY ADJUSTABLE LENS CHIPFABRICATED BY RAPID PROTOTYPINGM. Rosenauer and M.J. VellekoopVienna University of Technology, AUSTRIA
M10AA NEW VORTEX-TYPE MICROMIXERS.-Y. Yang1 and G.-B. Lee1,2
1National Cheng Kung University, TAIWAN and 2Industrial Technology Research Institute, TAIWAN
M11AA VERTICAL LAMINATING MICROMIXER (VLM)W.S. Yang 1, J.-O. Ryu2, and D.S. Kim1
1Chung-Ang University, KOREA and 2Allmedicus Co. Ltd, KOREA
M12AAU/PPY ACTUATORS FOR ACTIVE MICROMIXING AND MASS TRANSPORT ENHANCEMENTX. Casadevall i Solvas, R.A. Lambert, R.H. Rangel, and M.J. MadouUniversity of California, Irvine, USA
M13ACONTINUOUS MICROFLUIDIC IMMUNOSENSING WITH ANTIBODY CONJUGATEDPARAMAGNETIC BEADSL.A. Sasso and J.D. ZahnRutgers University, USA
M14AEFFECTIVE MIXING OF LAMINAR FLOWS AT A DENSITY INTERFACE BY ANINTEGRATED ULTRASONIC TRANSDUCERL. Johansson, S. Johansson, F. Nikolajeff , and S. ThorslundUppsala University, SWEDEN
M15AHIGH-SPEED CHEMICAL SIGNAL GENERATION WITH MULTI-PLUG MODULATORSF. Azizi and C.H. MastrangeloCase Western Reserve University, USA
M16AON-DEMAND DROPLET METERING AND FUSION UTILIZING MEMBRANE ACTUATIONB.-C. Lin and Y.-C. SuNational Tsing Hua University, TAIWAN
M17ARAPID MIXING BY MICRO-VORTEX IN A CONTRACTION-EXPANSION ARRAY MICROCHANNELS. Choi, M.G. Lee, and J.-K. ParkKorea Advanced Institute of Science and Technology (KAIST), KOREA
M18ASIMULATION OF MICROFLUIDIC FLUID MIXING USING ARTIFICIAL CILIAM.G.H.M. Baltussen1, J.M.J. den Toonder1,2, F.M. Bos1, and P.D. Anderson1
1Technische Universiteit Eindhoven, THE NETHERLANDS and 2Philips Research, THE NETHERLANDS
W19ATIPPING THE BALANCE WITH DIELECTROPHORETIC FORCES - AN ELECTRIC DETERMINISTICLATERAL DISPLACEMENT DEVICEJ.P. Beech, P. Jönsson, and J.O. TegenfeldtLund University, SWEDEN
M8AAUTOMATED DELIVERY OF SMALL FLUID VOLUMES THROUGH TUBING TO MICROFLUIDIC CHIPSK. Liu, C. Xia, C.K.-F. Shen, and R.M. van DamUniversity of California, Los Angeles, USA
M9ALOCALIZED BRAIN SLICE CHEMICAL STIMULATION USING A MICROFLUIDICDEVICE AND OFF-THE-SHELF PERFUSION CHAMBERH.H. Caicedo, J. Shaikh Mohammed, and C.P. Fall, and D.T. EddingtonUniversity of Illinois, Chicago, USA
MicrofluidicsFluid Mechanics & Modeling
MicrofluidicsWorld-to-Chip Interfacing
MicrofluidicsAliquoting, Mixing & Pumping
µTAS 2008 • San Diego4
MONDAY Program µTAS 2008 San Diego
M20ATUNABLE DELIVERY OF CHEMICAL GRADIENTS OVER LARGE CELL CULTURESUBSTRATES USING STACKED FLOWSC. Sip, H. Lai, and A. FolchUniversity of Washington, USA
M21AVENTURI-BASED TWO-LAYER MICROFLUIDIC PUMPING SYSTEMK. Hettiarachchi and A.P. LeeUniversity of California, Irvine, USA
M22AA NEW MICROFLUIDIC DEVICE FOR FORMATION AND SWITCHING OF MICRO-DROPLETSC.-Y. Lee1, Y.-H. Lin2, and G.-B. Lee1,2
1National Cheng Kung University, TAIWAN and2Industrial Technology Research Institute, TAIWAN
M23AMICROFLUIDIC ASSEMBLY OF CELL-LIKE SYSTEMS IN GIANT UNILAMELLAR LIPID VESICLESJ.C. Stachowiak, T.H. Li, D.L. Richmond, and D.A. FletcherUniversity of California, Berkeley, USA
M24ACLUSTER FORMATION AND EVOLUTION IN PARTICLE-LADEN MICROCHANNEL FLOWT. Gudipaty, L.S.L. Cheung, L. Jiang, and Y. ZoharUniversity of Arizona, USA
M25ADESIGN AND CHARACTERISATION OF MULTIPHASE LPG INTERFEROMETER USING DROPLETMICROFLUIDICSL.K. Chin, C.S. Lim, and A.Q. LiuNanyang Technological University, SINGAPORE
M26ADISPOSABLE, CONTINUOUS-FLOW BIOSENSOR FOR MULTI-ANALYTE MONITORING ANDMICROFLUIDIC CONTROL OF THE LINEAR RANGEO. Frey, S. Talaei, N.F. de Rooij, and M. Koudelka-HepUniversity of Neuchâtel, SWITZERLAND
M27AFAST, ROBUST AND SIMULTANEOUS SORTING WITH DROPLET GENERATION BYSYNCHRONIZED HIGH SWITCHING FREQUENCY OF ELECTROSTATIC ACTUATIONB. Ahn, R. Panchapakesan, K. Lee, and K.W. OhState University of New York, Buffalo, USA
M28AHIGH EFFICIENCY OF BIOCONJUGATION ON CARBOXYLATED COPOLYMERPARTICLES FABRICATED VIA A MICROFLUIDIC DEVICES.-H. Huang1, H.S. Khoo2, and F.-G. Tseng2
1National Taiwan Ocean University, TAIWAN and 2National Tsing Hua University, TAIWAN
M29ALIQUID CRYSTALLOGRAPHY IN MICROCHANNELSL. Shui1, S. Kooij2, J. C.T. Eijkel1, and A. van den Berg1
1MESA+, University of Twente, THE NETHERLANDS and 2University of Twente, THE NETHERLANDS
M30AMICROFLUIDIC DROPLET ADDER IN MICROCHANNELSE. Um and J.-K ParkKorea Advanced Institute of Science and Technology (KAIST), KOREA
M31AMICROFLUIDIC SPINNING OF BIODEGRADABLE POLYMER AND CELL ORIENTATIONCONTROL ON THE FIBERSC.M. Hwang1, K. Sun1, A. Khademhosseini2,3, and S.H. Lee1
1Korea University, KOREA, 2Massachusetts Institute of Technology, USA, and3Brigham and Women’s Hospital, Harvard Medical School, USA
M32AOPTOFLUIDIC ENCAPSULATION OF CRYSTALLINE COLLOIDAL ARRAYS USING PHOTOCURABLEDOUBLE EMULSION DROPLETSS.-H. Kim, S.-J. Jeon, and S.-M. YangKorea Advanced Institute of Science and Technology (KAIST), KOREA
M33AMICROWAVE TECHNIQUE FOR MONITORING PHASE SEPARATION OF A MULTIPHASE-FLOWREGIME UTILISED FOR CONTINUOUS MOLECULAR ENRICHMENTO. Castell, A. Masood, R. Göritz, D. Barrow, C. Allender, and A. PorchCardiff University, UK
M34ASINGLE MOLECULE DETECTION AND ISOLATION USING DROPLET MICROFLUIDICSM. Srisa-Art and J.B. EdelImperial College London, UK
M35ATWO-PHASE STRATIFIED FLOW OF LIQUID AND AIR IN PDMS MICROFLUIDIC CHANNELS FOROPTOFLUIDIC WAVEGUIDESJ.-M. Lim, S.-H. Kim, J.-H. Choi, and S.-M. YangKorea Advanced Institute of Science and Technology (KAIST), KOREA
M36AACOUSTOPHORESIS IN WET-ETCHED GLASS CHIPSA. Lenshof, M. Evander, T. Laurell, and J. NilssonLund University, SWEDEN
M37ACONTINUOUS SEPARATION OF PARTICLES USING INERTIAL LIFT FORCE AND VORTICITY VIAMULTI-ORIFICE MICROCHANNELJ.S. Park and H.-I. JungYonsei University, KOREA
M38AMICROFLUIDIC SELECTIVE ELECTROCHEMICAL LYSIS (µSEL) FOR ISOLATING PROKARYOTESFROM BIOLOGICAL SAMPLESR.M. Cooper, J.T. Nevill, M. Dueck, and L.P. LeeUniversity of California, Berkeley, USA
M39AHIGH-THROUGHPUT CELL SORTER WITH PIEZOELECTRIC ACTUATIONC.H. Chen, S.H. Cho, A. Erten, and Y.-H. LoUniversity of California, San Diego, USA
M40AINTEGRATED IMMUNOAFFINITY MONOLITH/POLYACRYLAMIDE-MEMBRANE/ELECTROPHORESISMICRODEVICES FOR TRACE BIOMARKER ANALYSISW. Yang, X. Sun, and A.T. WoolleyBrigham Young University, USA
M41AMULTIPLE NODE ULTRASONIC STANDING WAVE SEPARATION IN MICROCHANNELSIMPROVES LIPID DISCRIMINATION FROM COMPLEX BIO-SUSPENSIONSC. Grenvall1, P. Augustsson1, H. Matsuoka2, and T. Laurell11Lund University, SWEDEN and 2Tokyo University of Agriculture and Technology, JAPAN
M42APINCHED FLOW FRACTIONATION DEVICE FOR SIZE- AND DENSITY-DEPENDENTSEPARATION OF PARTICLES UTILIZING CENTRIFUGAL PUMPINGS. Sunahiro1, M. Senaha2, M. Yamada3, and M. Seki1,2
1Osaka Prefecture University, JAPAN, 2Chiba University, JAPAN, and3Tokyo Women's Medical University, JAPAN
MicrofluidicsMulti-Phase Microfluidics
MicrofluidicsSeparation Methods
µTAS 2008 • San Diego 5
MONDAY ProgramSan Diego µTAS 2008
M43ARAPID AND SELECTIVE CONCENTRATION OF MICROPARTICLES USINGOPTOELECTRO-OSMOTIC FLOW IN LAB-ON-A-DISPLAYH. Hwang and J.-K. ParkKorea Advanced Institute of Science and Technology (KAIST), KOREA
M44ASIZE SEPARATION OF PARTICLES USING FLOW-INDUCED ELECTROKINETIC TRAPPINGL.C. Jellema1, A.P. Markesteijn2, J. Westerweel2, and E.M.J. Verpoorte1
1University of Groningen, THE NETHERLANDS and 2Delft University of Technology, THE NETHERLANDS
M45ASPATIALLY-MULTIPLEXED PROTEIN SEPARATIONS ENABLED BY MULTIFUNCTIONALPHOTOPOLYMERIZED GELSS. Yang, J. Liu, and D.L. DeVoeUniversity of Maryland, USA
M46AA DROPLET ON DEMAND MICROFLUIDIC DEVICE FOR DETECTING DNA SINGLEBASE SUBSTITUTION USING PNA PROBES. Kaneda, T. Nojima, T. Yamamoto, and T. FujiiUniversity of Tokyo, JAPAN
M47AAPPLICATION OF TOPOLOGY OPTIMIZATION IN LAB-ON-A-CHIP DESIGNF. Okkels and H. BruusTechnical University of Denmark, DENMARK
M48AELECTROCHEMICAL BUBBLE-ACTUATED MICROVALVES AND PERISTALTIC PUMPS BASED ONEMBEDDED SU-8 MICROCANTILEVERSA. Ezkerra1, L.J. Fernández1, A. Wolff2, K. Mayora1, and J.M. Ruano-López1
1Ikerlan S. Coop., SPAIN and 2Technical University of Denmark (DTU), DENMARK
M49AA MICROFLUIDIC DEVICE FOR TISSUE BIOPSY CULTURE AND INTERROGATIONA. Webster, C.E. Dyer, K.J. Welham, A.M.L. Seymour, J. Greenman, and S.J. HaswellUniversity of Hull, UK
M50AON-CARD DRY REAGENT STORAGE FOR DISPOSABLE MICROFLUIDIC IMMUNOASSAYSD.Y. Stevens1, C.R. Petri2, and P. Yager11University of Washington, USA and 2Boston College, USA
M51ASOLVING THE SHRINKAGE-INDUCED PDMS REGISTRATION PROBLEM INMULTILAYER SOFT LITHOGRAPHYC. Moraes, C.A. Simmons, and Y. SunUniversity of Toronto, CANADA
M52ATOWARDS SIMULTANEOUS ELECTRICAL AND OPTICAL INVESTIGATION OF BLMS USING A NOVELMICROFLUIDIC DEVICEI. van Uitert, Y. Cesa, H. de Boer, J. Bomer, M. Bennink, S. Le Gac, and A. van den BergUniversity of Twente, THE NETHERLANDS
M2BELECTRO-PRECONCENTRATION OF BIO-MOLECULES IN NANOFLUIDIC DEVICESA. Plecis, C. Nanteuil, A.M. Haghiri-Gosnet, and Y. ChenCentre National de la Recherche Scientifique (CNRS), Marcoussis, FRANCE
M3BFABRICATION AND CHARACTERIZATION OF REVERSIBLY BONDED NANOFLUIDIC CHANNELSP. Kim, J.K. Kim, and K.Y. SuhSeoul National University, KOREA
M4BION PUMPING IN NANOCHANNELS USING AN ASYMMETRIC ELECTRODE ARRAYW. Sparreboom, C.F. Cucu, J.C.T. Eijkel, and A. van den BergUniversity of Twente, THE NETHERLANDS
M5BOPTOFLUIDIC MANIPULATION WITH SUB-WAVELENGTH SCALE PHOTONICSA.H.J. Yang, S.D. Moore, B.S. Schmidt, M. Lipson, and D. EricksonCornell University, USA
M6BTHE EFFECTS OF CONCENTRATION POLARIZATION ON MOLECULE TRANSLOCATIONIN A NANOPORE DEVICET.A. Zangle, A.H. Talasaz, R.W. Davis, and J.G. SantiagoStanford University, USA
M1BAMPLIFIED ELECTROKINETIC FLUID PUMPING AND SWITCHING BY CONCENTRATIONPOLARIZATION NEAR NANOFLUIDIC CHANNELS.J. Kim and J. HanMassachusetts Institute of Technology, USA
M7BCELL RUPTURE MICROFLUIDIC DEVICE USING NANO NEEDLE ALLAY FORDAMAGE-FREE EXTRACTION OF ORGANELLEST. Arakawa1,3, Y. Shirasaki2, D. Yamazaki1, T. Funatsu3, and S. Shoji11Waseda University, JAPAN, 2Kazusa DNA Research Institute, JAPAN, and3University of Tokyo, JAPAN
M8BENCAPSULATION OF PAL ENZYMES IN FLUORINATED REVERSE EMULSIONSP.R. Marcoux1, N. Faure2, V. Lanet2, P. Joly1, M. Dupoy1, F. Rivera1, F. Mallard2, and J.-P. Moy1
1CEA-LETI, FRANCE and 2bioMérieux, FRANCE
M9BINTEGRATION OF IMMUNOASSAY INTO EXTENDED NANOSPACE FOR ANALYSISAT SINGLE-MOLECULE LEVELF. Hiruma1, K. Mawatari2, T. Tsukahara1, and T. Kitamori1,2
1University of Tokyo, JAPAN and 2Kanagawa Academy of Science and Technology, JAPAN
M10BMICROFLUIDIC SELECTION OF LIBRARY ELEMENTSD.J. Solis, R. Lovchik, and E. DelamarcheIBM Research Gmbh, SWITZERLAND
M11BNANOTECHNOLOGY MEETS PLANT BIOTECHNOLOGY: CARBON NANOTUBES DELIVERDNA AND INCORPORATE INTO THE PLANT CELL STRUCTUREM. Fouad1, N. Kaji1, M. Jabasini1, M. Tokeshi1, and Y. Baba1,2
1Nagoya University, JAPAN and2National Institute of Advanced Industrial Science & Technology (AIST), JAPAN
Microfluidics
NanotechnologyNanofluidics
NanotechnologyNanobiotechnology
M12BCELL DRIVEN NANO LOCOMOTIONT. Hoshino1, Y. Hori1, T. Konno2, K. Ishihara2, and K. Morishima1
1Tokyo University of Agriculture and Technology, JAPAN and 2University of Tokyo, JAPAN
NanotechnologyNanoassembly
µTAS 2008 • San Diego6
MONDAY Program µTAS 2008 San Diego
M13BELECTRICAL MANIPULATION OF GOLD NANOPARTICLES FOR MICROFLUIDIC APPLICATIONSD.R. Reyes, G.I. Mijares, K.A. Briggman, J. Geist, and M. GaitanNational Institute of Standards and Technology (NIST), USA
M14BTEMPLATE-GUIDED SELF-ASSEMBLY OF BIOMIMETIC POLYMERS USINGEVAPORATION-ASSISTED PLASMA LITHOGRAPHYJ. Keyes1, M. Junkin1, J. Cappello2, X. Wu1, and P.K. Wong1
1University of Arizona, USA and 2Protein Polymer Technologies, Inc., USA
M1CA UNIVERSAL SURFACE MODIFICATION PROTOCOL FOR ACTIVE SURFACE CATALYTIC MICRODEVICESC.J. Cullen1, P. Williams2, and R.C.R. Wootton2
1Imperial College London, UK and 2Liverpool John Moores University, UK
M2CCARBON NANOTUBES PRESSURE SENSORS MODIFIED FOR CHEMICAL ANALYSISR. Ficek1, R. Vrba1, L. Zajickova2, O. Jasek2, and F. Matejka31Brno University of Technology, CZECH REPUBLIC, 2Masaryk University, CZECH REPUBLIC, and3Academy of Sciences of the Czech Republic, CZECH REPUBLIC
M3CDUAL FUNCTION SURFACE PREPARED ON POLYMERIC SUBSTRATE FOR HIGHLY SENSITVEIMMUNOASSAY-BASED MICROARRAY BIOSENSORSJ. Sibarani1,2, M. Takai1, and K. Ishihara1
1University of Tokyo, JAPAN and 2University of Udayana, INDONESIA
M4CROBUST SURFACE MODIFICATION FOR PROTEIN SEPARATION CHIP USINGA FILM OF A CELLULOSE DERIVATIVEH. Okada1, N. Kaji1, M. Tokeshi1, and Y. Baba1,2
1Nagoya University, JAPAN and 2National Institute of Advanced Industrial Science and Technology(AIST), JAPAN
M5CSURFACE MODIFICATION OF POLY(METHYL METHACRYLATE) MICROFLUIDIC DEVICESUSING THIN FILMS WITH ENTRAPPED HYDROXYPROPYL CELLULOSEX. Sun, W. Yang, and A.T. WoolleyBrigham Young University, USA
MaterialsSurface Modification
M7CA HYDRODYNAMICALLY FOCUSED STREAM AS A DYNAMIC TEMPLATE FOR SITE-SPECIFICELECTROCHEMICAL MICROPATTERNING OF CONDUCTING POLYMERSS. Wang, S. Hou, Z.T.F. Yu, K. Liu, J. Sun, W.-Y. Lin, C.K.F. Shen, and H.R. TsengUniversity of California, Los Angeles, USA
M8CFLUORESCENCE ENHANCEMENT USING SILVER NANO PARTICLES FABRICATEDBY MODIFIED SILVER MIRROR REACTIONK. Kurooka1, K. Hanada1, K. Deguchi1, H. Kojima1, T. Chishiro1, D. Citterio1,2,K. Suzuki1,2, T. Saiki1,2, and N. Miki1,2
1Keio University, JAPAN and 2Kanagawa Academy of Science and Technology, JAPAN
M9CMETALLIZATION OF SILICON NANOWIRES AND SERS RESPONSE FROMA SINGLE METALLIZED NANOWIREC. Fang, A. Agarwal, L. Linn, and N. Balasubramanian Agency for Science, Technology and Research (A*Star), SINGAPORE
M10CSYNTHESIS OF PALLADIUM NANOPARTICLES FROM ORGANOMETALLICCHEMISTRY ROUTE IN A TWO PHASE FLOW MICROREACTORS. Desportes, D.M. Fries, F. Trachsel, and P. Rudolf von RohrETH Zurich, SWITZERLAND
MaterialsNanostructured Materials
M11CFEMTOSECOND-LASER-BASED FUSED SILICA MICROMACHINING FOR µTAST. Haddock, and P. BadoTranslume, Inc., USA
M12CSHRINKY-DINK WRINKLESC.-S. Chen, A. Grimes, A. Gopinathan, and M. KhineUniversity of California, Merced, USA
M13CVISCOELASTIC CHARACTERIZATION OF SOFT MICROPILLARS FOR CELLULAR MECHANICS STUDYI.-K. Lin, Y.-M. Liao, K.-S. Chen, and X. Zhang1Boston University, USA and 2National Cheng Kung University, TAIWAN
MaterialsInnovative Chip Materials
M1DA HIGH-SENSITIVITY ON-CHIP FLUORESCENCE DETECTION FOR LAB-ON-A-CHIPY. Shuai, A. Banerjee, D. Klotzkin, and I. PapautskyUniversity of Cincinnati, USA
M2DA NOVEL AIR/NANOPOROUS DIELECTRIC CLAD OPTOFLUIDIC WAVEGUIDESYSTEM FOR SENSOR APPLICATIONSV. Korampally, M. Hossain, M. Yun, K. Gangopadhyay, L. Polo-Parada, and S. GangopadhyayUniversity of Missouri, USA
M3DA THERMALLY TUNABLE MICROLENS ARRAY ON INDIUM TIN OXIDE GLASSX. Huang, B. Wang, J. Song, and Q. LinColumbia University, USA
Detection TechnologiesOptical
MaterialsInterface Characterization
M15BNANOCAVITY-NANOPARTICLE MIRROR STRUCTURE FOR OPTIMIZATION OFLOCAL FIELD ENHANCEMENTB.M. Ross and L.P. LeeUniversity of California, Berkeley, USA
M6CCREATING CELLULAR MICROPATTERNS BY SWITCHING FOULING PROPERTIESOF ELECTROACTIVE ITO SURFACESS.S. Shah, JY. Lee, and A. RevzinUniversity of California, Davis, USA
Nanotechnology
µTAS 2008 • San Diego 7
MONDAY ProgramSan Diego µTAS 2008
M4DDETECTION OF THROMBIN BY APTAMER-BASED SURFACE ENHANCED RESONANCERAMAN SPECTROSCOPYH. Cho1, B.R. Baker2, S. Wachsmann-Hogiu3, C. Pagba3, T. Laurence2, S.M. Lane3, L.P. Lee1,and J.B.-H. Tok2
1University of California, Berkeley, USA, 2Lawrence Livermore National Laboratory, USA, and3University of California, Davis, USA
M5DDEVELOPMENT OF SOLID STATE LASER-INDUCED-FLOURESENCE DETECTION SYSTEMK. Yano1,3, T. Ohtsuka2, M. Katayama2, T. Kanie2, and D. Ehrlich3
1afiZEx Technologies., Inc., USA, 2Sumitomo Electric Industries, Ltd. JAPAN, and3Massachusetts Institute of Technology, USA
M6DDYNAMIC IMAGING OF SINGLE BIOMOLECULAR INTERACTION USING FLOW CONTROL ANDTIRFMT. Arakawa1,3, T. Sameshima3, Y. Sato1, Y. Sumiyoshi1, T. Ueno3, Y. Shirasaki2, T. Funatsu3,and S. Shoji11Waseda University, JAPAN, 2Kazusa DNA Research Institute, JAPAN, and 3University of Tokyo, JAPAN
M7DGENERATION AND DETECTION OF LAMINAR FLOW WITH LATERALLY-VARYINGOXYGEN CONCENTRATION LEVELSV. Nock, R.J. Blaikie, and T. DavidUniversity of Canterbury, NEW ZEALAND
M8DHIGH SENSITIVITY SESSILE DROPLET RESONATOR FOR LOW CONCENTRATION PROTEINDETECTIONY.F. Yu1,2, T. Bourouina2, C.S. Lim1, M.K. Chin1, and A.Q. Liu1
1Nanyang Technological University, SINGAPORE and2Ecole Superieure d'Ingnieurs en Electronique et Electrotechnique, FRANCE
M9DLASER-SCANNING FLOW CYTOMETER WITH A THREE-DIMENSIONAL MICROFLUIDIC CHIPS. Imanishi1, M. Furuki1, M. Shinoda1, Y. Morita2, Y. Yamazaki2, and H. Nakauchi21Sony Corporation, JAPAN and 2University of Tokyo, JAPAN
M10DMICROGAP FILTERING BASED LASER-INDUCED FLOURESCENCE DETECTION SYSTEMFOR HING-EFFICIENCY MICROFLUIDIC ELECTROPHORESIS ANALYSISQ.-H. Jin, B.-J. Xu, X.-C. Liao, H.-L. Zhang, and J.-L. ZhaoShanghai Institute of Microsystem and Information Technology, CHINA
M11DON-CHIP ELECTROKINETIC SAMPLE FOCUSING FOR MICROARRAY-BASEDBIOMOLECULAR INTERACTION ASSAYSG. Krishnamoorthy, E.T. Carlen, D. Kohlheyer, R. Schasfoort, and A. van den BergMESA+, University of Twente, THE NETHERLANDS
M12DOPTOFLUIDIC DEVICE FOR ULTRA-SENSITIVE MOLECULE DETECTION USING SURFACE-ENHANCED RAMAN SPECTROSCOPYM. Wang, N. Jing, M. Benford, I.-H. Chou, H.T. Beier, G.L. Coté, and J. KameokaTexas A&M University, USA
M13DSENSITIVE OPTICAL ABSORBANCE MEASUREMENTS ON A MICROFLUIDIC DEVICE USINGCONDUCTIVITY-BASED PHOTOTHERMAL DETECTIONE.R. Ferguson, P.J. Dennis, J.P. Alarie, J.M. Ramsey, and J.W. JorgensonUniversity of North Carolina, Chapel Hill, USA
M15DHIGH SENSITIVITY PH SENSING USING SCHOTTKY CONTACTED SILICON NANOWIREFIELD-EFFECT TRANSISTORS.K. Yoo, I.-H. Hwang, B.P. Mun, and J.H. LeeGwangju Institute of Science and Technology (GIST), KOREA
M16DMULTIMODAL PH AND LIGHT IMAGING DEVICES FOR DYNAMIC CHEMICALREACTION OBSERVATIONJ. Matsuo1, K. Sawada1,2,3, H. Takao1,2,3, and M. Ishida1,2,31Toyohashi University of Technology, JAPAN, 2Intelligent Sensing System Research Center, JAPAN, and3Japan Science and Technology Agency (JST), JAPAN
M17DAPPLYING ELECTRIC CELL-SUBSTRATE IMPEDANCE SENSING (ECIS) TO STUDY CELL ADHESIONAND CELL SPREADING OF AN INDIVIDUAL CELLP. Seriburi and D.R. MeldrumMicroscale Life Sciences Center, USA
M14DA MINIATURIZED CMOS MICROELECTRODE ARRAY SYSTEM FOR SINGLE DROPLETELECTROCHEMISTRY APPLICATIONSS. Hwang, V. Agarwal, C. LaFratta, J. Yu, D. Walt, and S.SonkusaleTufts University, USA
Detection TechnologiesElectrochemical
M1EA SINGLE MASK SINGLE-ETCH PROCESS FOR CONSTRUCTING THREE DIMENSIONALMICRO TOTAL ANALYSIS SYSTEMSP.A. Zellner and M. AgahVirginia Polytechnic Institute and State University, USA
M2ECONTROLLED MICROFRACTURE AND FOCUSED ION BEAM FOR MICRONOZZLE PROCESSINGM.J. Lopez1, E.M. Campo1, R. Pérez-Castillejos1,2, J. Esteve1, and J.A. Plaza1
1Centro Nacional de Microelectrónica, SPAIN and 2Harvard University, USA
M3EFABRICATION OF HYDRODYNAMICALLY-SHAPED SUB-MICRON PMMA FILAMENTSA.L. Thangawng, J.S. Erickson, P.B. Howell, and F.S. LiglerNaval Research Laboratory, USA
M4EMICROFABRICATION OF DUAL OPPOSITE SILVER ELECTRODES INSIDE A MICROCHANNEL BYMEANS OF MULTIPHASE LAMINAR FLOW WITH DENSITY DIFFERENCES.-H. Paek1, J.S. Kim2, C.J. Hwang2, Y.K. Choi1, and D.S. Kim1
1Chung-Ang University, KOREA and 2Korea Institute of Industrial Technology (KITECH), KOREA
MEMS & NEMS TechnologiesMicro & Nano-Machining
M18DIMPROVED PROTEIN BINDING RATE FOR BIOSENSORS USING AC ELECTROOSMOSISR. Hart, R.M. Lec, and H. NohDrexel University, USA
M19DLABEL-FREE, SINGLE-CELL CYTOTOXIN KINETICS ASSAY BY DIFFERENTIALIMPEDANCE SPECTROSCOPYD. Malleo1, J.T. Nevill2, L.P. Lee2, and H. Morgan1
1University of Southampton, UK and 2University of California, Berkeley, USA
M20DON-CHIP COULTER COUNTER WITH VARIABLE APERTURE USING A TWO LAYERSU-8 PROCESS FOR IMPROVED SAMPLE FOCUSINGS. Kostner and M.J. VellekoopVienna University of Technology, AUSTRIA
M21DQUANTIFICATION OF AMYLOID FIBRILIZATION BY SIMULTANEOUS DUAL MODE DETECTION WITHOPTICAL SCATTERING IMAGE DIELECTRIC RELAXATION SPECTROSCOPYY. Choi and L.P. LeeUniversity of California, Berkeley, USA
Detection Technologies
µTAS 2008 • San Diego8
MONDAY Program µTAS 2008 San Diego
M6EA MODULAR DISPENSING SYSTEM FOR LEAKAGE-FREE PICOLITER DROPLET RELEASEIN LIQUID ENVRIONMENTSJ. Steigert, M. Strasser, O. Brett, N. Wangler, W. Streule, P. Koltay, M. Daub, and R. ZengerleUniversity of Freiburg (IMTEK), GERMANY
M7EASSEMBLY-FREE MICROFABRICATION PROCESS FOR MULTI-LAYERED MICROFLUIDICNETWORKS USING SINGLE-MASK MULTIDIRECTIONAL PHOTOLITHOGRAPHYT. Suzuki1, Y. Hirabayashi2, I. Kanno2, M. Washizu3,4, and H. Kotera2,4
1Kagawa University, JAPAN, 2Kyoto University, JAPAN, 3Japan Science and Technology Agency (JST),JAPAN, and 4University of Tokyo, JAPAN
M8EDETERMINISTIC STORAGE OF LIQUID PLUGS IN MICROFLUIDIC CHANNELS USING PASSIVE VALVESJ. Atencia and L.E. LocascioNational Institute of Standards and Technology (NIST), USA
M9EELECTROSTATIC HYDRAULIC THREE-WAY GAS MICROVALVE FOR HIGH-PRESSURE APPLICATIONSH. Kim and K. NajafiUniversity of Michigan, USA
M10EFAST SELF-DIRECTED MICROLITER DROPLET MOVEMENTS INDUCED BYNANOTOPOGRAPHIC-ENHANCED GRADIENT SURFACESH.S. Khoo1 and F.-G. Tseng1,2
1National Tsing Hua University, TAIWAN and 2Academia Sinica, TAIWAN
M11EMASSIVE FORMATION OF UNIFORM-SIZED EMBRYONID BODIES IN ALGINATE WITHTHE REGULATION OF ENCAPSULATED CELL NUMBERC. Kim1,2, K.S. Lee3, E. Kang1, J.H. Kim1, K.J. Lee2, T.S. Kim1, and J.Y. Kang1
1Korea Institute of Science and Technology (KIST), KOREA, 2Korea University, KOREA, and3State University of New York, Buffalo, USA
M12EMICROFLUIDIC GLASS NEEDLE ARRAYS FOR DRUG DOSING DURING NEURAL RECORDINGE. Vrouwe, A.J. Kelderman, and M. BlomMicronit Microfluidics, THE NETHERLANDS
M13EOPTICAL TRAPPING IN A MICROFLUIDIC CHANNEL USING AN INTEGRATED FRESNEL ZONE PLATEE. Schonbrun1, J. Wong2, and K.B. Crozier11Harvard University, USA and 2Schlumberger-Doll Research Center, USA
M14EPORTABLE MICRO LIQUID DISPENSER SYSTEM WITH PRESSURIZATION AND DECOMPRESSIONSWITCHABLE MICRO PUMP CHIPT. Hasegawa1, F. Omatsu2, and K. Ikuta3
1Shibaura Institute of Technology, JAPAN, 2Osaka Institute of Technology, JAPAN, and3Nagoya University, JAPAN
M15EPROPOSAL OF A MICRO LIQUID ROTOR OPERATED BY SURFACE-ACOUSTIC-WAVET. Saiki1,2, K. Okada2, and Y. Utsumi21Hyogo Prefectural Institute of Technology, JAPAN and 2University of Hyogo, JAPAN
M16ESYNTHESIS OF CARBON NANOTUBES AT “ROOM TEMPERATURE” USING CAPILLARYMICROFLUIDICS AND DIP PEN TECHNIQUESR. Gargate and D. BanerjeeTexas A&M University, USA
MEMS & NEMS TechnologiesMicrofluidic Components
MEMS & NEMS TechnologiesHybrid Devices, Packaging & Components Interfacing
M17EA NEW FLEXIBLE MICROFABRICATED POLYMIDE-BASED PLATINUM ELECTRODES FORSTIMULATION OF RAT RETINAL TISSUE IN VITRO AND RECORDING USING A MULTI-ELECTRODE ARRAYH. Kasi1, B. Kolomiets3,4, S. Picaud2,3,4, J.A. Sahel3, and P. Renaud1
1Swiss Federal Institute of Technology at Lausanne (EPFL), SWITZERLAND, 2INSERM-U592, FRANCE,3Fondation Ophtalmologique Ade Rothschild, FRANCE, and 4Université Pierre et Marie Curie, FRANCE
M18EMICROMANIPULATION OF MICROTOOLS MADE OF SU-8 BY INTEGRATED OPTICAL TWEEZERSF. Arai, K. Onda, H. Matsumoto, and R. IitsukaTohoku University, JAPAN
M19EROBUST HYBRIDIZATION OF NANOSTRUCTURED BURIED INTEGRATED OPTICALWAVEGUIDE SYSTEMS WITH ON-CHIP FLUID HANDLING FOR CHEMICAL ANALYSISK.B. Gylfason1, B. Sánchez2, A. Griol2, C.A. Barrios3, H. Sohlström1, M.J. Bañuls2, V. González-Pedro2,Á. Maquieira2, M. Holgado3, R. Casquel3, D. Hill2, and G. Stemme1
1Royal Institute of Technology (KTH), SWEDEN, 2Universidad Politécnica de Valencia, SPAIN, and3Universidad Politécnica de Madrid, SPAIN
MEMS & NEMS TechnologiesIntegration “Sample to Result” Systems
M20EA COMPACT MICROFLUIDIC SYSTEM WITH AN INTEGRATED OPTICAL SYSTEM FORSINGLE-MOLECULE DETECTION VIA FLUORESCENCE RESONANCE ENERGY TRANSFERFOR REAL-TIME MOLECULAR ANALYSESJ.M. Emory, Z. Peng, F. Crawford-Drake, P.-C. Chen, M.C. Murphy, and S.A. SoperLouisiana State University, USA
M21ECONTINUOUS MONITORING OF RARE WATERBORNE BACTERIA VIA DIELECTROPHORESIS-ENHANCED POLYMERASE CHAIN REACTION (DEPCR) DEVICEK. Hsieh, B.S. Ferguson, and H.T. SohUniversity of California, Santa Barbara, USA
M22EINTEGRATED MICROFLUIDIC CAPILLARY ELECTROPHORESIS SYSTEM FOR BIOCHEMICALANALYSIS ON MARS AS PART OF THE UREY INSTRUMENTP.A. Willis1, J.A. Smith1, F. Greer1, F.J. Grunthaner1, L. Epp1, D. Hoppe1, T.N. Chiesl2,R.A. Mathies2, J.J. Sprague3, and J.P. Rolland3
1NASA Jet Propulsion Laboratory, USA, 2University of California, Berkeley, USA, and3Liquidia Technologies Inc., USA
M23ELOW-COST, FULLY INTEGRATED LIQUID HANDLING PLATFORM FOR PROTEIN ASSAYSJ. Nestler1, K. Hiller1, A. Morschhauser1, S. Bigot2, C. Griffiths2, J. Auerswald3, J. Gavillet4,G. Nonglaton4, T. Otto5, and T. Gessner1,5
1Chemnitz University of Technology, GERMANY, 2Cardiff University, UK, 3CSEM, SWITZERLAND,4Commissariat à l’Energie Atomique (CEA), FRANCE, and5Fraunhofer Research Institution for Electronic Nano Systems (ENAS), GERMANY
M24EINTEGRATED MICROFLUIDIC ELECTROCHEMICAL DNA SENSOR (IMED)B.S. Ferguson, J.S. Swensen, K. Hsieh, and H.T. SohUniversity of California, Santa Barbara, USA
M25ERAPID POINT OF CARE (POC) BLOOD ANALYSIS USING INTEGRATED DYNAMIC BLOODSEPARATION AND SANDWICH IMMUNOASSAY ON A POLYMER LAB CHIPA.W. Browne, W.Jung, K.K. Lee, S.H. Lee, J. Do, and C.H. AhnUniversity of Cincinnati, USA
M5EMONOLITHICAL INTEGRATION OF FORCE SENSOR, SIGNAL-PROCESSING CIRCUITRY ANDSELF-ASSEMBLED CELLS FOR CHARACTERIZATION OF MUSCLES' MECHANICSX. Ji, L. Wang, J. Xi, and Z.H. LiPeking University, CHINA
µTAS 2008 • San Diego 9
MONDAY ProgramSan Diego µTAS 2008
M10F96-IMMUNOASSAY DIGITAL MICROFLUIDIC MULTIWELL PLATER.S. Sista, A. Sudarsan, V. Srinivasan, A.E. Eckhardt, M.G. Pollack, and V.K. PamulaAdvanced Liquid Logic Inc., USA
M11FA VERSATILE PLATFORM FOR RAPID LABEL-FREE DETECTION OF PROTEINS ANDSMALL MOLECULES USING MICROFABRICATED ELECTRODE ARRAYSY.-W. Huang, F.A. Shaikh, and V.M. UgazTexas A&M University, USA
M12FANALYSIS OF WHOLE BLOOD PLATELET TRANSLOCATION ON A VWF-COATEDMICROFLUIDIC FLOW CHAMBERB. Lincoln1, G. Meade2, N. Kent1, L. Basabe-Desmonts1, D. Kenny2, A.J. Ricco1, and L.P. Lee1,3
1Dublin City University, IRELAND, 2Royal College of Surgeons in Ireland, IRELAND, and3University of California, Berkeley, USA
M13FCELLSCOPE: MOBILE MICROSCOPY FOR SINGLE CELL ANALYSISD.N. Breslauer1, R.N. Maamari1, W. Lam2, T. Hunt1, L.P. Lee1, and D.A. Fletcher11University of California, Berkeley, USA and 2University of California, San Francisco, USA
M14FHIGH PERFORMANCE ACETYLCHOLINE BIOSENSOR USING CHARGE TRANSFER TECHNIQUES.-R Lee1, K. Sawada1, H. Takao1, M. Ishida1, and H.D. Seo2
1Toyohashi University of Technology, JAPAN and 2Yeungnam University, JAPAN
M15FLAB-ON-A-DISC FOR SIMULTANEOUS ANALYSIS OF BLOOD CHEMISTRY AND IMMUNOASSAY Y.-K. Cho1, J.-M. Park2, B.-S. Lee2, S. Kim2, and J.-G. Lee2
1Ulsan National Institute of Science and Tecchnology (UNIST), KOREA and 2Samsung AdvancedInstitute of Technology (SAIT), KOREA
M16FMICROFLUIDIC ENUMERATION PROTOCOL FOR COMPREHENSIVE PROFILINGOF NUCLEATED CELLS IN MILD PHENOTYPE SICKLE CELL DISEASE (SCD)W.N. White, A. Raj, M.D. Nguyen, S.J. Bertolone, and P. SethuUniversity of Louisville, USA
M17FPORTABLE MICROELISA SYSTEM FOR TOXICOLOGICAL HAIR ANALYSIST. Ohashi1, H. Miyaguchi2, H. Takahashi1, K. Mawatari1, Y.T. Iwata2, H. Inoue2, and T. Kitamori1,3
1Kanagawa Academy of Science and Technology, JAPAN, 2National Research Institute of PoliceScience, JAPAN, and 3University of Tokyo, JAPAN
M18FON-CHIP SURFACE PLASMON RESONANCE MEASUREMENT OF DISEASE MARKER PROTEIN ANDSMALL METABOLITE COMBINED WITH IMMUNO AND ENZYMATIC REACTIONSK. Nakamoto1,2, N. Sekioka1,2, R. Kurita2, and O. Niwa1,2
1University of Tsukuba, JAPAN and2National Institute of Advanced Industrial Science and Technology (AIST), JAPAN
ApplicationsGenomics & Proteomics
ApplicationsClinical Diagnostics
M19FDYNAMIC MICROFLUIDIC DEVICES WITH NANOCHANNELS FOR THE ARRAYOF 1MICRON-SIZED OBJECTSK. Iwai, N. Misawa, and S. TakeuchiUniversity of Tokyo, JAPAN
M20FHIGHLY EFFICIENT SINGLE CELL CAPTURING IN MICROWELL ARRAY USING HYDRODYNAMICGUIDING STRUCTURESJ. Chung1, Y.-J. Kim1, I.-J. Cho2, and E. Yoon2
1University of Minnesota, USA and 2University of Michigan, USA
M21FMICROFLUIDIC PROCESSING OF DIAGNOSTIC AND COMMERCIAL DNA MICROARRAYSJ. Petersen1, L. Poulsen2, L.B. Moller3, H.S. Birgens1, and M. Dufva2
1Copenhagen University Hospital, DENMARK, 2Technical University of Denmark, DENMARK, and3Kennedy Center, DENMARK
ApplicationsMicroarrays
M1FDEVELOPMENT OF APTAMER-BASED AFFINITY ASSAYS USING TEMPERATUREGRADIENT FOCUSING: MINIMIZATION OF THE LIMIT OF DETECTIONM.S. Munson, J.M. Meacham, D. Ross, and L.E. LocascioNational Institute of Standards and Technology (NIST), USA
M2FINTEGRATED ONE-STEP AND TWO-STEP GENE SYNTHESIS ON A CHIPM.C. Huang, Y.K. Kuan, H. Ye, M.-H. Li, and J.Y. YingInstitute of Bioengineering and Nanotechnology, SINGAPORE
M3FMICROCHIP INTEGRATED ROLLING CIRCLE AMPLIFICATION FOR SINGLE DNAMOLECULE DETECTION IN MINUTE SAMPLE VOLUMESA. Tachihara1, K. Sato1, B. Renberg1, Y. Tanaka2, J. Jarvius2, M. Nilsson2, and T. Kitamori11University of Tokyo, JAPAN and 2Uppsala University, SWEDEN
M4FMICROFLUIDIC REVERSED PHASE COLUMN ARRAY FOR LIQUID CHROMATOGRAPHY -DUAL IONIZATION MODE MASS SPECTROMETRY SHOTGUN PROTEOMIC ANALYSISD.R. Knapp, J. Liu, R. Nayak, and D. HigbeeMedical University of South Carolina, USA
M5FNANOPILLAR CHIPS ARRANGED IN TILTED ARRAY PATTERN FORFAST SEPARATION OF DNA AND PROTEINST. Yasui1, N. Kaji1, M. Reza Mohamadi2, R. Ogawa3, S. Hashioka3,M. Tokeshi1, Y. Horiike3, and Y. Baba1,4,5
1Nagoya University, JAPAN, 2Institut Curie, FRANCE, 3National Institute for Materials Science, JAPAN,4National Institute for Advanced Industrial Science and Technology (AIST), JAPAN, and5Institute for Molecular Science, JAPAN
M6FON-LINE DETECTION OF PRION PROTEIN IN A MICROFLUIDIC CHIPA. Le Nel1, C. Smadja2, J.-M. Peyrin3, J.-L. Viovy1, and M. Taverna2
1Curie Institute, FRANCE, 2University of Paris, Sud, FRANCE, and 3CNRSI-UMR7102, FRANCE
M7FPARALLEL MONITORING OF SINGLE CELL RESPIRATION ACTIVITY BY USING MICROARRAYEDOXYGEN SENSORSM. Suzuki, T. Yamada, S. Kato, and Y. IribeUniversity of Toyama, JAPAN
M8FREAL-TIME MONITORING OF CONFORMATIONAL TRANSITION OF DNA AT A SINGLEMOLECULE LEVEL IN MICROFLUIDIC DEVICESK. Fujiyoshi1, N. Kaji1, M. Tokeshi1, and Y. Baba1,2
1Nagoya University, JAPAN and2National Institute of Advanced Industrial Science and Technology (AIST), JAPAN
M9FSYNTHESIS OF SILICA MICROPARTICLES WITH STEP-EMULSIFICATION MICROFLUIDICSV. Chokkalingam1, B. Weidenhof2, W.F. Maier2, S. Herminghaus1, and R. Seemann1,2
1Max Planck Institute for Dynamics and Self-Organization, GERMANY and2Saarland University, GERMANY
µTAS 2008 • San Diego10
MONDAY Program µTAS 2008 San Diego
M23FDEVELOPMENT OF A MICROFLUIDIC SOUTHERN HYBRIDIZATION ANALYSIS SYSTEMK. Sato1,2, H. Harada1, Y. Sakamoto1, and E. Yoshimura1
1University of Tokyo, JAPAN and 2Japan Science and Technology Agency, JAPAN
M24FHIGH PERFORMANCE MULTIPLE BIOMOLECULES SORTING SYSTEMK. Ozaki1, H. Sugino2, T. Arakawa1,2, Y. Shirasaki3, T. Funatsu2, and S. Shoji11Waseda University, JAPAN, 2University of Tokyo, JAPAN, and 3KAZUSA DNA Research Institute, JAPAN
M25FMICROFLUIDIC PROTEIN SEPARATION BY FREE FLOW ISOELECTRIC FOCUSINGJ. Wen, J. Albrecht, E.W. Wilker, M.B. Yaffe, and K.F. JensenMassachusetts Institute of Technology, USA
M26FQUANTITATIVE EVALUATION OF DYNAMIC COATING ON PLASTIC MICROCHIPSFOR PREVENTING PROTEIN ADSORPTIONM.R. Mohamadi1, T. Yasui2, N. Kaji2, M. Tokeshi2, and Y. Baba2
1Institut Curie , FRANCE and 2Nagoya University, JAPAN
M27FSPINTRONIC DEVICE FOR CELL/MAGNETIC PARTICLE SORTING AND COUNTINGJ. Loureiro1,2, R. Ferreira1,2, S. Cardoso1,2, J. Germano1,3, D. Snakenborg4,J.M.S. Cabral2,5, and P.P. Freitas1,2
1Universidade Técnica de Lisboa, PORTUGAL,2Instituto Superior Técnico (IST), PORTUGAL, 3INESC-Investigação e Desenvolvimento, PORTUGAL,4Technical University of Denmark, DENMARK, and5IBB- Institute for Biotechnology and Bioengineering, PORTUGAL
ApplicationsSeparation Science
M28F4D IMAGING OF INTRACELLULAR RESPONSE TO LOCALIZED STIMULUS ONTISSUE-MIMICKING MICRODEVICEK. Terao1, A. Okonogi1, T. Okitsu2, T. Suzuki3, M. Washizu4, and H. Kotera2
1Kyoto University, JAPAN, 2Kyoto University Hospital, JAPAN, and 3Kagawa University, JAPAN, and3University of Tokyo, JAPAN
M29FA MICRO CELL CHIP INTEGRATED WITH A CAPACITIVE PRESSURE SENSOR ARRAY FOR THESTUDY OF STIMULATION EFFECT ON THE STEM CELL DIFFERENTIATIONW.-Y. Sim, S.-W. Lee1, S.-W. Park1, S.-S. Yang1, S.-H. Park2, and B.-H. Min1
1Ajou University, KOREA and 2Tufts University, USA
M30FA MULTIPLE RECORDING PATCH CLAMP CHIP WITH INTEGRATED SUBTERRANEANMICROFLUIDIC CHANNELS FOR CULTURED NEURONAL NETWORKSC. Py1, G. Mealing1, M. Denhoff1, A. Charrier2, R. Monette1, T. Comas1,T. Ahuja1, D. Martinez1, A. Krantis3, and S. Wingar11National Research Council, CANADA,2Centre National de la Reserche Scientifique (CNRS), FRANCE, and3University of Ottawa, CANADA
M31FA NOVEL VERSATILE BIOMECHANO SENSOR FOR REAL TIME VASCULAR CELL CONTRACTILITYMAPPINGX. Zheng1, H. Surks2, and X. Zhang1
1Boston University, USA and 2Tufts Medical School, USA
ApplicationsCell Handling & Analysis
M32FANALYSIS OF BACTERIAL CHEMOTAXIS USING MICROFLUIDIC CONTACTINGS.-H. Lee1, H.-E. Kim2, C.-S. Lee2, and H. Kang1
1Korea Institute of Industrial Technology (KITECH), KOREA and2Chungnam National University, KOREA
M33FBIOLOGICAL VALIDATION OF HIGH THROUGHPUT MICROCHANNEL CULTUREJ.P. Puccinelli, A.L. Paguirigan , and D.J. BeebeUniversity of Wisconsin, USA
M34FCELL TRAPPING PLATFORM TOWARDS A PATCH-CLAMP MICROCHANNEL ARRAYM. Alberti, D. Snakenborg, and J.P. KutterTechnical University of Denmark (DTU), DENMARK
M35FCONTROL OF 3D COLLAGEN MATRIX POLYMERIZATION FOR HUMAN MAMMARYFIBROBLAST (HMF) CULTUREK.E. Sung1, G. Su1, A. Friedl1,2, and D.J. Beebe1
1University of Wisconsin, USA and 2Department of Veteran Affairs Medical Center, USA
M36FDEVELOPMENT OF MICROFLUDIC CHIP-BASED ALGINATE MICROTUBE FOR ANGIOGENESISS.J. Shin, K.H. Lee, and S.H. LeeKorea University, KOREA
M37FDROPLET-BASED MICROFLUIDIC SYSTEM FOR ENCAPSULATION AND CULTURE OFNEURON CELLS IN MICRO-GEL-PARTICLESS. Long1, D.P. Desai1, K. Kumar1, C.-C. Chen1,2, P. Ingram1, C.E. Schmidt1, and X. Zhang1
1University of Texas, Austin, USA and 2Industrial Technology Research Institute, TAIWAN
M38FAN INTEGRATED MICROFLUIDIC FISH CHIP: ENUMERATING CHROMOSOMES ON ACELL-BY-CELL BASIS IN LESS THAN 1 HOURV.J. Sieben, C.S. Debes-Marun, L.M. Pilarski, and C.J. BackhouseUniversity of Alberta, CANADA
M39FFLEXIBLE AND AUTOMATED MICROFLUIDIC PICOLITER DROPLET SYSTEMFOR SINGLE CELL ANALYSISS.-Q. Gu, W.-B. Du, and Q. FangZhejiang University , CHINA
M40FHIGH FREQUENCY CHEMICAL STIMULATION OF LIVING DICTYOSTELIUM DISCOIDEUM CELLSJ.-C. Galas, S. Dorent, D. Bartolo, and V. StuderEcole Supérieure de Physique et de Chimie Industrielles (ESPCI), FRANCE
M41FHIGH-YIELD PARALLEL ELECTRO-FUSION DEVICE BASED ON FIELD CONSTRICTIONAT AN ORIFICE ARRAYY. Kimura1,2, M. Gel1, B. Techaumnut2, K. Tsuda1, H. Oana1,2, H. Kotera2,4, T. Tada2,4,and M. Washizu1,2
1University of Tokyo, JAPAN, 2Japan Science and Technology Agency (JST), JAPAN,3Chulalongkorn University, THAILAND, and 4Kyoto University, JAPAN
M42FINVESTIGATING THE POROSITY OF TRABECULAR MESHWORK USING MICROFABRICATEDSTRUCTURES FOR GLAUCOMA TREATMENTSS.W. Price, B. Kim, C.J. Roberts, D.M. Grzybowski and Y. ZhaoOhio State University, USA
M43FMICROCHIP ANALYSIS OF CELLULAR RESPIRATORY ACTIVITY ON PDMS MEMBRANEHAVING GAS PERMSELECTIVE PROPERTYT. Shirai1, T. Sakata1, M. Takai1, Y. Miyahara1,2, and K. Ishihara1
1University of Tokyo, JAPAN and 2National Institute for Material Science, JAPAN
M22FSEQUENTIALLY ADDRESSABLE TWO-DIMENSIONAL MICROWELL ARRAY FORHIGH-THROUGHPUT SINGLE CELL-BASED ASSAYY.-J. Kim1, H.-K. Lee2, J. Chung1, I.-J. Cho3, and E.Yoon1,3
1University of Minnesota, USA, 2Seagate Technology, USA, and 3University of Michigan, USA
µTAS 2008 • San Diego 11
MONDAY ProgramSan Diego µTAS 2008
M57FDEVELOPMENT OF A MICRO TOTAL BIOASSAY SYSTEM MIMICKING THE HUMAN BODYFOR ORAL MEDICINESY. Imura, E. Yoshimura, and K. SatoUniversity of Tokyo, JAPAN
M58FMICROFLUIDIC CHIP-BASED IN VIVO-LIKE DRUG PERMEABILITY ASSAY SYSTEMJ.H. Yeon and J.-K. ParkKorea Advanced Institute of Science and Technology (KAIST), KOREA
M59FPOLYMER-BASED DENSE FLUIDIC NETWORKS FOR HIGH THROUGHPUT SCREENING (HTS)WITH ULTRASENSITIVE FLUORESCENCEP.I. Okagbare, J. Gottert, P. Datta, V. Singh, and S.A. SoperLouisiana State University, USA
ApplicationsDrug Discovery
M60FBIOLUMINESCENT WHOLE-CELL BIOSENSOR FOR ON-LINE WATER TOXICITY DETECTIONR. Almog1, R. Daniel1, S. Yagur-kroll2, T. Elad2, S. Melamed2, S. Belkin2, and Y. Shacham-Diamond1
1Tel-Aviv University, ISRAEL and 2Hebrew University of Jerusalem, ISRAEL
M61FMONITORING OF PHOSPHATE LEVELS IN WASTEWATER USING AN AUTONOMOUSMICROFLUIDIC SENSORJ. Cleary1, C. Slater1, D. Kim1, W.S. Yerazunis2, and D. Diamond1
1Dublin City University, IRELAND and 2Mitsubishi Electric Research Laboratories, USA
ApplicationsEnvironmental
M62FAPPLICATION OF A MICROFLUIDIC DROPLET MIXER FOR [18F]FLUORINE LABELINGOF BIOMOLECULES FOR POSITRON EMISSION TOMOGRAPHYS. Olma, K. Liu, Y.-C. Chen, H.R. Tseng, R.M. van Dam, and C.K.F. ShenUniversity of California, Los Angeles, USA
M63FMULTI-STEP PARALLEL PROCESSING ON A CHIP FOR ENZYMATIC REACTIONSJ.Y. Yun1, D. Kim1,2, S. Jambovane1, and J.W. Hong1
1Auburn University, USA and 2Korea Institute of Machinery and Materials (KIMM), KOREA
M64FPREPARATION AND CHARACTERIZATION OF MICROCAPSULES CONTAINING FLUORESCENTNANOPARTICLES SENSITIVE TO ORGANIC SOLVENTM.J. Kim1, J.C. Park1, J.M. Cha1, D.G. Won1, T. Arakawa2, S. Shoji2, and J.S. Go1
1Pusan National University, KOREA and 2Waseda University, JAPAN
ApplicationsChemical Synthesis
M44FMICROFLUIDIC APOPTOSIS CHIP FOR DRUG SCREENING TO IMPROVE ANDPERSONALIZE CANCER THERAPYF. Wolbers1, H.R. Franke2, H. Andersson-Svahn3, I. Vermes2, and A. van den Berg1
1MESA+, University of Twente, THE NETHERLANDS, 2Medisch Spectrum Twente, THE NETHERLANDS, and3Royal Institute of Technology (KTH), SWEDEN
M45FMICROFLUIDIC MAGNETIC CELL SORTING SYSTEM FOR CANCER DIAGNOSISL. Saias1, A.-E. Saliba1, J.-Y. Pierga1, P. Vielh2, F. Farace2, and J.-L. Viovy1
1Institut Curie, FRANCE and 2Institut Gustave Roussy, FRANCE
M46FMICROFLUIDIC TECHNOLOGIES FOR SINGLE CELL GENETIC AND EXPRESSION ANALYSISY. Zeng, P. Kumaresan, N.M. Toriello, E.S. Douglas, C.J. Yang, R.G. Blazej, S.A. Cronier, N. Thaitrong,S.C.H. Hsiao, M.B. Francis, C.R. Bertozzi, and R.A. MathiesUniversity of California, Berkeley, USA
M47FA MICROFLUIDIC-BASED PLATE SYSTEM FOR CELL BASED ASSAYS WITH REDUCED CELL USAGEAND INTEGRATED COMPOUND DILUTIONC. Park1, I. Kazakova1, J. Kim1, J. Farinas1, A. Chow1, and P. Tagari21Caliper Life Sciences, USA and 2Amgen, USA
M48FMICROVALVE-ASSISTED PATTERNING PLATFORM FOR 3D CELL CULTUREAND IN SITU CELL-BASED ASSAYSM.S. Kim and J.-K. ParkKorea Advanced Institute of Science and Technology (KAIST), KOREA
M49FON-CHIP CO2 CONTROL FOR MICROFLUIDIC CELL CULTURES.P. Forry1, A. Tona1, P.C. Thomas1,2, and L.E. Locascio1
1National Institute of Standards and Technology (NIST), USA and 2University of Maryland, USA
M50FORGANIZING COMPLEX MULTICELLULAR CONSTRUCTS USING STENCIL-DELINEATEDELECTROACTIVE PATTERNING (S-DEP)S. Sampattavanich, B.M. Taff, S. Desai, and J. VoldmanMassachusetts Institute of Technology, USA
M51FPATTERNING ADHERENT CELLS WITHIN MICROCHANNELS BY COMBINATION OFELECTROCHEMICAL BIOLITHOGRAPHY AND DIELECTROPHORESISH. Kaji, M. Hashimoto, and M. NishizawaTohoku University, JAPAN
M52FREAL-TIME MONITORING GLUCOSE UTILIZATION IN SINGLE CELL USING A CELLCULTURE CHIP WITH AN EMBEDDED DETECTORZ.T.F. Yu1, N.T. Vu1, K. Kamei1, C.Y.N. Chang1, R.W. Silverman1, R. Farrell2, K.S. Shah2, M.E. Phelps1,C.G. Radu1, A.F. Chatziioannou1, and H.-R. Tseng1
1University of California, Los Angeles, USA and 2Radiation Monitoring Devices Inc., USA
M53FPCR AMPLIFICATION AND GENETIC ANALYSIS IN A MICROWELL CELL CULTIVATION CHIPS. Lindström, M. Hammond, J. Gantelius, A. Ahmadian, and H. Andersson-SvahnRoyal Institute of Technology (KTH), SWEDEN
M54FSTRETCHABLE SUBSTRATES USING PNEUMATIC ACTUATORS FOR MONITORINGMECHANICAL-STRESS-DEPENDENT CELL RESPONSEY.J. Heo, E. Iwase, K. Matsumoto, and I. ShimoyamaUniversity of Tokyo, JAPAN
M55FSURFACE PROTEIN PATTERNING FOR AXON GUIDANCE AND NEURAL MATURATIONP. Björk1,2, S. Khalifa2, T. Schönberg1, B. Kostyszyn2, P. Linderholm1,2, A. Magnusson2,A. Erlandsson2, E. Scarfone2,3, C. Vieider1, and M. Ulfendahl21Acreo AB, SWEDEN, 2Karolinska Institute, SWEDEN, and 3CNRS, FRANCE
M56FTHE VIABILITY ENHANCEMENT OF ENCAPSULATED CELLS IN ALGINATE BEADSUSING HYDRODYNAMIC REMOVAL OF TOXIC OLEIC ACIDC. Kim1,2, K.S. Lee3, E. Kang1, J.H. Kim1, K.J. Lee2, S.H. Kim4, T.S. Kim1, and J.Y. Kang1
1Korea Institute of Science and Technology (KIST), KOREA, 2Korea University, KOREA,3State University of New York, Buffalo, USA, and 4Kyungwon University, KOREA
µTAS 2008 • San Diego12
MONDAY Program µTAS 2008 San Diego
M65FA MICROFLUIDIC PLATFORM FOR FOCAL CHEMICAL STIMULATION OF CELLSG. Mallén-Ornelas, L. Chang, P.Y. Li, T. Hoang, L.J. Ho, K. Swertfager, and E. MengUniversity of Southern California, USA
M66FBRAIN INTERFACE DEVICE FOR LONG-TERM OBSERVATION OF NEURAL CELLSIN VIVO USING 2-PHOTON LASER SCANNING MICROSCOPYH. Takehara, A. Nagaoka, J. Noguchi, T. Akagi, H. Kasai, and T. IchikiUniversity of Tokyo, JAPAN
M67FDESIGN AND PERFORMANCE OF A RAPID, NANOLITER, CONTINUOUS FLOWPOLYMERASE CHAIN REACTOR FOR A HIGH THROUGHPUT MICROSYSTEMP.C. Chen1, D.S. Park1, B.H. You1, N. Kim1, T. Park1, P. Datta1, Y. Desata2, S.A. Soper1,D.E. Nikitopoulos1, and M.C. Murphy1
1Louisiana State University, USA and 2BioFluidica Microtechnologies, USA
M68FLAB-ON-A-CHIP FOR LABEL-FREE MULTIDETECTION OF RESIDUAL ANTIBIOTICS IN MILKY.-H. Jin1, G. Suárez2, S. Berchtold2, J. Auerswald2, J.-M. Diserens3, A Sayah1, Y. Leterrier1,J.-A.E. Månson1, and G. Voirin2
1Ecole Polytechnique Fédérale de Lausanne (EPFL), SWITZERLAND,2Centre Suisse d'Electronique et de Microtechnique, SWITZERLAND, and3Nestlé Research Center, SWITZERLAND
M69FMICROFLUIDIC CO-CULTURE PLATFORM FOR CNS AXON MYELINATIONJ. Park, H. Koito, J. Li, and A. HanTexas A&M University, USA
M70FQUANTITATIVE PHENOTYPING OF C.ELEGANS BEHAVIOR IN AN AUTOMATED MICROSYSTEMG. Cremona, J. Stirman, and H. LuGeorgia Institute of Technology, USA
M71FSPONTANEOUS FORMATION OF POLYMER VESICLES FROM MICRODROPLETSOF POLYION COMPLEX VIA MICROPHASE SEPARATIONH. Oana1, K. Yonehara1,2, A. Kishimura1, Y. Yamasaki1,2, K. Kataoka1,2, and M. Washizu1,2
1University of Tokyo, JAPAN and 2Japan Science and Technology Agency (JST), JAPAN
DNA SEQUENCING BY LIGATION ON SURFACE-BOUND BEADS IN A MICROCHANNELENVIRONMENTC.R. Forest, A.M. Rosenbaum, and G.M. ChurchHarvard University, USA
QUANTITATIVE EVALUATION OF PATTERNED SELF-ASSEMBLED MONOLAYERS BY COLORIMAGING OF ZETA-POTENTIAL OBTAINED FROM TWO-COLOR FLUORESCENCE ANDEVANESCENT WAVE ILLUMINATIONY. Kazoe, S. Miyakawa, N. Miki, and Y. SatoKeio University, JAPAN
16:20 - 16:40
16:40 - 17:00
17:00 - 17:20
Session 1B3Mapping and Imaging
Session 1A3Tools for Nucleic Acid Research and Discovery
MICROFLUIDIC DARWINIAN EVOLUTIONB.M. Paegel and G.F. JoyceScripps Research Institute, USA
THREE-DIMENSIONAL IN SITU TEMPERATURE MEASUREMENT IN MICROFLUIDIC SYSTEMUSING BROWNIAN MOTION OF NANOPARTICLESK. Chung, J. Cho, L. Cheplen, V. Breedveld, and H. LuGeorgia Institute of Technology, USA
INTEGRATED NASBA ARRAY FOR DRUG SCREENING AND EXPRESSION PROFILINGI.K. Dimov1 and L.P. Lee1,2
1Biomedical Diagnostics Institute, IRELAND and 2University of California, Berkeley, USA
NOVEL APPROACH FOR 3D LIVE CELL FLUORESCENCE MICROSCOPYBASED ON MICROFABRICATED MIRRORSH. Hajjoul1, J. Girard1, M. Dilhan1, S. Kocanova2, K. Bystricky2, and A. Bancaud1
1Centre National de la Recherche Scientifique (CNRS)-LAAS, FRANCE and2Centre National de la Reserche Scientifique (CNRS)-LBME, FRANCE
Applications
17:20 Adjourn for the Day
Grand Ballroom A-B Grand Ballroom C
µTAS 2008 • San Diego 13
TUESDAY ProgramSan Diego µTAS 2008
ADVANCES TOWARDS PROGRAMMABLE MATTERM.T. Tolley, M. Krishnan, H. Lipson, and D. EricksonCornell University, USA
STOCHASTIC SENSING USING CHEMICALLY MODIFIED SOLID-STATE NANOPORESA.L.R. Holland, L.D. Menard, and J.M. RamseyUniversity of North Carolina, Chapel Hill, USA
08:55 - 09:15
FABRICATION AND HETEROGENOUS ASSEMBLY OF MICROGEL ARRAY USING RAILEDMICROFLUIDICSW. Park, S. Shin, S.-H. Lee, S.E. Choi, and S. KwonSeoul National University, KOREA
INTEGRATION OF CARBON NANOTUBES IN ELECTROKINETIC SEPARATION DEVICESK.B. Mogensen1, L. Gangloff2, P. Boggild1, K.B.K. Teo2, W.I. Milne2, and J.P. Kutter11Technical University of Denmark (DTU), DENMARK and 2University of Cambridge, UK
09:15 - 09:35
MICROFLUIDICS-BASED LITHOGRAPHY FOR FABRICATING CERAMIC AND CELL-LADENMICROPARTICLESP. Panda1, R.E. Shepherd2, Z. Bao3, S. Ali4, E. Lo4, B.G. Chung4, K.H. Sandhage3, J.A. Lewis2,A. Khademhosseini4, T.A. Hatton1, and P.S. Doyle1
1Massachusetts Institute of Technology, USA, 2University of Illinois, Urbana-Champaign, USA,3Georgia Institute of Technology, USA, and 4Harvard-MIT Division of Health Sciences, USA
POLARIZATION ANISOTROPY OF DNA IN NANOCHANNELSF. Persson1, F. Westerlund2, J.O. Tegenfeldt3, and A. Kristensen1
1Technical University of Denmark (DTU), DENMARK, 2Copenhagen University, DENMARK, and3Lund University, SWEDEN
09:35 - 09:55
FLOW-THROUGH CHIP FOR SEQUENTIAL TREATMENT AND ANALYTE ELUTION FROM BEADS ORCELLSP. Augustsson, T. Laurell, and S. EkströmLund University, SWEDEN
CHANNEL SWITCHING AND CROSS-T INJECTION WITHOUT EXTERNALLY ACTIVATED VALVESD.C. Leslie1, E. Seker1, C.J. Easley2, J.P. Landers1, M. Utz1, and M.R. Begley1
1University of Virginia, USA and 2Vanderbilt University, USA
10:25 - 10:45
MICROFLUIDIC TEMPORAL CELL STIMULATIONN. Andrew1, D. Craig2, J.P. Urbanski1, J. Gunawardena1, and T. Thorsen2
1Harvard University, USA and 2Massachusetts Institute of Technology, USA
MULTIPLEXED PNEUMATIC VALVE CONTROL SYSTEM FOR LARGE SCALE INTEGRATEDMICROFLUIDIC CIRCUIT (LSIMC)K. Kawai1, Y. Shibata1, M. Kanai2, and S. Shoji11Waseda University, JAPAN and 2Shimadzu Corporation, JAPAN
10:45 - 11:05
MICROFLUIDIC CONTROL OF STEM CELL DIFFUSIBLE SIGNALINGK. Blagovic, L.Y. Kim, A.M. Skelley, and J. VoldmanMassachusetts Institute of Technology, USA
A TERNARY MICROFLUIDIC MULTIPLEXER USING DIFFERENT THRESHOLD PRESSURE VALVESD.W. Lee and Y.-H. ChoKorea Advanced Institute of Science and Technology (KAIST), KOREA
11:05 - 11:25
Session 2B1Channels, Tubes and Pores on the Nanoscale
Session 2A1Fluidic Design and Assembly
Session 2B2Fluid Circuits
Session 2A2Microfluidic Cell Signaling and Response
Tuesday, October 14, 2008
08:00 - 08:40 Plenary IIICELLS AND TISSUES ON A DEVICE: SHOWCASING THEIR INTEGRATIVE DYNAMICS IN VITROT. FujiiUniversity of Tokyo, JAPAN
09:55 – 10:25 Break & Exhibit Inspection
Grand Ballroom A-B Grand Ballroom C
Grand Ballroom A-B Grand Ballroom C
µTAS 2008 • San Diego14
Tuesday Program µTAS 2008 San Diego
11:25 – 12:40 Lunch & Exhibit Inspection
12:40 - 13:20 Plenary IVMINIATURIZING THE LABORATORY IN EMULSION DROPLETSA. GriffithsInstitut de Science et d'Ingenierie Supramoleculaires, FRANCE
13:20 - 15:40 Poster Session II
T1AA METHOD FOR SIMULATING DNA ELECTROPHORESIS IN ELECTRICALLY INSULATINGMICROFLUIDIC AND NANOFLUIDIC GEOMETRIESJ. Cho and K.D. DorfmanUniversity of Minnesota, USA
T2AFLUID-PARAMETER-INDEPENDENT MICRO-FLUIDIC DEVICE FOR RELIABLE GENERATION OFMULTI-COMPONENT DROPLETSK. Liu, Y.-C. Chen, H.-R. Tseng, C.K.-F. Shen, and R.M. van DamUniversity of California, Los Angeles, USA
T3AMEASURING METHOD OF ELECTROOSMOTIC FLOW VELOCITY AND ELECTRIC FIELDDISTRIBUTIONS USING MICRO-PIVK. Tatsumi, K. Fukuda, Y. Katsumoto, and K. NakabeKyoto University, JAPAN
T4AMULTIMODE COMPUTATIONAL MODELS OF ISOTACHOPHORETIC SAMPLE CONCENTRATIONCOMBINED WITH BINDING REACTION KINETICSL. Bousse, C. Li, T. Kawabata, and G. WadaWako Pure Chemical Industries, USA
T5ATHERMALLY INDUCED DEFLECTION OF MICROJETS K.M. Vaeth, J. Grace, E. Furlani, and K. NgEastman Kodak Company, USA
T6ATHREE-DIMENSIONAL VISUALIZATION OF MICROSCOPIC FLUIDIC STRUCTURES FORMED INVISCOELASTIC FLUID FLOWH. Kinoshita1, F.-C. Li2, N. Oshima3, M. Oshima1, and T. Fujii11University of Tokyo, JAPAN, 2Harbin Institute of Technology, CHINA, and 3Hokkaido University, JAPAN
T7ACHARACTERIZATION AND FABRICATION OF HIGH-DENSITY, ON-DEMAND, REUSABLE, IN-PLANEPOLYMER INTERCONNECTS TOWARDS STANDARDIZED MICROFLUIDIC PACKAGINGR. Lo and E. MengUniversity of Southern California, USA
T8AMODULAR MICROFLUIDIC SYSTEM WITH A CAST PDMS PUMPING BED AND PLANAR PDMSINTERCONNECTION BLOCKSD. Sabourin, D. Snakenborg, P. Skafte-Pedersen, J.P. Kutter, and M. DufvaTechnical University of Denmark (DTU), DENMARK
T9APROPOSAL OF A NOVEL CONTINUOUS FLOW PUMPING OPERATED BY SURFACE ACOUSTIC WAVEY. Utsumi1, T. Saiki1,2, and K. Okada1
1University of Hyogo, JAPAN and 2Hyogo Prefectural Institute of Technology, JAPAN
T10AAC ELECTROOSMOTIC PUMPING IN 3D C-MEMS STRUCTURESH.A. Rouabah1, B.Y. Park2, R.B. Zaouk2, M.J. Madou2, H. Morgan1, and N.G. Green1
1University of Southampton, UK and 2University of California, Irvine, USA
T11AAC FIELD EFFECT FLOW CONTROL OF EOF IN COMPLEX MICROFLUIDIC SYSTEMSWITH INTEGRATED ELECTRODES E.J. van der Wouden1, S. Pennathur2, and A. van den Berg1
1MESA+, University of Twente, THE NETHERLANDS and 2University of California, Santa Barbara, USA
T12ACHARACTERIZATION OF ADVECTIVE MICRO-SCALE MIXING IN 3D BY MEANS OF ASTEREOSCOPIC PARTICLE IMAGING SYSTEMR. Lindken1, J. van Esch1, B. Wieneke2, and J. Westerweel11Delft University of Technology, THE NETHERLANDS and 2LaVision GmbH, GERMANY
T13ACONTROLLED SEQUENTIAL DROPLET MANIPULATION IN RATCHETED MICRO-CHANNELSTHROUGH AMPLITUDE MODULATED VIBRATIONSZ. Ding and B. ZiaiePurdue University, USA
T14AELECTRICAL EQUIVALENT CIRCUIT MODEL OF MICROFLUIDIC SYSTEM CONTAININGPIEZOELECTRIC VALVELESS MICROPUMP AND VISCOELASTIC PDMS MICROCHANNELA. Nakata, S. Tanaka, K. Sugano, T. Tsuchiya, and O. TabataKyoto University, JAPAN
T15AINTEGRATED LIQUID AND DROPLET DEP FOR LAB ON A CHIP APPLICATIONSD. Chugh and K.V.I.S. KalerUniversity of Calgary, CANADA
T16AMICROPARTICLE-ASSISTED CONTINUOUS 2-DIMENSIONAL GRADIENTS OF THERAPEUTICAGENTS IN MICROCHANNEL FOR DRUG TESTSM. Estes and C.H. AhnUniversity of Cincinnati, USA
T17APASSIVE FLOW-RATE REGULATORS USING PRESSURE-DEPENDENT AUTONOMOUS DEFLECTIONOF PARALLEL MEMBRANE VALVESI. Doh and Y.-H. ChoKorea Advanced Institute of Science and Technology (KAIST), KOREA
T18AREAL-TIME MONITORING OF BINDING ASSAYS ON MICROFLUIDIC DEVICES WITH CONTACTLESSCONDUCTIVITY DETECTIONW.K.T. Coltro1, J.A. Fracassi da Silva2, and E. Carrilho1
1Universidade de São Paulo, BRAZIL and 2Universidade Estadual de Campinas, BRAZIL
MicrofluidicsFluid Mechanics & Modeling
MicrofluidicsAliquoting, Mixing & Pumping
MicrofluidicsWorld-to-Chip Interfacing
µTAS 2008 • San Diego 15
Tuesday ProgramSan Diego µTAS 2008
T19ASUB-NANOLITER PER MINUTE FLOW RATES WITH CUSTOM MICROSYRINGE PUMPS IN AMICROFLUIDIC CHIP: THE IMPORTANCE OF TEMPERATURE CONTROLJ.T. Nevill, D.M. Hartmann, D. Wyrick, G. Votaw, C. Buckner, and H.C. CrenshawGlaxoSmithKline, USA
T20AUNIDIRECTIONAL SHAKE-MODE FOR MIXING HIGHLY WETTING FLUIDS ON CENTRIFUGALPLATFORMSS. Lutz1, V. Reitenbach1, D. Mark1, J. Ducree1, R. Zengerle1,2, and F. von Stetten1,2
1Institute for Micromachining and Information Technology (HSG-IMIT), GERMANY and 2University ofFreiburg, GERMANY
T21AMULTIPLE GENE ANALYSIS WITHIN A SIMPLE DROPLET-IN-OIL MICROFLUIDIC PCR PLATFORMY. Zhang, V. Bailey, C.M. Puleo, C. Chen, and T.H. WangJohns Hopkins University, USA
T22AAC ELECTROKINETIC PHASE SEPARATION, FOCUSING AND CONCENTRATION IN MICROCHANNELN. Sasaki, K. Hosokawa, and M. MaedaRIKEN, JAPAN
T23AAUTOMATED CONTINUOUS FLOW PLATFORM FOR DNA DETECTION BY HYPERBRANCHEDROLLING CIRCLE AMPLIFICATION IN DROPLETSG. Colas, S. Begolo, M. Chabert, and J.-L. ViovyInstitut Curie , FRANCE
T24ACONTROLLABLE GENERATION AND TRANSFORMATION OF HIGHLY UNIFORM NONSPHERICALDROPLETS IN MICROCHANNEL ARRAY DEVICESI. Kobayashi1, K. Uemura1, and M. Nakajima1,2
1National Food Research Institute, JAPAN and 2University of Tsukuba, JAPAN
T25ADIGITAL MICROFLUIDICS FOR SCREENING ASSAYSA.R. Wheeler, E.M. Miller, I. Barbulovic-Nad, and V.N. LukUniversity of Toronto, CANADA
T26AEFFECTIVE DILUTION OF PROTEIN FOR SINGLE MOLECULE ASSAY IN AN INTEGRATED ASSAYDEVICET. Nakayama1, K. Tabata2, H. Noji2, and R. Yokokawa1,3
1Ritsumeikan University, JAPAN, 2Osaka University, JAPAN, and3Japan Science and Technology Agency (JST), JAPAN
T27AFORMATION OF POLYMER VESICLES UTILIZING PDMS DOUBLE EMULSIFICATION DEVICESC.-Y. Liao and Y.-C. SuNational Tsing Hua University, TAIWAN
T28AIMPROVING THE OPERATION OF ELECTROWETTING-BASED DIGITAL MICROFLUIDIC SYSTEMS BYUSING WATER-OIL CORE-SHELL DROPLETS D. Brassard1,2, L. Malic1,3, F. Normandin1, M. Tabrizian3, and T. Veres1,2
1National Research Council, CANADA, 2Laval University, CANADA, and 3McGill University, CANADA
T29ALOCALLY DEFINED THERMALLY REVERSIBLE HYDROGEL FORMATION IN MICROCHANNELSJ. Flueckiger and K. CheungUniversity of British Columbia, CANADA
T30AMICROFLUIDIC INVESTIGATION OF MASS TRANSPORT ENHANCEMENT IN NANOPARTICLESUSPENSIONSS. Ozturk, Y.A. Hassan, and V.M. UgazTexas A&M University, USA
T31ANOVEL METHOD FOR ANALYSING PHASE DIAGRAMS USING PERVAPORATIONA. Moumen1, J. Leng2, M. Joanicot2, and P. Tabeling1
1Ecole Supérieure de Physique et de Chimie Indutriells (ESPCI), FRANCE and 2Lab of the Future,FRANCE
T32APREPARATION OF WATER-IN-OIL-IN-WATER EMULSION WITH ULTRA-THIN OIL PHASE LAYERUSING HYDROPHOBIC MICROCHANNEL WITH STEP STRUCTURED. Saeki1,2, S. Sugiura1, T. Baba1, T. Kanamori1, S. Sato2, and S. Ichikawa2
1National Institute of Advanced Industrial Science and Technology (AIST), JAPAN and2University of Tsukuba, JAPAN
T33ASELECTIVE EXTRACTION OF RECOMBINANT PROTEINS BY MULTIPLE-AFFINITY TWO-PHASEPARTITIONING IN MICROCHANNELSR.J. Meagher, Y.K. Light, and A.K. SinghSandia National Laboratories, USA
T34ATHE EFFECT OF INTERFACIAL FORCES ON 2-PHASE MICROFLUIDICSL. Shui, J.C.T. Eijkel, D. Wijnperlé, and A. van den BergUniversity of Twente, THE NETHERLANDS
T35AA FULLY AUTOMATED MICRO-SOLID PHASE EXTRACTION CHIP USING MONOLITHIC HIGHPRESSURE MICROVALVESS.-I. Han, H. Lee, and K.-H. HanInje University, KOREA
T36ACONTINUOUS, HIGH THROUGHPUT MAGNETIC SEPARATION OF PATHOGENS FROM BLOODJ. Fiering1, C.W. Yung2, A.J. Mueller1, M. Varghese1, K.M. Isaac3, and D.E. Ingber21Charles Stark Draper Laboratory, USA, 2Harvard Medical School & Children's Hospital, USA, and3Missouri University of Science and Technology, USA
T37AGRADIENT ELUTION MICROCHIP ELECTROCHROMATOGRAPHY USING A MONOLITH STATIONARYPHASEA.G. Chambers and J.M. RamseyUniversity of North Carolina, Chapel Hill, USA
T38AIMPROVED BACTERIAL AND VIRAL RECOVERIES FROM COMPLEX SAMPLES USINGELECTROPHORETICALLY ASSISTED ACOUSTIC FOCUSINGK.D. Ness, K.A. Rose, B. Jung, K. Fisher, and R.P. Mariella Jr.Lawrence Livermore National Laboratory, USA
T39AMICROFLUIDIC DEVICE FOR BLOOD PLASMA EXTRACTION USING DIELECTROPHORETIC BLOODCELL REMOVALY. Nakashima and T. YasudaKyushu Institute of Technology, JAPAN
T40AON-CHIP CREATION AND ELIMINATION OF MICROBUBBLES BY ELECTROLYSIS AND EWOD FORMICRO-OBJECT MANIPULATORS.K. Chung and S.K. ChoUniversity of Pittsburgh, USA
T41AA DIFFUSION-DEFINED PHOTOPOLYMERIZATION PROCESS FOR POLYACRYLAMIDE GRADIENTGELS FOR ON-CHIP PROTEIN SIZINGC.T. Lo1, D.J. Throckmorton2, A.K. Singh2, and A.E. Herr21Yale University, USA and 2Sandia National Laboratories, USA
MicrofluidicsMulti-Phase Microfluidics
MicrofluidicsSeparation Methods
µTAS 2008 • San Diego16
Tuesday Program µTAS 2008 San Diego
T42APRESSURE-PINCHED INJECTION IN PDMS MICROCHIPS CONTAINING IN SITU PREPAREDMONOLITHIC PHASES A. Filipowicz-Szymnaska1,2, T. Rosenling2, R. Bischoff2, Z. Brzózka1, and E. Verpoorte2
1Warsaw University of Technology, POLAND and 2University of Groningen, THE NETHERLANDS
T43ARAPID SEPARATION AND CAPTURE OF PLATELETS FROM WHOLE BLOODL. Basabe-Desmonts1, S. Ramstrom2, G. Meade2, S. O'Neill2, A. Riaz1, L. Kent1, D. Kenny2,L.P. Lee1,3, and A.J. Ricco1
1Dublin City University, IRELAND, 2Royal College of Surgeons in Ireland (RCSI), IRELAND, and3University of California, Berkeley, USA
T44ASIZE-BASED PARTICLE SORTING BY CALIPER WALLS IN A WIDE MICROFLUIDIC CHANNELK. Mogi, T. Yamamoto, H. Kinoshita, and T. FujiiUniversity of Tokyo, JAPAN
T45ASWEEPING FLOW ELECTROPHORESIS (SFE): A NEW CONTINUOUS SEPARATION TECHNIQUEP. Vulto1, D. Kohlheyer2, G.A. Urban1, and R.B.M. Schasfoort21University of Freiburg (IMTEK), GERMANY and 2MESA+, University of Twente, THE NETHERLANDS
T46AA MONOLITHIC PASSIVE CHECK-VALVE FOR SYSTEMATIC CONTROL OF TEMPORAL ACTUATIONIN MICROFLUIDIC DEVICESB. Mosadegh, C.-H. Kuo, Y.-C. Tung, Y.-S. Torisawa, and S. TakayamaUniversity of Michigan, USA
T47ADETECTION OF DNA HYBRIDIZATION ON A CONFIGURABLE DIGITAL MICROFLUIDIC BIOCHIPUSING SPR IMAGINGL. Malic1, T. Veres2, and M. Tabrizian1
1McGill University, CANADA and 2National Research Council, CANADA
T48AENGINEERING 3D ECM MICROARCHITECTURES FOR CELL CO-CULTURE STUDIESC.P. Huang, H. Seon, J. Lu, A. Putnam, and N.L. JeonUniversity of California, Irvine, USA
T49AMOVING MASK LITHOGRAPHY FOR REAL-TIME SYNTHESIS OF PHOTOPOLYMERIZEDMICROSTRUCTURES IN MICROFLUIDIC CHANNELSH. Park1, K. Yu2, H. Kim1, N. Park1, and S. Kwon1
1Seoul National University, KOREA and 2University of California, Berkeley, USA
T50AON-DEMAND FLUID CONTROL ON MICROCHIP BY MICRO-PATTERNED LIGHT IRRADIATION USINGPHOTO-RESPONSIVE HYDROGELSS. Sugiura1, A. Szilágyi1,2, K. Sumaru1, T. Takagi1, M. Zrínyi2, and T. Kanamori11National Institute of Advanced Industrial Science and Technology (AIST), JAPAN and2Budapest University of Technology and Economics, HUNGARY
T51ATHE GENERATION OF STATIONARY CHEMICAL GRADIENTS AROUND STAGNANT POINTS USING AMICROFLUIDIC PROBEM.A. Qasaimeh, P. Sanyal, R. Safavieh, C.M. Perrault, A. Queval, and D. JunckerMcGill University, CANADA
T52ATUNABLE LIQUID GRADIENT REFRACTIVE INDEX (L-GRIN) LENSX. Mao, S.-C.S. Lin, J. Shi, M.I. Lapsley, and T.J. HuangPennsylvania State University, USA
T1BANALYSIS OF SINGLE DNA MOLECULES TRANSLOCATING THROUGH NANOCHANNELSFABRICATED IN SiO2L.D. Menard1, S.A. Soper2, K.L. Braun1, C. Huang1, and J.M. Ramsey1
1University of North Carolina, Chapel Hill, USA and 2Louisiana State University, USA
T2BELECTROKINETIC TRAPPING AT SINGLE NANOPORES INTEGRATED IN MICROFLUIDIC DEVICESM.L. Kovarik, K. Zhou, and S.C. JacobsonIndiana University, USA
T3BFABRICATION OF MASSIVELY-PARALLEL REGULAR NANOFILTERS FOR HIGH-THROUGHPUT BIOMOLECULE SEPARATIONP. Mao and J. HanMassachusetts Institute of Technology, USA
T4BLENGTH-BASED SEPARATION OF SHORT DNA USING NANOSLIT ARRAYSE.A. Strychalski, H.W. Lau, L. Archer, and H.G. CraigheadCornell University, USA
T5BRAPID IMMUNOASSAY USING STEADY-STATE DISPERSION EFFECTS IN NANOCHANNELSN.F.Y. Durand, E. Saveriades, A. Valero, and P. RenaudEcole Polytechnique Fédérale de Lausanne (EPFL), SWITZERLAND
Microfluidics
NanotechnologyNanofluidics
T6BISOLATION AND MANIPULATION OF SINGLE MICROTUBULE BY SILICON MICROTWEEZERSM.C. Tarhan1, D. Collard1, C. Bottier1, R. Yokokawa2, M. Hosogi3, G. Hashiguchi3, and H. Fujita1
1University of Tokyo, JAPAN, 2Ritsumeikan University, JAPAN, and 3Shizuoka University, JAPAN
NanotechnologyNanoengineering
T7BDETERMINATION OF PROTEIN CONCENTRATION WITH TWO-DIMENSIONAL (2D) PHOTON BURSTDIAGRAMS USING MICROFLUIDIC CHANNELN. Jing1, C.B. Su1, C.-K. Chou2, M.-C. Hung2, and J. Kameoka1
1Texas A&M University, USA and 2University of Texas, M.D.Anderson Cancer Center, USA
T8BFIELD-EFFECT BASED SILICON NANOWIRE WHOLE-CELL BACTERIAL BIOSENSORS FOR NEUTRALSPECIES DETECTIONI.K. Lao, A. Agarwal, and N. BalasubramanianA*Star (Agency for Science, Technology and Research), SINGAPORE
T9BKINESIN-BASED TRANSPORTATION AND ELECTROFUSION OF LIPID VESICLESC. Bottier1, M.C. Tarhan1, D. Collard1, R. Yokokawa2, and H. Fujita1
1University of Tokyo, JAPAN and 2Ritsumeikan University, JAPAN
T10BMITOCHONDRIAL AND GENOMIC DNA DAMAGE ANALYSIS IN MICROFLUIDIC CHIPSY. Tanaka1, H. Johansson1, C. Larsson1, J. Jarvius1, T. Kitamori2, and M. Nilsson1
1Uppsala University, SWEDEN and 2University of Tokyo, JAPAN
T11BSURFACE-ENHANCED RAMAN SPECTROSCOPY AND CONFOCAL IMAGING OF PERIODICNANOHOLE ARRAYS SURROUNDED BY PLASMONIC BRAGG MIRRORSN.C. Lindquist, H. Im, K.C. Bantz, A. Lesuffleur, C.L. Haynes, and S.-H. OhUniversity of Minnesota, USA
NanotechnologyNanobiotechnology
µTAS 2008 • San Diego 17
Tuesday ProgramSan Diego µTAS 2008
T12BDETERMINISTIC TRANSPLANTING ASSEMBLY OF INDIVIDUAL CARBON NANOTUBES TO MEMSCANTILEVERS FOR BIOSCANNINGS. Kim, H.W. Lee, and S.-G. KimMassachusetts Institute of Technology, USA
T13BRAPID ELECTROKINETIC PATTERNING OF COLLOIDAL PARTICLES WITH OPTICAL LANDSCAPESA. Kumar, S.J. Williams, and S.T. WereleyPurdue University, USA
T14BUNEXPECTEDLY HIGH ENTRAPMENT EFFICIENCIES IN NANOMETER SCALE LIPOSOMES WITHHYDRODYNAMIC FOCUSING USING CONTINUOUS-FLOW MICROFLUIDICSA. Jahn1,2, J.E. Reiner1, W.N. Vreeland1, D.L. DeVoe2, L.E. Locascio1, and M. Gaitan1
1National Institute of Standards and Technology (NIST), USA and 2University of Maryland, USA
T6CMEASURING SURFACE STRESS CURVATURE OF INDUCED, LIPID BILAYERS USINGMICROCANTILEVERSK.W. Liu and S.L. BiswalRice University, USA
MaterialsInterface Characterization
T1DA LABEL-FREE BIOSENSOR BASED ON PROTEIN-FORMED DIFFRACTION GRATING ON OPTICALWAVEGUIDEZ. Lai1, Y. Wang2, N. Allbritton2, G.P. Li1, and M. Bachman1
1University of California, Irvine, USA and 2University of North Carolina, Chapel Hill, USA
T2DA PLATFORM FOR IN SITU SENSING OF BIOMOLECULAR REACTION PRODUCTS USING ACHITOSAN MEDIATED SERS SUBSTRATE FABRICATED IN MICROFLUIDICSS. Buckhout-White, X. Luo, D.L. Berlin, and G.W. RubloffUniversity of Maryland, USA
Detection Technologies Optical
T9CCONTACTLESS CONDUCTIVITY DETECTION IN LTCC TECHNOLOGY FOR MICROCHIPELECTROPHORESISG. Fercher1,2, W. Smetana1, and M.J. Vellekoop1
1Technical University Wien, AUSTRIA and 2Integrated Microsystems Austria GmBh, AUSTRIA
T10CPLASTIC-PDMS HYBRID DEVICES FOR HIGH PRESSURE HYDROLYTICALLY STABLE ACTIVEMICROFLUIDICSK.S. Lee and R.J. RamMassachusetts Institute of Technology, USA
T11CSMART GLASS MANUFACTURING: LOW COST / HIGH VOLUME FABRICATION METHOD FOR GLASSMICROFLUIDIC DEVICESE. Brunet1, G. Duisit1, H. Gascon1, and V. Labrot21Saint-Gobain Recherche, FRANCE and 2Lab of the Future, FRANCE
MaterialsInnovative Chip Materials
NanotechnologyNanoassembly
T1CA VERSATILE METHOD FOR THE SURFACE MODIFICATION OF THE MICROCHANNEL IN POLYMERMICROCHIPSY. Okamoto1, Y.-S. Park1, N. Kaji1, M. Tokeshi1, and Y. Baba1,2
1Nagoya University, JAPAN and2National Institute of Advanced Industrial Science and Technology (AIST), JAPAN
T2CDEVELOPMENT OF SINGLE-STEP HETEROGENEOUS SANDWICH CAPILLARY IMMUNOSENSOR FORCAPILLARY-ASSEMBLED MICROCHIP (CAs-CHIP) INTEGRATIONT.G. Henares, H. Yoshimura, T. Yao, and H. HisamotoOsaka Prefecture University, JAPAN
T3CELECTRIC DISCHARGE METHOD FOR SELECTIVE SURFACE PATTERNING IN THE FABRICATION OFMICROFLUIDIC STRUCTURESN. Suni1, M. Haapala1, A. Mäkinen2, L. Sainiemi3, S. Franssila3, E. Färm1, E. Puukilainen1, M. Ritala1,and R. Kostiainen1
1University of Helsinki, FINLAND, 2University of Oulu, FINLAND, and3Helsinki University of Technology, FINLAND
T4CSELECTIVE CONTROL OF CELL ATTACHMENT IN MICROCHANNEL USING PHOTOCHEMICALREACTIONK.H. Jang, K. Sato, T. Konno, K. Ishihara, and T. KitamoriUniversity of Tokyo, JAPAN
T5CTARGETED PATTERNING OF NUCLEIC ACID PROBES ON OPTICAL NANOSTRUCTURESJ.M. Goddard, S. Mandal, and D. EricksonCornell University, USA
MaterialsSurface Modification
T15BSIMULATION OF NANOCROWN FOR BIOMOLECULAR PLASMONICSS.G. Hong and L.P. LeeUniversity of California, Berkeley, USA
Nanotechnology
T7CAPPLICATION OF MICRON-SPIKED ELECTRODES PRODUCED BY THE PHASE TRANSFORMATIONPHENOMENON OF STAINLESS STEEL FOR GENE TRANSFER DEVICEN. Miyano1, M. Morieda1, Y. Inoue2, Y. Teramura1, F. Tsumori1, H. Iwata1, and H. Kotera1
1Kyoto University, JAPAN and 2University of Tokyo, JAPAN
T8CGENERATION AND SELF-REPLICATION OF MONOLITHIC, DUAL-SCALE POLYMER STRUCTURES BYTWO-STEP CAPILLARY FORCE LITHOGRAPHYH.E. Jeong, R. Kwak, J.K Kim, and K.Y. SuhSeoul National University, KOREA
MaterialsNanostructured Materials
µTAS 2008 • San Diego18
Tuesday Program µTAS 2008 San Diego
T3DA TUNABLE FLUIDIC MICROLENS WITH FLUORESCENCE ENHANCEMENTL.K. Chin, Y.C. Seow, C.S. Lim, and A.Q. LiuNanyang Technological University, SINGAPORE
T4DDEVELOPMENT AND ANALYSIS OF A MICROFLUIDIC PHOTOTHERMAL ABSORBANCE DETECTORUSING POLYELECTROLYTIC GEL ELECTRODESH. Chun, P.J. Dennis, E.R. Ferguson, J.P. Alarie, J.W. Jorgenson, and J.M. RamseyUniversity of North Carolina, Chapel Hill, USA
T5DPMMA BIOSENSOR FOR NUCLEIC ACIDS WITH INTEGRATED MIXER AND ELECTROCHEMICALDETECTIONS.R. Nugen, P.J. Asiello, J.T. Connelly, and A.J. BaeumnerCornell University, USA
T6DDIGITALLY-MODULATED LIGHT SOURCE UTILIZING A LOW-COST LCD PROJECTOR FOR HIGHTHROUGHPUT CAPILLARY ELECTROPHORESIS DETECTIONS.-W. Lin1, D.-Y. Wu2, L.-M. Fu3, and C.-H. Lin2
1National Cheng Kung University, TAIWAN, 2National Sun Yat-Sen University, TAIWAN, and 3National Pingtung University of Science and Technology, TAIWAN
T7DGENETIC ANALYSIS INSTRUMENT CONSISTING OF A SINGLE MICROELECTRONIC CHIPM. Behnam, G. Kaigala, M. Khorasani, D. Elliott, and C. BackhouseUniversity of Alberta, CANADA
T8DHUMAN IDENTIFICATION USING ALUs ANALYZED VIA AN INTEGRATED MICROFLUIDIC SYSTEMWITH MULTICOLOR FLUORESCENCE AND MICROCHIP FREE SOLUTION CONJUGATEELECTROPHORESISS.K. Njoroge1, M.A. Witek1, M.L. Hupert1, J. Coyne2, A. Barron2, M.A. Batzer1, and S.A. Soper11Louisiana State University, USA and 2Stanford University, USA
T9DINTEGRATED pH AND OXYGEN SENSOR ARRAY PREPARED BY MICROCONTACT DOUBLEPRINTINGM. Suzuki, A. Nomura, M. Yamamoto, and Y. IribeUniversity of Toyama, JAPAN
T10DA LIQUID-WAVEGUIDE-BASED EVANESCENT WAVE SENSOR FOR HIGH SENSITIVITY REAL TIMEDETECTION AND LABEL FREE BIOSENSING APPLICATIONSX.C. Li1,2, Y.C. Seow2, J. Wu1, K. Xu1, J.T. Lin1, and A.Q. Liu2
1Beijing University of Posts and Telecommunications, CHINA and2Nanyang Technological University, SINGAPORE
T11DNANO-LAMP ARRAYS FOR MULTIPLEX MICROFLUIDIC SPR BIOSENSINGA. Lesuffleur, H. Im, N.C. Lindquist, K.S. Lim, and S.-H. OhUniversity of Minnesota, USA
T12DON-CHIP LOCAL PH MEASUREMENT AROUND INDIVIDUAL CELL USING OPTICALLYMANIPULATED GEL-TOOL WITH ADHESIVE-CONTROLLABILITYH. Maruyama1, F. Arai1, and T. Fukuda2
1Tohoku University, JAPAN and 2Nagoya University, JAPAN
T13DPHOTONIC CRYSTAL SENSOR INTEGRATED IN A MICROFLUIDIC SYSTEMP.S. Nunes, N.A. Mortensen, J.P. Kutter, and K.B. MogensenTechnical University of Denmark, DENMARK
T14DSERS SIGNAL AMPLIFICATIONS VIA BIOFLUIDIC-ADSORPTION PRECONCENTRATION IN CDPLATFORMD. Choi, Y. Choi, T. Kang, H. Cho, and L.P. LeeUniversity of California, Berkeley, USA
T15DDEVELOPMENT OF EMBEDDED METAL LINES IN A PLASTIC ELECTROCHEMICAL MICROFLUIDICDEVICE BY BLANKET MOLD IMPRINTINGJ.-H. Seo1, J.-Y Kim1, H.-W. Lim1, J.-G. Park1, P.L. Leow2, B.A. Patel2, and D. O'Hare2
1Hanyang University, KOREA and 2Imperial College London, UK
T16DIMPEDANCE-SENSING ASSAY FOR REAL-TIME MONITORING ONGOING CARDIOMYOCYTEAPOPTOSISY. Qiu1, R. Liao2, and X. Zhang1
1Boston University, USA and 2Brigham and Women’s Hospital, Harvard Medical School, USA
T17DON-CHIP ELECTRICAL IMPEDANCE TOMOGRAPHY FOR MONITORING THE KINETICS IN THE CELLCULTURET. Sun, S. Tsuda, N.G. Green, K.P. Zauner, and H. MorganUniversity of Southampton, UK
Detection Technologies Electrochemical
T1EBLOW MOLDING OF POLYMER FOILS FOR RAPID PROTOTYPING OF MICROFLUIDIC CARTRIDGESM. Focke1, B. Faltin1, T. Hösel1, C. Müller1, J. Ducrèe2, R. Zengerle1,2, and F. von Stetten1,2
1University of Freiburg (IMTEK), GERMANY and2Institute for Micromachining and Information Technologoy (HSG-IMIT), GERMANY
T2EDIFFRACTION MOIRE: DECOUPLING DISTORTIONS IN PERIODIC POLYMERIC POST ARRAYS FORBIOLOGICAL APPLICATIONSX. Zheng and X. ZhangBoston University, USA
T3EFABRICATION OF PDMS MICROLENSES WITH VARIOUS CURVATURES USING A WATER-BASEDMOLDING METHODH.-K. Kim and K.-S. YunSogang University, KOREA
MEMS & NEMS Technologies Micro & Nano-Machining
T18DA MICROFLUIDIC CHIP BASED ELECTROSPRAY INTERFACE FOR MASS SPECTROMETRY WITH ALOW-TEMPERATURE ALLOY MICROELECTRODEY. Zhu, J. Pan, Y. Su, and Q. FangZhejiang University, CHINA
T19DLABEL-FREE ELECTRICAL DETECTION OF PSA BY A NANOGAP FIELD EFFECT TRANSISTORJ.-H. Ahn, M. Im, and Y.-K. ChoiKorea Advanced Institute of Science and Technology (KAIST), KOREA
T20DMEASUREMENT OF PROTEIN CONCENTRATION USING THE BINDING FORCE BETWEEN TWOSURFACESK. Kuwana, K. Matsumoto, and I. ShimoyamaUniversity of Tokyo, JAPAN
T21DON-CHIP IMPEDANCE SPECTROSCOPY OF pH-RESPONSIVE POLYELECTROLYTE MICROCAPSULESC. Bernabini1, D. Holmes1, M. Bedard2, G.B. Sukhorukov2, and H. Morgan1
1University of Southampton, UK and 2Queen Mary University of London, UK
Detection Technologies
µTAS 2008 • San Diego 19
Tuesday ProgramSan Diego µTAS 2008
T4EMICROVALVE-ADDRESSABLE PICOLITER CHAMBERS FOR SINGLE-MOLECULE ENZYMOLOGYD. Cate, N. Li, and A. FolchUniversity of Washington, USA
T5EQUICK AND EASY FABRICATION OF MICROFLUIDIC CHANNELS WITH WATER-SOLUBLE MOLDSR. Gojo1, Y. Morimoto1, and S. Takeuchi1,2
1University of Tokyo, JAPAN and 2Japan Science and Technology Agency (JST), JAPAN
T17EEXCHANGEABLE, PRE-LOADED “SKIN DEPOT” FOR DIGITAL MICROFLUIDICSH. Yang, V.N. Luk, M. Abdelgawad, I. Barbulovic-Nad, and A.R. WheelerUniversity of Toronto, CANADA
T18EMINIMIZING PARASITIC REACTIONS FOR ENZYME-CONTROLLED METABOLIC PATHWAYSINVESTIGATED IN BIOMEMSX. Luo, D.L. Berlin, S. Buckhout-White, W.E. Bentley, G.F. Payne, R. Ghodssi, and G.W. RubloffUniversity of Maryland, USA
T19ESELF-SEALED VERTICAL NANOPOROUS JUNCTIONS FOR INTEGRATING VARIOUSNANOMATERIALS IN PDMS MICROFLUIDIC SYSTEMS.J. Kim and J. HanMassachusetts Institute of Technology, USA
T16EWORM-ON-CHIP TECHNOLOGY FOR STUDYING AGING OF THE NERVOUS SYSTEM IN c. elegansA. Tripathi, T.V. Chokshi, and N. ChronisUniversity of Michigan, USA
MEMS & NEMS TechnologiesHybrid Devices, Packaging & Components Interfacing
T6EA PDMS PINCH VALVE WITH ZERO DEAD VOLUME AS A VALVING MODULE FOR RIGID POLYMERLAB CHIPS A.W. Browne and C.H. AhnUniversity of Cincinnati, USA
T7EBUBBLE INCLUSION AND REMOVAL USING PDMS MEMBRANE-BASED GAS PERMEATION FORAPPLICATIONS IN PUMPING AND MIXING IN MICROFLUIDIC DEVICESM. Johnson, G. Liddiard, M. Eddings, and B. GaleUniversity of Utah, USA
T8EDEVELOPMENT OF A NOVEL PNEUMATIC DISPENSER USING AN INTEGRATED BACKFLOWSTOPPERS. Lee and J. KimPohang University of Science and Technology (POSTECH), KOREA
T9EPILLAR ARRAY MICRO-TRAPS WITH NEGATIVE DIELECTROPHORESIS H.H. Cui1, J. Voldman1,2, and K.M. Lim1,2
1National University of Singapore, SINGAPORE and 2Massachusetts Institute of Technology, USA
T10EFORMATION OF MONODISPERSE MICROSIZED-EMULSIONS USING AN AXISYMMETRIC FLOW-FOCUSING DEVICE FABRICATED BY PHOTOLITHOGRAPHY AND STEREOLITHOGRAPHYY. Morimoto, K. Kuribayashi, and S. TakeuchiUniversity of Tokyo, JAPAN
T11EMICROFLUIDIC ASSEMBLY BLOCKSM. Rhee and M.A. BurnsUniversity of Michigan, USA
T12EMICROPORE FORMATION USING OVERLAPPED ETCH FRONTS IN INTEGRATED DEVICES FORCELLULAR ANALYSIST.D. Perroud, M. Wu, R.F. Renzi, A.K. Singh, and K.D. PatelSandia National Laboratories, USA
T13EPASSIVE MICROFLUIDIC SORTING OF PARTICLES USING DIFFERENTIAL MIGRATION A.A.S Bhagat, S.S Kuntaegowdanahalli, and I. PapautskyUniversity of Cincinnati, USA
T14EPRINTING OF TEMPERATURE-SENSITIVE HYDROGELS FOR COMPACT MICROFLUIDIC VALVESN.E. Reticker-Flynn, H.W. Lee, and S.-G. KimMassachusetts Institute of Technology, USA
T15ESILICON-BASED MHZ ULTRASONIC NOZZLES C.S. Tsai1, Y.L. Song1,2, C.H. Cheng3, N. Wang1, R.W. Mao1, C.T. Lee2, and S.C. Tsai41University of California, Irvine, USA, 2National Cheng-Kung University, TAIWAN,3National Taiwan Universtiy, TAIWAN, and 4California State University, Long Beach, USA
MEMS & NEMS TechnologiesMicrofluidic Components
T20EANALYSIS OF POLYMER DEGRADATION UNDER HIGH SHEARS IN MICROFLUIDIC CHIPSP. Nghe, P. Tabeling, A. Ajdari, and P. MaryEcole Supérieure de Physique et de Chimie Industrielles (ESPCI), FRANCE
T21EDEVELOPMENT OF A MICROFLUIDIC PLATFORM AND DETECTION SYSTEM FOR PLATELETFUNCTION ANALYSISN.J. Kent1, G. Meade1,2, L. Basabe-Desmonts1, B. Lincoln1, D. Kenny1,3, A.J. Ricco1, B.D. MacCraith1,and B.G. Corcoran2
1Dublin City University, IRELAND and 2Royal College of Surgeons in Ireland, IRELAND
T22EINTEGRATED MICROFLUIDIC SAMPLE PRECONCENTRATOR AND IMPEDANCE DETECTIONPLATFORM FOR PATHOGEN MONITORING P. Sabounchi1, A.M Morales1, B.A. Simmons1, and R.V. Davalos2
1Sandia National Laboratories, USA and 2Virginia Tech-Wake Forest University, USA
T23EMICRO Q-PCR CHIP ON A MINIATURIZED DETECTION SYSTEM FOR DNA DETECTION ANDQUANTIFICATIONJ.-H. Wang1, L.-J. Chien1, T.-M. Hsieh1, C.-H. Luo1, P.-H. Chen2, P.-J. Chen2, D.-S. Lee3,and G.-B. Lee1,4
1National Cheng Kung University, TAIWAN, 2Taiwan University, TAIWAN,3Taipei University of Technology, TAIWAN, and4Industrial Technology Research Institute, TAIWAN
T24EMULTIPURPOSE MICROCHIP SYSTEM FOR PHOTOMETRIC CHEMICAL ANALYSIS INTEGRATEDWITH TEMPERATURE CONTROLLED SOLUTION MIXERT. Noda1, N. Hirokubo1, Y.S. Shin1, K. Miyamura2, K. Matsumoto2, H. Takao1,3, K. Sawada1,3,and M. Ishida1,3
1Toyohashi University of Technology, JAPAN, 2HORIBA, Ltd., JAPAN, and3Japan Science and Technology Agency (JST), JAPAN
T25ETOTAL INTEGRATED IMMUNE ASSAY SYSTEM EMPLOYING SIMPLE AND ACCURATE CHECKVALVE-PUMP FLOW CONTROL WITH NON-LABEL HIGH SENSITIVE ELECTROCHEMICALDETECTION FOR CLINICAL DIAGNOSISY. Takamura1, S. Torai1, M. Chikae1, Y. Tsujita2, K. Maehashi2, K. Matsumoto2, and E. Tamiya2
1Japan Advanced Institute Science Technology (JAIST), JAPAN and 2Osaka University, JAPAN
MEMS & NEMS TechnologiesIntegration "Sample to Result" Systems
µTAS 2008 • San Diego20
Tuesday Program µTAS 2008 San Diego
T12FAUTOMATED CHIP-BASED EXTRACTION OF HPV mRNA FROM CERVICAL SAMPLEST. Baier1, T. Hansen-Hagge1, R. Gransee1, A. Crombé1, S. Schmahl1, K.S. Drese1, P. Grønn2, L. Solli2,I.M. Falang2, C. Martin3, H. Keegan3, and L. Furuberg4
1Institut für Mikrotechnik Mainz GmbH, GERMANY, 2Norchip AS, NORWAY, 3Coombe Womens HospitalDublin, IRELAND, and 4SINTEF Microsystems and Nanotechnology, NORWAY
T13FDENGUE RNA EXTRACTION IN A FULLY-ENCLOSED SELF-CONTAINED LAB-ON-A-CHIP (LOC)CARTRIDGEL. Yobas1, S. Rafeah1, Z. Li1, S.-E. Yong1, K.-Z. Ong1, K. Lau2, V.T.K. Chow2, and C.-K. Heng2
1Institute of Microelectronics, SINGAPORE and 2National University of Singapore, SINGAPORE
T14FINTEGRATED MICROFLUIDIC CYTOMETER FOR THE DIRECT ANALYSIS OF LEUKOCYTES IN WHOLEBLOODJ.K. Herr1, J.P. Alarie1, J. Soohoo2, G.M. Walker1,2, N. Sharpless1, and J.M. Ramsey1,2
1University of North Carolina, Chapel Hill, USA and 2North Carolina State University, USA
T15FMECHANICAL AND THERMAL MODELING OF A PARYLENE ELECTROTHERMAL VALVE FORMAPPING BRAIN FUNCTION IN FREELY MOVING SUBJECTSP.-Y. Li, T.K. Givrad, D.P. Holschneider, J.-M.I. Maarek, and E. MengUniversity of Southern California, USA
T16FMICROFLUIDIC IMAGING CYTOMETRY (MIC) TECHNOLOGY FOR IN VITRO MOLECULARDIAGNOSTICSJ. Sun, M. Ohashi, K.I. Kamei, H. Wang, M. Masterman-Smith, Z.T.-F. Yu, H.I. Kornblum, P.S. Mischel,and H.-R. TsengUniversity of California, Los Angeles, USA
T17FRAPID AND EASY-TO-USE MULTIPLEX IMMUNOASSAY DEVICEM. Ikami1, M. Tokeshi1,2, Y. Okamoto1,2, N. Kaji1,2, and Y. Baba1,2,3
1Nagoya University, JAPAN,2National Institute of Advanced Industrial Science and Technology (AIST), JAPAN, and3Institute for Molecualr Science, JAPAN
T18FRAPID, MULTI-STEP BIOASSAYS ON THE SURFACE OF MOBILE MAGNETIC PARTICLES INCONTINUOUS FLOWS.A. Peyman, A. Iles, and N. PammeUniversity of Hull, UK
T10FA HIGH-THROUGHPUT MICROFLUIDIC PLATFORM FOR IN VITRO TOXICITY ASSAYSG.A. Cooksey, J.T. Elliott, and A.L. PlantNational Institute of Standards and Technology (NIST), USA
T11FAN ENZYMATIC MICROREACTOR FOR CONTINUOUS GLUCOSE MONITORINGB.-U. Moon, A.J.M. Schoonen, B.H.C. Westerink, and E. VerpoorteUniversity of Groningen, THE NETHERLANDS
ApplicationsClinical Diagnostics
T1FPHYSICAL TRAPPING AND ELECTRIC LYSIS OF BACTERIAL CELLS IN A MICROFLUIDIC DEVICEN. Bao and C. LuPurdue University, USA
T2FCHEMICAL-MEDIATED MELTING CURVE ANALYSIS FOR GENOTYPING OF SINGLE NUCLEOTIDEPOLYMORPHISMSA. Russom, D. Irimia, W. White, and M. TonerMassachusetts General Hospital, Harvard Medical School and Shriners Hospital for Children, USA
T3FDNA EXTRACTION, USING CARRIER RNA, INTEGRATED WITH AGAROSE GEL-BASED POLYMERASECHAIN REACTION IN A MICRO FLUIDIC DEVICEK.J. Shaw, J. Oakley, P.T. Docker, C.E. Dyer, J. Greenman, G.M. Greenway, and S.J. HaswellUniversity of Hull, UK
T4FINTEGRATION OF PROTEIN PROCESSING STEPS ON A DIGITAL MICROFLUIDICS PLATFORM FORANALYSIS BY MALDI-MSD. Chatterjee, A.J. Ytterberg, S.U. Son, J.A. Loo, and R.L. GarrellUniversity of California, Los Angeles, USA
T5FMICROFLUIDIC DEVICE FOR DNA ENRICHMENT AND THE APPLICATION OF “CHROMATINIMMUNOPRECIPITATION”H.J. Oh1, S.E. Park1, B.Y. Lee1, J.S. Park1, H.M. Jung1, T.J. Yoon1, and S.H. Lee2
1Seoulin Bioscience Institute, KOREA and 2Korea University, KOREA
T6FMINIATURIZED SYSTEM FOR REAL-TIME PCR IN LOW-COST DISPOSABLE LTCC CHIP WITHINTEGRATED OPTICAL WAVEGUIDER.W. Walczak1,2, P.B. Bembnowicz1, P.S. Szczepanska1, J.A. Dziuban1,2, L. Golonka1, J. Koszur2,and D.D. Bong3
1Wroclaw University of Technology, POLAND, 2Institute of Electron Technology, POLAND, and3Technical University of Denmark (DTU), DENMARK
T7FON-CHIP DEVICE FOR ISOTHERMAL, CHEMICAL CYCLING POLYMERASE CHAIN REACTIONA. Persat and J.G. SantiagoStanford University, USA
T8FPROCESSING PROTEINS IN SERUM BY DIGITAL MICROFLUIDICS M.J. Jebrail, V.N. Luk, and A.R. WheelerUniversity of Toronto, CANADA
T9FSELEX-ON-A-CHIP: MICROFLUIDIC CHIP INTEGRATION OF THE SOL-GEL DERIVED AFFINITYCOLUMN FOR MONITORING RNA-PROTEIN INTERACTIONS.-M. Park1, J. Ahn1,2, M. Jo2, S. Kim2, J.T. Lis1, and H.G. Craighead1
1Cornell University, USA and 2Dongguk University, KOREA
ApplicationsGenomics & Proteomics
T19FA FULLY-INTEGRATED CMOS MICROSENSOR ARRAY FOR IMAGING THE HYDROGEN ION ACTIVITYOF LIVING CELLSM.J. Milgrew, M.O. Riehle, and D.R.S. CummingUniversity of Glasgow, UK
T20FELECTROFORMATION OF GIANT LIPOSOMES FROM DENSELY MICRO-PATTERNED LIPID FILMSK. Kuribayashi1, A. Utada1, and S. Takeuchi1,2
1University of Tokyo, JAPAN and 2Japan Science and Technology Agency (JST), JAPAN
T21FIMAGING OF PHYSIOLOGICAL CELLULAR STIMULATION-RESPONSE PHENOMENA ONTISSUE-REPRODUCING CELL ARRAY DEVICEA. Okonogi1, K. Terao1, T. Okitsu1,2, T. Suzuki1,3, and H. Kotera1,4
1Japan Science and Technolory Agency (JST), 2Kyoto University Hospital, JAPAN,3Kagawa University, JAPAN, and 4Kyoto University, JAPAN
T22FMULTICHANNEL NANOPORE BIOSENSORS FOR HIGH THROUGHPUT SINGLE MOLECULEDETECTIONT. Osaki1,2, H. Suzuki1, B. Le Pioufle2, and S. Takeuchi31University of Tokyo, JAPAN, 2Centre National de la Research Scientifique (CNRS), FRANCE, and3Japan Science and Technology (JST), JAPAN
ApplicationsMicroarrays
µTAS 2008 • San Diego 21
Tuesday ProgramSan Diego µTAS 2008
T33FATTACHMENT AND DETACHMENT OF PROSTATE CANCER CELLS IN A MICROFLUIDIC SYSTEML.S.L. Cheung, X.J. Zheng, A. Stopa, J. Schroeder, R.L. Hemark, J.C. Baygents, R. Guzman,and Y. ZoharUniversity of Arizona, USA
T34FBLOOD CELL ANALYSIS USING PORTABLE FLOW CYTOMETER WITH MICROFLUIDIC CHIPS ASCARTRIDGES. Zheng1, H.L. Kasdan2, A. Fridge2, and Y.-C. Tai11California Institute of Technology, USA and 2Iris Diagnostics, USA
T35FCELLULAR MICROTISSUES SPONTANEOUSLY FORMED IN A MICROFABRICATED DEVICE FORANGIOGENESISS. Le Gac1, N. Rivron2, D. Wijnperlé1, C. van Blitterswijk2, and A. van den Berg1
1Universiteit Twente, THE NETHERLANDS and 2BMTI, THE NETHERLANDS
T36FDEVELOPMENT OF A MICROFLUIDIC ON-LINE CULTURE SYSTEM FOR COMBINEDELECTROCHEMICAL AND OPTICAL REAL-TIME DETECTION OF CELLULAR PROCESSESA. Heiskanen1,2, C. Spégel1, J. Tønnesen1, Z. Fohlerova1, L. Goulart2,J. Hansen3, M. Kokaia1, T. Ruzgas4, M. Dufva2, and J. Emnéus2
1Lund University, SWEDEN, 2Technical University of Denmark (DTU), DENMARK,3Aquaporin A/S, DENMARK, and 4Malmö University, SWEDEN
T37FDISCRETE STIMULATION OF SINGLE PROTOPLAST CELLS BY HIGHLY RESOLVED DRUG RELEASEN. Wangler, O. Brett, M. Laufer, M. Straßer, A. Dovzhenko, K. Voigt, K. Palme, M. Daub, R. Zengerle, andJ. SteigertUniversity of Freiburg, GERMANY
T38FDYNAMIC FLOW CYTOMETRY IN AN ACOUSTO-OPTIC MICROFLUIDIC CHIPJ. Svennebring, O. Manneberg, H. Hertz, and M. WiklundRoyal Institute of Technology (KTH), SWEDEN
T39FENUMERATING VIABLE CIRCULATING TUMOR CELLS FOR CANCER DIAGNOSTICSS.J. Tan1,2, L. Yobas2, G.Y.H Lee3, C.N. Ong1, and C.T. Lim1,3
1National University of Singapore, SINGAPORE, 2Institute of Microelectronics, SINGAPORE, and3Singapore MIT-Alliance, SINGAPORE
T40FFORMATION OF SIMPLE THREE-DIMENSIONAL BIOLOGICAL BARRIERS BASED ON MICROFLUIDICDEVICEJ.-B. Shao, Q.-H. Jin, and J.-L. ZhaoShanghai Institute of Microsystem and Information Technology, CHINA
T41FHIGH PERFORMANCE PARALLEL BIOPARTICLE SORTER WITH 3-DIMENSIONAL PDMS CHIPH. Sugino1, Y. Nara2, Y. Shirasaki3, T. Arakawa1,2, S. Shoji2, and T. Funatsu1
1University of Tokyo, JAPAN, 2Waseda University, JAPAN, and 3Kazusa DNA Research Institute, JAPAN
T42FHIGH-THROUGHPUT CELL AND PARTICLE CHARACTERIZATION USING ISO-DIELECTRICSEPARATIONM.D. Vahey and J. VoldmanMassachusetts Institute of Technology, USA
T43FNANOFIBER MATRIX BASED MICROCHIP FOR HUMAN MESENCHYMAL STEM CELL CULTUREK.H. Lee1, S.J. Shin1, Y. Park1, D.K. Han2, J.J. Park1, and S.H Lee1
1Korea University, KOREA and 2Korea Institute of Science & Technology, KOREA
T44FINTEGRATED MICROFLUIDIC SYSTEMS BIOLOGY PLATFORM: CELL CULTURE, DRUG TREATMENT,LYSIS, SEPARATION AND DETECTIONA. Riaz1, I.K. Dimov1, L. Kent1, C.R. Poulsen1, S. O’Toole2, M. Radomski3, J. O’Leary2, A.J. Ricco1,and L.P. Lee1,4
1Dublin City University, IRELAND, 2St. James Hospital, IRELAND, 3Trinity College Dublin, IRELAND, and4University of California, Berkeley, CA, USA
T23FTHREE-DIMENSIONAL (3D) HOLLOW POLYMERIC MICROSTRUCTURES FOR SHEAR-PROTECTINGCELL CONTAINERS WITHIN MICROFLUIDIC CHANNELS.H. Lee, H.S. Cho, C.I. Park, and K.Y. SuhSeoul National University, KOREA
T24FEXTERNAL FORCE RESPONSIBLE NANOGELS FOR MICROCHIP ELECTROPHORESIS OF DNAK. Kondo1, N. Kaji1, S. Toita2, K. Akiyoshi2, M. Tokeshi1, and Y. Baba1,2,3
1Nagoya University, JAPAN, 2Tokyo Medical and Dental University, JAPAN, and 3National Institute ofAdvanced Industrial Science and Technology (AIST), JAPAN
T25FHYBRID CERAMIC-POLYMER MICROFLUIDIC CHIPS FOR BIOMOLECULE SEPARATIONST. Sikanen1, S. Aura2, L. Heikkilä1, S. Franssila2, T. Kotiaho1, and R. Kostiainen1
1University of Helsinki, FINLAND and 2Helsinki University of Technology, FINLAND
T26FONE-STEP PREPARATION OF AMINO-PEG MODIFIED PMMA MICROCHIPS FORELECTROPHORETIC SEPARATION OF BIOGENIC COMPOUNDSF. Kitagawa, K. Kubota, and K. OtsukaKyoto University, JAPAN
T27FRAPID SEPARATION OF PROTEIN DIGESTS ON SU-8 BASED CAPILLARY ELECTROPHORESIS-ELECTROSPRAY IONIZATION MASS SPECTROMETRY MICROCHIPSN. Brenner1, T. Sikanen1, S. Aura2, S. Tuomikoski2, K. Vuorensola1, T. Kotiaho1,2, S. Franssila2,and R. Kostiainen1
1University of Helsinki, FINLAND and 2Helsinki University of Technology, FINLAND
T28FSYSTEMS ANALYSIS FOR POLYMER MATRIX TECHNOLOGY TRANSFER FROM CAPILLARIES TOMICROFLUIDIC CHIPSD.G. Hert1, C.P. Fredlake1, and A.E. Barron2
1Northwestern University, USA and 2Stanford University, USA
ApplicationsSeparation Science
T29FA MICROFLUIDIC PLATFORM FOR INVESTIGATING THE IMPAIRMENT OF MITOCHONDRIALTRANSPORTH.J. Kim1, J.W. Park2, J. Harris1, B. Vahidi1, and N.L. Jeon1
1University of California, Irvine, USA and 2Gwangju Institute of Science and Technology (GIST), KOREA
T30FA NEW DISCRIMINATION METHOD BASED ON BULGE GENERATION BETWEEN CANCEROUS ANDNORMAL CELLSY.C. Kim1,2, S.-J. Park2, and J.-K. Park1
1Korea Advanced Institute of Science and Technology (KAIST), KOREA and2KIMM, KOREA
T31FA VISUAL MICROFLUIDIC DNA DETECTORD.M. Finkler1, C.W. Price1, L.A. Legendre1, G.R.M. Duarte2, J.P. LeDuc1, and J.P. Landers1
1University of Virginia, USA and 2Institute of Chemistry of São Carlos, BRAZIL
T32FIMPROVED ACOUSTIC DIFFERENTIAL EXTRACTION ON A MICRODEVICE FOR SEPARATION OFSPERM CELLS AND EPITHELIAL CELL LYSATEJ.V. Norris1, M. Evander2, K.M. Horsman1, J. Nilsson2, T. Laurell2, and J.P. Landers1
1University of Virginia, USA and 2Lund University, SWEDEN
ApplicationsCell Handling & Analysis
µTAS 2008 • San Diego22
Tuesday Program µTAS 2008 San Diego
T57FTHE DEVELOPMENT OF A PRECISION, REAL-TIME ON-CHIP CELL MIGRATION ASSAY UTILIZINGSELF ASSEMBLED MONOLAYER MODIFICATION OF MICRO-FABRICATED ELECTRODES ANDCELLULAR IMPEDANCE SENSINGL. Wang, J. Zhu, K. Mitchelson, and J. ChengTsinghua University, CHINA
T58FTOWARDS FAST PLASMA AND BLOOD CELL SEPARATION-PATTERN AND ARRANGEMENTINVESTIGATION OF POST ARRAYS USED IN DETERMINISTIC HYDRODYNAMICSJ. Li, S. Le Gac, and A. van den BergMESA+, University of Twente, THE NETHERLANDS
T59FMICROFLUIDIC DEVICE FOR COMBINATORIAL PROTEIN REFOLDINGS. Kondapalli and B.J. KirbyCornell University, USA
T60FNOVEL INORAGANIC POLYMER DERIVED MICROREACTORS FOR THE APPLICATION OF ORGANICMICROCHEMICAL SYNTHESIST.-H. Yoon1, L.-Y. Hong1, S.-H. Park1, K.-I. Min1, S.-J. Park1, and D.-P. Kim1,2
1Chungnam National University, KOREA and2Korea Advanced Institute of Science and Technology (KAIST), KOREA
T61FTOWARDS IMPROVED IN VITRO SYSTEMS FOR ADME-TOX STUDIES: DEVELOPMENT OF ANINTESTINE-LIVER BIOCHIPP.M. van Midwoud, G.M.M. Groothuis, M.T. Merema, and E. VerpoorteUniversity of Groningen, THE NETHERLANDS
T45FLOCAL OXYGEN LEVEL IS DENSITY DEPENDENT IN MICROCHANNEL CULTUREK. Hayashi1,2, E. Berthier1, J. Warrick1, M.J. McShane3, and D.J. Beebe1
1University of Wisconsin, USA, 2NTT Microsystem Integration Laboratories, JAPAN, and3Texas A&M University, USA
T46FMICROFABRICATED SLITS IN SERIES: A SIMPLE PLATFORM TO PROBE DIFFERENCES IN CELLDEFORMABILITYH. Bow1, P. Abgrall1,2, and J. Han1
1Massachusetts Institute of Technology, USA and 2Singapore-MIT Alliance, SINGAPORE/USA
T47FMICROFLUIDIC DEVICE APPLIED TO MULTIPLE FUNCTIONAL ASSAYS FOR ISLETS: NEW METHODFOR PRETRANSPLANT ISLET QUALITY ASSESSMENTJ. Shaikh Mohammed, Y. Wang, T.A. Harvat, J. Oberholzer, and D.T. EddingtonUniversity of Illinois, Chicago, USA
T48FMICROFLUIDIC PATTERNING OF P-SELECTIN FOR CELL SEPARATION THROUGH ROLLINGS. Bose1, S. Hong1, R. Langer1, J.M. Karp2, and R. Karnik1
1Massachusetts Institute of Technology, USA and 2Brigham and Women’s Hospital, USA
T49FMICROPATTERNED CO-CULTURE MODEL OF BACTERIA AND EPITHELIAL CELLS FORINVESTIGATING SIGNAL-MEDIATED HOST-PATHOGEN INTERACTIONSJ.Y. Kim, F. Senocak, M. Hegde, and A. JayaramanTexas A&M University, USA
T50FMICROVORTEX FOCUSING AND SORTING OF PARTICLES IN MICROCHANNELSC.H. Hsu, D. Di Carlo, C. Chen, D. Irimia, and M. TonerMassachusetts General Hospital/Harvard Medical School, USA
T51FON-CHIP DISAGGREGATION OF PRIMARY HUMAN CANCER CELLS FROM SOLID TUMOURBIOPSIES FOR DOWNSTREAM CELLULAR ANALYSIS IN A MICROFLUIDIC DEVICE J. Woods1, S.M. Hattersley1, P.T. Docker1, K. Jiang2, C.E. Dyer1, J. Greenman1, and S.J. Haswell11University of Hull, UK, 2University of Birmingham, UK
T52FPARTITION OF MICROCHANNELS WITH COLLAGEN FOR FABRICATING TUNABLE 3D CELLULARMICROENVIRONMENTS R. Perez-Castillejos1,2, A.P. Wong1, J.C. Love3, and G.M. Whitesides1
1Harvard University, USA, 2New Jersey Institute of Technology, USA, and3Massachusetts Institute of Technology, USA
T53FPCM-PROGRAMMABLE ARBITRARY GRADIENT GENERATOR FOR CELL CHEMOTAXISY. Xie, S. Sarkar, F. Azizi, P.J. Thomas, H. Baskaran, and C.H. MastrangeloCase Western Reserve University, USA
T54FRECEDING MENISCUS INDUCED DOCKING OF YEAST CELLS FOR QUANTITATIVE SINGLE-CELLANALYSISM.C. Park1, J.Y. Hur1, J.-R. Kim2, K.-H. Cho2, K.W. Kwon1, M.K. Kwak1, H.S. Cho1, S.-Y. Hwang1,S.-H. Park1, and K.Y. Suh1
1Seoul National University, KOREA and 2Korea Advanced Institute of Science and Technology, KOREA
T55FSPATIOTEMPORAL ANALYSES OF INNATE IMMUNITY ENABLED BY INTEGRATED MICROFLUIDICSINGLE-CELL PREPARATION, MICROSCOPY AND FLOW CYTOMETRYN. Srivastava, M. Wu, C.S. Branda, J.S. Brennan, A.E. Herr, and A.K SinghSandia National Laboratories, USA
T56FMECHANICAL CONTROL OF STEM CELL DIFFERENTIATION USING MICRO-ENGINEERED MATRIXJ. Fu, Y.-K. Wang, M.T. Yang, T.T. Lee, and C.S. ChenUniversity of Pennsylvania, USA
ApplicationsDrug Discovery
T62FCONTINUOUS ANALYSIS OF ATMOSPHERIC AEROSOLS USING MICROCHIP ELECTROPHORESISS.D. Noblitt1, S.V. Hering2, J.L. Collett1, and C.S. Henry1
1Colorado State University, USA and 2Aerosol Dynamics, Inc., USA
T63FON-SITE HEAVY METAL ANALYZER WITH POLYMER LAB CHIP ARRAY FOR AUTOMATICCONTINUOUS SAMPLING AND MONITORINGZ. Zou, E. MacKnight, A. Jang, P.M. Wu, J. Do, P.L. Bishop, and C.H. AhnUniversity of Cincinnati, USA
ApplicationsEnvironmental
T64FCONTROLLABLE SYNTHESIS OF PEPTIDE POLYMERS IN MICROFLUIDIC REACTORM. Miyazaki1,2, J. Kaneno3, H. Yamaguchi1, T. Honda1, E. Kanaumi3, and H. Maeda1,2
1National Institute of Advanced Industrial Science and Technology (AIST), JAPAN,2Kyushu University, JAPAN, and 3NS Materials Inc., JAPAN
T65FMULTIPHASE PHOTOCATALYTIC REACTIONS IN A MICROREACTION SYSTEMY. Matsushita, Y. Satoh, N. Ohba, N. Usami, T. Suzuki, and T. IchimuraTokyo Institute of Technology, JAPAN
T66FREACTION CALORIMETRY IN MICROREACTORS: FAST REACTION SCREENING AND PROCESSDESIGNJ. Antes, M. Gegenheimer, S. Löbbecke, and H. KrauseFraunhofer Institut für Chemische Technologie, GERMANY
ApplicationsChemical Synthesis
µTAS 2008 • San Diego 23
Tuesday ProgramSan Diego µTAS 2008
T67FA POLYMERIC ELECTROPORATION MICRONEEDLE ARRAY FOR ENHANCED INTRACELLULARDELIVERYS.-O. Choi, Y.-C. Kim, J. Hutcheson, J.W. Lee, M.R. Prausnitz, and M.G. AllenGeorgia Institute of Technology, USA
T68FCARDIOMYOCYTE ACTUATOR FOR MICROFLUIDICS PLATFORM NOZZLES-DIFFUSER PUMPM-D.T. Nguyen, G. Giridharan, and P. SethuUniversity of Louisville, USA
T69FDEVELOPMENT OF MICROFLUDIC DEVICES INTEGRATING METAL ELECTRODES FOR ON-LINEPRECONCENTRATION AND A PROTON-SENSITIVE ISFET SENSORK. Takemura, F. Kitagawa, and K. OtsukaKyoto University, JAPAN
T70FLABEL-FREE MICROFLUIDIC CHARACTERIZATION OF TEMPERATURE DEPENDENTBIOMOLECULAR BINDING BY MALDI-TOF MASS SPECTROMETRYT.H. Nguyen, R. Pei, M. Stojanovic, and Q. LinColumbia University, USA
T71FON-CHIP ATP AMPLIFICATIONY. Murakami, Y. Shinoda, T. Satoh, K. Noda, and A. KurodaHiroshima University, JAPAN
T72FRECHARGEABLE 3-D MICROBATTERIES FABRICATED WITH AN EXOTHERMIC NANOPOROUSCASTING PROCESSH. Berry, C. Whitney, and C.G. WilsonLouisiana Tech University, USA
Applications
A “MICROFLUIDIC NOSE”: LARGE-AREA MICROARRAYS OF OLFACTORY SENSORY NEURONS FORDETECTING ODORANT RESPONSESX.A. Figueroa1, G.A. Cooksey1, S.V. Votaw1, L. Horowitz2, and A. Folch1
1University of Washington, USA and 2Fred Hutchinson Cancer Research Center, USA
INERTIAL MICROFLUIDICS: HIGH-THROUGHPUT FOCUSING AND SEPARATION OF CELLS ANDPARTICLESD. Di Carlo, D. Irimia, R.G. Tompkins, and M. TonerHarvard University, USA
15:40 - 16:00
Session 2B3Analyzing Blood Components
Session 2A3Extreme Multiplexed Analysis
MULTIPLEXED “DETECTORLESS” ELECTROPHORESISD. Ross and J.G. KraljNational Institute of Standards and Technology (NIST), USA
ON-CHIP NEUTROPHIL CAPTURE AND MIGRATION ANALYSIS FROM A DROP OF BLOODN. Agrawal, M. Toner, and D. IrimiaMassachusetts General Hospital and Harvard Medical School, USA
16:00 - 16:20
CONCURRENT MULTI-SAMPLE ANALYSIS OF LOW EXPRESSED BIOMARKERS ON SINGLE HUMANCELLS BY ENZYMATICALLY AMPLIFIED IMMUNODETECTION IN DROPLETSH.N. Joensson1, M.L. Samuels2, E.R. Brouzes2, M. Medkova2, M. Uhlén1, H. Andersson Svahn1,and D.R. Link2
1Royal Institute of Technology (KTH), SWEDEN and 2RainDance Technologies, USA
MICROFLUIDIC SYNTHESIS OF SQUISHY BIO-MIMETIC PARTICLES WITH TUNABLEDEFORMABILITYR. Haghgooie1, M. Toner1, and P.S. Doyle3
1Harvard University, USA and 2Massachusetts Institute of Technology, USA
16:20 - 16:40
16:40 Adjourn for the Day
18:00 -22:00 Conference Banquet at the San Diego Zoo
Grand Ballroom A-B Grand Ballroom C
µTAS 2008 • San Diego24
Wednesday Program µTAS 2008 San Diego
HIGH THROUGHPUT, MULTI-TARGET MAGNETOPHORETIC SEPARATIONJ.D. Adams, U. Kim, and H.T. SohUniversity of California, Santa Barbara, USA
STUDY ON VAPOR-LIQUID PHASE TRANSITION PHENOMENA IN EXTENDED-NANO SPACEST. Tsukahara1, T. Maeda1, K. Mawatari2, A. Hibara1, and T. Kitamori1,2
1University of Tokyo, JAPAN and 2Kanagawa Academy of Science and Technology , JAPAN
09:15 - 09:35
MICROFLUIDIC DEVICE FOR CONTINUOUS DIELECTROPHORETIC SEPARATION OF CELLS INDIVISIONN. Demierre, T. Braschler, A. Valero, and P. RenaudEcole Polytechnique Fédérale de Lausanne (EPFL), SWITZERLAND
PARALLEL SCREENING OF IN SITU CLICK CHEMICAL LIBRARIES IN INTEGRATED MICROFLUIDICDEVICESW.-Y. Lin, Y. Wang, R. Lin, M.E. Phelps, C.K.-F. Shen, K. Faull, and H.-R. TsengUniversity of California, Los Angeles, USA
09:35 - 09:55
MEASURING THE IMPACT OF DIELECTROPHORESIS ON CELL PHYSIOLOGY USING A HIGH-CONTENT SCREENING PLATFORMS.P. Desai and J. VoldmanMassachusetts Institute of Technology, USA
LOCAL SURFACE MODIFICATION USING TRAPPING AND MELTING OF POLYMER MICROPARTICLESFOR DIVERSE PATTERNINGS. Fukushima1, M. Yamada2, M. Yamamoto3, and M. Seki11Chiba University, JAPAN, 2Tokyo Women's Medical University, JAPAN, and3Osaka Prefecture University, JAPAN
09:55 - 10:15
ULTRA-RAPID SAMPLE PRECONCENTRATION UNDER SLANT FIELD USING HIGH-ASPECT-RATIONANOPOROUS MEMBRANESY.-C. Wang, A.K. Singh, and A.V. HatchSandia National Laboratories, USA
MICROFLUIDIC CHIPS WITH “AXON DIODES” FOR DIRECTED AXONAL OUTGROWTH ANDRECONSTRUCTION OF COMPLEX LIVE NEURAL NETWORKSJ.M. Peyrin1, L. Saias2, P. Gougis2, S. Magnifico1, S. Betuing1, D. Kilinc1, J.L. Viovy2, and B. Brugg1
1Université Pierre et Marie Curie, FRANCE and 2Institut Curie, FRANCE
10:45 - 11:05
HIGH-THROUGHPUT SAMPLE PREPARATION FOR MASS SPECTROMETRY BY CONTINUOUS-FLOWPI-BASED FRACTIONATION OF PEPTIDES AND PROTEINSY.-A. Song and J. HanMassachusetts Institute of Technology, USA
“MICROFLUIDIC PALETTE”: GENERATION OF STABLE AND PURELY DIFFUSIVE CHEMICAL GRADI-ENTS INSIDE A MICROFLUIDIC CHAMBERJ. Atencia, J. Morrow, and L.E. LocascioNational Institute of Standards and Technology (NIST), USA
11:05 - 11:25
NOVEL TWO-PHASE FLOW CONTROL CONCEPT AND MULTI-STEP EXTRACTION MICROCHIPA. Hibara1,2,3, K. Kasai1, H. Miyaguchi4, and T. Kitamori1,2,3
1University of Tokyo, JAPAN, 2Kanagawa Academy of Science & Technology, JAPAN,3Japan Science and Technology Agency (JST), JAPAN, and4National Research Institute of Police Science, JAPAN
MICROSCALE CONTROL OF MICROPOST STIFFNESS TO INDUCE CELLULAR DUROTAXISR.D. Sochol, A.T. Higa, R.R.R. Janairo, K.G. Shah, T.D. Johnson, S. Li, and L. LinUniversity of California, Berkeley, USA
11:25 - 11:45
Session 3B1Innovative Chemistries for Microfluidics
Session 3A1Cell Sorting
Session 3B2Tools for Controlled Cell Culture I
Session 3A2Sample Preparation
Wednesday, October 15, 2008
08:00 - 08:20 Announcement of the µTAS 2009 Conference
08:20 - 09:00 Plenary VINTEGRATED ELECTROCHEMICAL CELLULAR DEVICES FOR DETECTION OF GENE EXPRESSIONT. MatsueTohoku University, JAPAN
10:15 – 10:45 Break & Exhibit Inspection
Grand Ballroom A-B Grand Ballroom C
Grand Ballroom A-B Grand Ballroom C
µTAS 2008 • San Diego 25
Wednesday ProgramSan Diego µTAS 2008
11:45 – 13:00 Lunch & Exhibit Inspection
13:00 - 13:40 Plenary VICREATIVITY IN SCIENCE AND TECHNOLOGY: EXAMPLES FROM FLUIDS, LESSONS FROM ARTJ.M. OttinoNorthwestern University, USA
13:40 - 14:00 Art In Science AWARD sponsored by National Institute of Standards and Technology (NIST), USA
14:00 - 16:20 Poster Session III
W1AA PORTABLE IMAGING DEVICE USING A CMOS DETECTOR AND OLED LIGHT SOURCEN. Misawa, T. Yamamura, and S. TakeuchiUniversity of Tokyo, JAPAN
W2AEXPERIMENTAL AND THEORETICAL MEASUREMENTS OF CONCENTRATION DISTRIBUTIONS INACOUSTIC FOCUSING DEVICESK.A. Rose, K. Fisher, B. Jung, K. Ness, and R.P. Mariella, Jr.Lawrence Livermore National Laboratory, USA
W3AIN-SITU MEASUREMENT OF VISCOUS DRAG BY POLYMERIC MICROFLUIDIC FORCEMETERS.A. Lee, J. Kim, and S. KwonSeoul National University, KOREA
W4AMICRO-FLUIDIC MIXING BY ACTIVE CONTROL OF THE FLOW BIFURCATION IN A T-MIXERR. Lindken, J. Hussong, and J. WesterweelDelft University of Technology, THE NETHERLANDS
W5AMICROFLUIDIC OSCILLATORS: FLUIDIC BAND-PASS FILTERS WITH HIGH Q-FACTORSM.R. Begley and M. UtzUniversity of Virginia, USA
W6APRESSURE CHARACTERISTICS MODELLING FOR THE RAPID DESIGN OF CAPILLARYMICROFLUIDIC SYSTEMST. Metz, L. Riegger, C. Ziegler, R. Zengerle, and P. KoltayUniversity of Freiburg (IMTEK), GERMANY
W7ATHREE-DIMENSIONAL HYDRODYNAMIC FOCUSING OVER A WIDE REYNOLDS NUMBER RANGEUSING A TWO-LAYER MICROFLUIDIC DESIGNG.S. Zhuang, T.G. Jensen, and J.P. KutterTechnical University of Denmark, DENMARK
W8AAN ACTIVE, INTEGRATED BUBBLE TRAP AND DEBUBBLER FOR MICROFLUIDIC APPLICATIONSA.M. Skelley and J. VoldmanMassachusetts Institute of Technology, USA
W9AINTEGRATED PIPETTE COMPATIBLE STERILE INTERFACE TO MICROFLUIDIC CHAMBERSH.L.T. Lee, P. Boccazzi, R.J. Ram, and A.J. SinskeyMassachusetts Institute of Technology, USA
W10AA MILLISECONDS MICROFLUIDIC MIXER BASED ON SINGLE BUBBLE STREAMINGD. Ahmed, X. Mao, B.K. Juluri, J. Shi, and T.J. HuangPennsylvania State University, USA
W11AA VALVE-LESS MICRO PUMP WITH PZT DIAPHRAGMV. Thanh Dau, T. Xuan Dinh, R. Sakamoto, O. Tomonori, K. Tanaka, and S. SugiyamaRitsumeikan University, JAPAN
W12AACTIVE SUPERPARAMAGNETIC BEAD MANIPULATION FOR IMMUNOASSAYS ON-CHIPY. Moser, T. Lehnert, E.P. Dupont, R. Afshar, and M.A.M. GijsEcole Polytechnique Fédérale de Lausanne (EPFL), SWITZERLAND
W13ACILIA DEVICE FOR MICROFLUID MANIPULATIONK. Oh1, J.-H. Chung1, S. Devasia1, J.J. Riley1, and K.H. Lee2
1University of Washington, USA and 2NanoFacture, Inc., USA
W14ADISPENSING INDIVIDUAL FLUID PARTICLES ON DEMAND IN A MICROFLUIDIC CHIPJ. Xu and D. AttingerColumbia University, USA
W15AHIGH-PERFORMANCE MICROMIXER FOR FULLY INTEGRATED MICROFLUIDIC SYSTEMSD. Kim1,2, H.S. Rho1, and J.W. Hong1
1Auburn University, USA and 2Korea Institute of Machinery and Materials (KIMM), KOREA
W16ALATERAL CAVITY ACOUSTIC TRANSDUCERA.R. Tovar, R. Madangopal, J. Draper, and A.P. LeeUniversity of California, Irvine, USA
W17ANOVEL MICROMIXER UTILIZING FREQUENCY MODE MODULATION ONMETA-STRUCTUREK. Kanda1, Y. Noda2, T. Suzuki3, I. Kanno3, and H. Kotera3
1Advanced Software Technology and Mechatronics Research Institute of Kyoto, JAPAN,2Arkray Inc., JAPAN, and 3Kyoto University, JAPAN
W18APEN-TYPE 3D PERISTALTIC MICROPUMP FOR PORTABLE APPLICATIONSW. Rhie and T. HiguchiUniversity of Tokyo, JAPAN
W19ASELF-SYNCHRONIZED GENERATION AND CONTROLLED MERGING OF DROPLETSP. Carreras, S. Mohr, P. Fielden, and N. GoddardUniversity of Manchester, UK
W20ATUBELESS MICROFLUIDIC SAMPLING/MIXING DEVICE USING WETTABILITY GRADIENT ANDELECTROWETTINGT. Yasuda and S. HaradaKyushu Institute of Technology, JAPAN
MicrofluidicsFluid Mechanics & Modeling
MicrofluidicsWorld-to-Chip Interfacing
MicrofluidicsAliquoting, Mixing & Pumping
µTAS 2008 • San Diego26
Wednesday Program µTAS 2008 San Diego
W21AUSE OF PHOTOPATTERNED NANOPOROUS POLYMER MONOLITHS AS PASSIVE MIXERS TOENHANCE MIXING EFFICIENCY FOR ON-CHIP LABELING REACTIONSD.A. Mair1, E. Geiger1,2, T. Schwei2,3, T. Dinio2,3, F. Svec2,3, and J. Fréchet2,3
1Fluigence, LLC, USA, 2Lawrence Berkeley National Laboratory, USA, and3University of California, Berkeley, USA
W22AA MICROFLUIDIC DEVICE FOR CONTINUOUS-FLOW LAYER-BY-LAYER ENCAPSULATION OFDROPLETS WITH POLYELECTROLYTESS. Zhang1,2, L. Yobas1, and D. Trau2
1Institute of Microelectronics, SINGAPORE and 2National University of Singapore, SINGAPORE
W23AMICROFLUIDIC EXTRACTION IN DROPLETS AND ITS APPLICATIONS TO BIOLOGY ANDENVIRONMENTAL SCIENCE P. Mary1, V. Studer1, M. Stambouli2, and P. Tabeling1
1Ecole Supérieure de Physique et de Chimie Industrielles (ESPCI), FRANCE and2Ecole Centrale Paris, FRANCE
W24ACHARACTERIZATION OF LAMINAR FLOW-ASSISTED DENDRITIC AMPLIFICATIONK. Hosokawa and M. MaedaRIKEN, JAPAN
W25ADEFORMED DROPLET BREAKUP IN MICROFLUIDIC DEVICE FOR SMALLER PARTICLESGENERATIONT. Moritani1, S. Doi2, and M. Seki11Chiba University, JAPAN and 2Osaka Prefecture University, JAPAN
W26ADIFFERENTIAL INERTIAL FOCUSING IN CURVED HIGH-ASPECT-RATIO CHANNELS FORCONTINUOUS HIGH THROUGHPUT PARTICLE SEPARATIONA. Russom, S. Nagrath, A.K. Gupta, D. DiCarlo, J.F. Edd, and M. TonerHarvard Medical School, USA
W27ADISCRETE AQUEOUS TWO-PHASE MICROEXTRACTION WITH SIMULTANEOUSELECTROHYDRODYNAMIC GENERATION OF A SINGLE DROPLETY.S. Song, Y.H. Choi, G. Park, and D.H. KimKorea Advanced Institute of Science and Technology (KAIST), KOREA
W28AENCAPSULATION OF BIOMOLECULES WITH PROGRAMMABLE CONCENTRATIONS INMICRODROPLETS USING ELECTROKINETIC CONCENTRATORY.-A. Song, A. Sarkar, and J. HanMassachusetts Institute of Technology, USA
W29AGEOMETRICALLY MEDIATED DROPLET MERGING IN MICROCHANNELSX. Niu and J.B. EdelImperial College London, UK
W30ALIPOSOME FORMATION BY COUNTER-CURRENT FLOWS IN MICROCHANNELSM. Shibata1, Y. Okamoto1, N. Kaji1, M. Tokeshi1, and Y. Baba1,2,3
1Nagoya University, JAPAN,2National Institute of Advanced Industrial Science and Technology (AIST), JAPAN, and3Institute for Molecular Science, JAPAN
W31AMICRO-CALORIMETER WITH ENCLOSED PARYLENE CHAMBERS FOR BIO/CHEMICALAPPLICATIONSC.H. Lee1,3, G. Walker2, A. O’Neill2, and D.K. Manikkam1
1California State University, Fresno, USA, 2North Carolina State University, USA, and3Marquette University, USA
W32AMICROFLUIDIC METHOD FOR THE PRODUCTION OF MONODISPERSE ALGINATE MICROBEADSAND IN SITU ENCAPSULATION OF CELLS C.-H. Choi, J.-H. Jung, and C.-S. LeeChungnam National University, KOREA
W33ARAPID FABRICATION OF 3-D BRANCHED MICROVASCULAR FLOW NETWORKSJ.-H. Huang, J. Kim, A. Jayaraman, and V.-M. UgazTexas A&M University, USA
W34ASELF-SYNCHRONIZING DROPLETS WITH DOUBLE STEP-EMULSIFICATION DEVICESV. Chokkalingam1, S. Herminghaus1, and R. Seemann1,2
1Max Planck Institute for Dynamics and Self-Organization, GERMANY and2Saarland University, GERMANY
W35AFAST MICROFLUIDIC PARTICLE FILTERING BY DEAN SPREADINGZ. Wu and K. HjortUppsala University, SWEDEN
W36AA CHANNEL-FREE SEPARATION SYSTEM BASED ON CIRCULAR SHEAR DRIVEN FLOWY. Cai, D. Janasek, J. Franzke, and A. ManzInstitute for Analytical Sciences (ISAS), GERMANY
W37ADIELECTROPHORETIC SEPARATION OF COLLOIDAL PARTICLES USING ANGLED ELECTRODEARRAYN.A. Md Yunus and N.G. GreenUniversity of Southampton, UK
W38AENHANCED MICROFLUIDIC SYSTEMATIC EVOLUTION OF LIGANDS BY EXPONENTIALENRICHMENT (EM-SELEX)J.K. Qian1, X. Lou1, Y. Zhang2, Y. Xiao1, A. Gerdon1, and H.T. Soh1
1University of California, Santa Barbara, USA and 2Cynvenio Biosystems, USA
W39AHIGH-DYNAMIC RANGE PARTICLE SEPARATION VIA INSULATING DIELECTROPHORESISB.G. Hawkins and B.J. KirbyCornell University, USA
W40AINKJET-BASED DNA INJECTOR FOR MICROCHIP ELECTROPHORESISY. Inoue1, N. Kaji1, Y. Okamoto1, M. Tokeshi1, and Y. Baba1,2,3
1Nagoya University, JAPAN,2National Institute of Advanced Industrial Science and Technology (AIST), JAPAN, and3Institute for Molecular Science, JAPAN
W41AMICROFLUIDIC CARTRIDGE FOR (BIO)CHEMICAL FUNCTIONALIZATION OFPT MICROELECTRODES INTEGRATED ON SILICON MICROPROBESO. Frey, B. Guélat, N.F. de Rooij, and M. Koudelka-HepUniversity of Neuchâtel, SWITZERLAND
W42AMICROFLUIDIC SUPERPARAMAGNETIC BEAD-BASED MULTIPLEX DETECTION SYSTEMJ. Nambi Krishnan, T.S. Kim, and S.K. KimKorea Institute of Science and Technology (KIST), KOREA
W43AON-CHIP SEPARATION AND DETECTION OF NON-FLUORESCENT TOXINS IN WATER USINGFLUORESCENT MOBILITY MARKERST. Khurana and J.G. SantiagoStanford University, USA
MicrofluidicsMulti-Phase Microfluidics
MicrofluidicsSeparation Methods
μTAS 2008 • San Diego 27
Wednesday ProgramSan Diego μTAS 2008
W44APYKLINOPHORESIS: A NEW PARTICLE MIGRATION PRINCIPLE DRIVEN BY DENSITY GRADIENTAND APPLICATION TO ANALYSIS OF SOLUTION DENSITY IN A MICROFLUIDIC DEVICEJ.H. Kang, B. Kim, and J.-K. ParkKorea Advanced Institute of Science and Technology (KAIST), KOREA
W45ASEPARATION AND COLLECTION OF MICROPARTICLES USING OSCILLATING BUBBLESK. Ryu, S.K. Chung, and S.K. ChoUniversity of Pittsburgh, USA
W46ASORTING CONCENTRATED SUSPENSIONS: PARTICLE INTERACTIONS, EMERGENT BEHAVIOR, ANDIMPLICATIONS FOR MICROFLUIDIC SEPARATIONSM.D. Vahey and J. VoldmanMassachusetts Institute of Technology, USA
W1BDEVELOPMENT OF PRESSURE-DRIVEN SEPARATION IN EXTENDED-NANO SPACESM. Inaba1, M. Kato1, T. Tsukahara1, K. Mawatari2, A. Hibara1, and T. Kitamori1,2
1University of Tokyo, JAPAN and 2Kanagawa Academy of Science and Technology, JAPAN
W2BEVALUATION OF WATER PROPERTY IN EXTENDED-NANO SPACE USING STREAMING CURRENTMEASUREMENTK. Morikawa1, M. Kato1, T. Tsukahara1, K. Mawatari2, A. Hibara1, and T. Kitamori1,2
1University of Tokyo, JAPAN and 2Kanagawa Academy of Science and Technology, JAPAN
W3BFORMATION OF LIQUID MENISCI IN FLEXIBLE NANOCHANNELSJ.W. van Honschoten, N.R. Tas, V.B. Svetovoy, M. Escalante, and M. ElwenspoekUniversity of Twente, THE NETHERLANDS
W4BMULTIPLE MEASUREMENTS ON THE SAME MOLECULE IN A NANOPORE SYSTEM WITH FEED-BACK CONTROLY.H. Sen and R. KarnikMassachusetts Institute of Technology, USA
W5BSINGLE MOLECULE ANALYSIS OF ELECTRODYNAMICALLY STRETCHED DNA IN NANOCHANNELSS.M. Stavis1,2, C.H. Reccius1,3, J.T. Mannion1, L.P. Walker1, and H.G. Craighead1
1Cornell University, USA, 2National Institute of Standards & Technology (NIST), USA, and 3PhillipsResearch, UK
W47AA NOVEL MICROFLUIDIC DEVICE FOR IMMOBILIZING AND IMAGING DROSOPHILAEMBRYOS H.N. Cartwright1, S.M. Abmayr1,2, and J.W. Schwartz1,3
1Stowers Institute for Medical Research, USA, 2University of Kansas Medical Center, USA, and3University of Kansas, USA
W48ADNA DIFFUSION CONTROLJ. Regtmeier1, R. Eichhorn1, P. Reimann1, A. Ros2, and D. Anselmetti11Bielefeld University, GERMANY and 2Arizona State University, USA
W49AFABRICATION OF PDMS MEMBRANES WITH AQUEOUS MOLDS FOR MICROFLUIDIC SYSTEMSK. Bilotkach and A.P. LeeUniversity of California, Irvine, USA
W50AON-CHIP LIQUID TUNABLE GRATING USING LAMINAR MICROFLUIDIC CONTROL SYSTEMZ.G. Li, L.K. Chin, H.J. Huang, H.N. Unni, and A.Q. LiuNanyang Technological University, SINGAPORE
W51AEXPANSION CHANNELS FOR LOW-PASS FILTERING OF AXIAL CONCENTRATION GRADIENTS INMICROFLUIDIC SYSTEMSD.M. Hartmann, D. Wyrick, J.T. Nevill, G. Votaw, and H.C. CrenshawGlaxoSmithKline, USA
W52ATHROUGHPUT THROUGH THIN-FILM FLUIDICSJ.P. Beech1, T. Mäkelä2, P. Majander2, and J.O. Tegenfeldt11Lund University, SWEDEN and 2VTT, FINLAND
W53AULTRASONIC MICRO-CAGES: A NEW APPROACH FOR MANIPULATION AND MONITORING OFINDIVIDUAL CELLS AND FOR FLUID MIXINGO. Manneberg, J. Svennebring, H.M. Hertz, and M. WiklundRoyal Institute of Technology (KTH), SWEDEN
Microfluidics
NanotechnologyNanofluidics
W6BNOVEL SYNTHESIS OF POLYMERIC NANOPARTICLES FOR DRUG DELIVERY APPLICATIONS USINGMICROFLUIDIC RAPID MIXINGP. Valencia1, P. Basto1, F. Gu1, L. Zhang1, C. Cannizzaro1, R. Langer1, O. Farokhzad2, and R. Karnik1
1Massachusetts Institute of Technology, USA and2Brigham and Women's Hospital, Harvard Medical School, USA
NanotechnologyNanoengineering
W7BMAPPING IN NANOCHANNELSW.W. Reisner1,2, H. Flyvbjerg2, and J. O. Tegenfeldt11Lund University, SWEDEN and 2Technical University of Denmark (DTU), DENMARK
W8BHIGH-THROUGHPUT GENE ANALYSIS USING SUSPENDING DNA FIBERS (SDFs) ON A MICROGLASS-PHONORECORDA. Fuke1, T. Suzuki2, K. Nakama3, H. Kabata4, and H. Kotera1
1Kyoto University, JAPAN, 2Kagawa University, JAPAN, 3Nippon Glass Sheet, JAPAN, and4Sysmex Corporation, JAPAN
W9BMAGNETOPHORETIC POSITION DETECTION FOR MULTIPLEXED IMMUNOASSAYS USING COLOREDMICROSPHERESY.K. Hahn, Z. Jin, J.-B. Chang, H.-S. Kim, and J.-K. ParkKorea Advanced Institute of Science and Technology (KAIST), KOREA
W10BMOLECULAR DELIVERY INTO LIVE CELLS WITH LIGHT IMAGE PATTERNS AND A GOLD PARTICLECOATED SUBSTRATES. Kalim, T.-H. Wu, C. Callahan, E.P.Y. Chiou, and M. TeitellUniversity of California, Los Angeles, USA
NanotechnologyNanobiotechnology
µTAS 2008 • San Diego28
Wednesday Program µTAS 2008 San Diego
W11BUV-MEDIATED LIGAND IMMOBILIZATION FOR MULTIPLEXED ANALYSIS IN EXTENDEDNANOSPACE CHANNELSB. Renberg1, K. Mawatari2, T. Tsukahara1, N. Idota1, K. Sato1, and T. Kitamori11University of Tokyo, JAPAN and 2Kanagawa Academy of Science and Technology, JAPAN
W12BPROTON TRANSPORT THROUGH SELF-ASSEMBLED FUNCTIONALIZED NANOPOROUS SILICONS. Moghaddam, E. Pengwang, R. Masel, and M. ShannonUniversity of Illinois, Urbana-Champaign, USA
W13BSELF ASSEMBLY OF HIGHLY ORDERED NANO-COLLOID ARRAY ON PATTERNED PEG HYDROGELH. Cong, A. Revzin, and T. PanUniversity of California, Davis, USA
NanotechnologyNanoassembly
W14BDEUTERIUM SUBSTITUTION AND SOLVENT EFFECTS ON REACTION DYNAMICS IN EXTENDED-NANO SPACES ON A CHIPT. Tsukahara1, K. Nagaoka1, and T. Kitamori1,2
1University of Tokyo, JAPAN and 2Kanagawa Academy of Science & Technology, JAPAN
Nanotechnology
W1CA SIMPLE AND VERSATILE METHOD FOR SINGLE CELL PATTERNINGA. Azioune1, M. Théry2, M. Bornens1, and M. Piel11Institut Curie, FRANCE, 2Commissariat à l’Energie Atomique (CEA), FRANCE
W2CAC-ELECTROOSMOSIS-ASSISTED LOCALISATION AND ENHANCED BIOCONCENTRATION ONELECTROCHEMICALLY BIOFUNCTIONALIZED MICRODEVICESL. Tanguy1, S. Salomon1, P. Mailley2, and L. Nicu1
1LAAS-CNRS, FRANCE and 2Commissariat à l’Energie Atomique (CEA), FRANCE
W3CDEVELOPMENT OF TUNABLE SUPERHYDROPHOBIC SURFACES BY DUAL-SCALE SURFACEMODIFICATION USING SIMPLE SILICON WET ETCHING AND ZnO NANORODS FORMATIONH. Kim and J. KimPohang University of Science and Technology (POSTECH), KOREA
W4CMICROFLUIDICS-GENERATED IMMOBILIZED BIOMOLECULE GRADIENTS ON HYDROGELSS.A. Kobel, S. Cosson, and M.P. LutolfEcole Polytechnique Fédérale de Lausanne (EPFL), SWITZERLAND
W5CSURFACE MODIFICATION AND PATTERNING OF BIOMOLECULES AND CELLS, USING A POLYMERLIFT-OFF TEMPLATEC.P. Tan, J.M. Moran-Mirabal, D.J. Brooks, B.R. Ilic, C. Fischbach-Teschl, and H.G. CraigheadCornell University, USA
MaterialsSurface Modification
W6CAN INTEGRATED CRACK-OPENING METHOD FOR DETERMINING THE WORK OF FRACTURE OFBONDED POLYMER INTERFACESH. Taylor and D. BoningMassachusetts Institute of Technology, USA
W7CTRANSIENT ELECTROKINETIC PHENOMENA IN HYDROPHOBIC MICROFLUIDIC DEVICESV. Tandon, S.K. Bhagavatula, and B.J. KirbyCornell University, USA
MaterialsInterface Characterization
W1DA DISPOSABLE MICRO-ELECTRO-OPTICAL INTERFACE FOR FLOW MONITORING INBIO-MICROFLUIDICSM. Bucolo1, V.J. Cadarso2, J. Esteve2, L. Fortuna1, A. Llobera2, F. Sapuppo1, and F. Schembri11Università degli Studi di Catania, ITALY and 2Centro Nacional de Microelectrónica, SPAIN
Detection TechnologiesOptical
W11CPDMS BASED NEGATIVE PHOTORESIST FOR MICROFLUIDIC APPLICATIONSS. Suhard1, G. Ardila1, D. Collin2, M.-F. Guimon3, A. Martinez Rivas1, P. Martinoty2, M. Mauzac1,A.-F. Mingotaud1, C. Rossi1, and C. Séverac1
1Université de Toulouse, FRANCE, 2Institut Charles Sadron, FRANCE, and3Ecole Centrale Paris, FRANCE
W12CRAPID PROTOTYPING AND NON-PLANAR PATTERNING USING PHOTODEFINABLE PDMSP. Jothimuthu, A.A.S. Bhagat, and I. PapautskyUniversity of Cincinnati, USA
W13CTHERMOPLASTIC ELASTOMERS (TPE) BLOCK COPOLYMERS, A NEW MATERIAL PLATFORM FORMICROFLUIDICS: PROOF OF CONCEPT FOR COMPLEX SIPHON VALVING ON CDE. Roy1, J. Siegrist2, R. Peytavi3, G.A. Diaz-Quijada1, H. Roberge1, F. Normandin1, G. Jia2, J. Zoval2,M. Madou2, M.G. Bergeron3, M.M. Dumoulin1, and T. Veres1
1National Research Council, CANADA, 2University of California, Irvine, USA, and3Laval University, CANADA
MaterialsInnovative Chip Materials
W8CDROPLET EVAPORATION ON NANOSTRUCTURED SUPERHYDROPHOBIC SURFACESC.-H. Choi1 and C.-J. Kim2
1Stevens Institute of Technology, USA and 2University of California, Los Angeles, USA
W9CMETAL-SEMICONDUCTOR TRANSITION OF ssDNA DECORATED SINGLE-WALLED CARBONNANOTUBESM. Cha, S. Jung, J. Hwang, and J. LeeSeoul National University, KOREA
W10CQUANTITATIVE END-GRAFTING OF DNA ONTO FLAT AND NANOPOROUS GOLD SURFACESL. Huang, E. Seker, M. Utz, M.R. Begley, and J.P. LandersUniversity of Virginia, USA
MaterialsNanostructured Materials
µTAS 2008 • San Diego 29
Wednesday ProgramSan Diego µTAS 2008
W2DA LIQUID WAVEGUIDE BASED TWIN MACH-ZEHNDER INTERFEROMETER FOR REAL TIMEPARTICLE SORTING X.C. Li1,2, Z.G. Li2, H.J. Huang2, J. Wu1, K. Xu1, J.T. Lin1, and A.Q. Liu2
1Beijing University of Posts and Telecommunications, CHINA and2Nanyang Technological University, SINGAPORE
W3DA SIGNIFICANTLY IMPROVED LIMIT OF DETECTION OF AN INTEGRATED FLUORESCENCEDETECTOR FOR MICROFLUIDIC DEVICEST. Kamei, K. Matsuhiro, and A. ShikanaiNational Institute of Advanced Industrial Science and Technology (AIST), JAPAN
W4DAN EFFICIENT SEMICONTINUOUS BEAD TRAPPING METHOD FOR THE APPLICATION OFµ-IMMUNOASSAY PLATFORMSS.K. Yoo, Y.M. Kim, J.H. Lee, and S. YangGwangju Institute of Science and Technology (GIST), KOREA
W5DDEVELOPMENT OF DIFFERENTIAL INTERFERENCE CONTRAST THERMAL LENS MICROSCOPE FORCOUNTING INDIVIDUAL NON-FLUORESCENT MOLECULESH. Shimizu1, K. Mawatari2, and T. Kitamori1,2,3
1University of Tokyo, JAPAN, 2Kanagawa Academy of Science and Technology, JAPAN, and3Japan Science and Technology Agency (JST), JAPAN
W6DHIGH SENSITIVITY PROTEIN DETECTION USING MICRO-MAGNETIC APTAMER PCR (MAP)TECHNOLOGYA.E. Gerdon1, J. Qian1, Y. Zhang2, J.D. Adams1, S.S. Oh1, A. Csordas1, and H.T. Soh1
1University of California, Santa Barbara, USA and 2CytomX, LLC, USA
W7DIN VIVO-LIKE MICROSYSTEM FOR HIGH CONTENTS ANTI-INFLAMMATORY DRUG SCREENINGK. Lee and H. JungYonsei University, KOREA
W8DINEXPENSIVE INTEGRATED CELL IMAGING DEVICEM. Gabriel1, V. Haguet1, N. Picollet-D’hahan1, M. Block2, B. Fouqué1, and F. Chatelain1
1Commissariat à l’Energie Atomique (CEA), FRANCE and 2IAB, FRANCE
W9DINTEGRATION OF EVANESCENT EXCITATION (EE)-BASED CHIP WITH MICROFLUIDIC CHANNELSFOR UPRIGHT AND INVERTED MICROSCOPE OBSERVATIONSN.C.H. Le1, R. Yokokawa1,2, D.V. Dao1, T.D. Nguyen1, J. Wells1, and S. Sugiyama1
1Ritsumeikan University, JAPAN and 2Japan Science and Technology Agency (JST), JAPAN
W10DMEASUREMENT OF THREE-DIMENSIONAL TEMPERATURE DISTRIBUTION IN MICROELECTROPHORESIS USING CONFOCAL TWO-COLOR LASER-INDUCED FLUORESCENCES. Saeki, J. Funakoshi, T. Saito, and K. NakamuraYamaguchi University, JAPAN
W11DNOVEL, COST-EFFECTIVE, HIGH-QUALITY SURFACE PLASMON RESONANCE AND FLUORESCENCEMICROSCOPER. Thariani and P. YagerUniversity of Washington, USA
W12DON-CHIP SANDWICH IMMUNOASSAY IN AN INTEGRATED MAGNETO-OPTICAL CMOSMICROSYSTEME.P. Dupont, U. Lehmann, M. Lombardini, E. Charbon, and M.A.M. GijsEcole Polytechnique Fédérale de Lausanne (EPFL), SWITZERLAND
W13DPHOTOTHERMAL IMAGING OF ABSORBANCE DISTRIBUTION WITH SYNCHRONOUS CCDDETECTION METHODA. Hibara1, K. Oikawa1, and T. Kitamori1,2
1University of Tokyo, JAPAN and 2Kanagawa Academy of Science & Technology, JAPAN
W18DCONTACTLESS DIFFERENTIAL CONDUCTIVITY DETECTIONG.A. Shaw, D. Ross, S.E. Fick, and W.N. VreelandNational Institute of Standards and Technology (NIST), USA
W19DELECTRICAL IMMUNOASSAY USING PROTEIN FUNCTIONALIZED MICROFLUIDIC CHANNELSM. Javanmard, A.H. Talasaz, M. Nemat-Gorgani, F. Pease, M. Ronaghi, and R.W. DavisStanford University, USA
W20DSPLIT RING RESONATOR TECHNIQUE FOR COMPOSITIONAL ANALYSIS OF SOLVENTS INMICROCAPILLARY SYSTEMSA. Masood, O. Castell, D.A. Barrow, C. Allender, and A. PorchCardiff University, UNITED KINGDOM
W21DPOLYSACCHARIDE TEMPLATED SILVER NANOWIRE FOR ULTRASENSITIVE ELECTRICALDETECTION OF NUCLEIC ACIDS ON NANOGAPPED BIOSENSORJ.M. Kong1, A.R. Ferhan2, X.T. Chen1, L. Zhang1, and N. Balasubramanian1
1Institute of Microelectronics, SINGAPORE and 2Nanyang Technological University, SINGAPORE
W22DTHE RELATION BETWEEN BIOMOLECULAR INTERACTION AND RESONANCE BEHAVIOR OFMICROCANTILEVERK.S. Hwang, H.K. Jeon, S.-M. Lee, S.K. Kim, and T.S. KimKorea Institute of Science and Technology (KIST), KOREA
Detection Technologies
W15D2D-SPR DETECTION OF INTERLEUKIN-2 IN SINGLE CELL BASED MICROWELL ARRAYM. Suzuki, S. Hane, and Y. IribeUniversity of Toyama, JAPAN
W16DIN SITU MONITORING OF THE ANTICANCER DRUG EFFLUX FROM DRUG RESISTANT LUNGCANCER CELLSY. Chen1, H. Li2, Y. Wang1, L. Zhang1, R. Julien1, and K. Tang1
1Institute of Microelectronics, SINGAPORE and 2Nanyang Technological University, SINGAPORE
W17DPDMS-BASED MICROFLUIDIC PLATFORM WITH AN ION-SELECTIVE MICROELECTRODE FORQUANTIFYING K+ EFFLUX FROM CELLSC. Miville-Godin, L. MacQueen, S. Bychkov, M.R. Wertheimer, and O.T. GuenatÉcole Polytechnique de Montréal , CANADA
W14DSIMULTANEOUS NATIVE UV FLUORESCENCE AND ABSORBANCE DETECTION FOR MICROCHIPELECTROPHORESIS USING INTEGRATED WAVEGUIDESP.D. Ohlsson, O. Ordeig, K.B. Mogensen, and J.P. KutterTechnical University of Denmark (DTU), DENMARK
Detection TechnologiesElectrochemical
µTAS 2008 • San Diego30
Wednesday Program µTAS 2008 San Diego
W1ECONDUCTIVE AND FLEXIBLE NANOCOMPOSITE PATTERNS EMBEDDED IN ELASTOMER USINGMICROCONTACT PRINTING AND CAST MOLDINGC.-X. Liu and J.-W. ChoiLouisiana State University, USA
W2EFABRICATION OF HOURGLASS-SHAPED MICROAPERTURE VIA TWO-STAGE LASER PULSES ANDITS APPLICATIONC.-Y. Chen, T.-Y. Tu, D.-S. Jong, and A.M. WoNational Taiwan University, TAIWAN
W3EIN-SITU FABRICATION OF THREE-DIMENSIONAL POLYMERIC MICROSTRUCTURES USING SOFTMEMBRANE DEFORMATION AND OPTOFLUIDIC MASKLESS LITHOGRAPHYS.A. Lee, S.E. Chung, and S. KwonSeoul National University, KOREA
W4EMONOLITHIC FABRICATION OF NOVEL MICROFLUIDIC COMPONENTS WITH FIXED ASPECT RATIOROUND MICROFLUIDIC CHANNELS USING NOVEL RAPID MOLDINGA.W. Browne, W. Jung, M.J. Rust, S. Lee, and C.H. AhnUniversity of Cincinnati, USA
MEMS & NEMS TechnologiesMicro & Nano-Machining
W5EA MICROFLUIDIC DEVICE FOR PARTICLE SEPARATION UTILIZING EAVES STRUCTURESH.-W. Wu1, C.-W. Huang1, and G.-B. Lee1,2
1National Cheng Kung University, TAIWAN and 2Industrial Technology Research Institute, TAIWAN
W6EARBITRARY SERIAL DILUTION MICROFLUIDIC NETWORK COMPOSED OF MICROCHANNELS WITHHIGH CROSS-SECTION AREA RATIOK. Hattori, S. Sugiura, and T. KanamoriNational Institute of Advanced Industrial Science and Technology (AIST), JAPAN
W7EDESIGN AND FABRICATION OF A PDMS MICROFLUIDIC CHAMBER FOR MICROFLUIDIC EXPERI-MENTS WITH ORGANOTYPIC BRAIN SLICES A. Queval, C.M. Perrault, M.A. Qasaimeh, R.A. McKinney, and D. JunckerMcGill University, CANADA
W8EDEVELOPMENT OF A VASCULAR SMOOTH MUSCLE CELL-BASED BIO-MICROACTUATORY. Tanaka1, K. Sato1, T. Shimizu2, M. Yamato2, T. Okano2, I. Manabe2, R. Nagai1, and T. Kitamori11University of Tokyo, JAPAN and 2Tokyo Women's Medical University, JAPAN
W9EFABRICATION AND EVALUATION OF TEMPERATURE-TOLERANT BIOACTUATOR DRIVEN BY INSECTHEART CELLSY. Akiyama, K. Iwabuchi, Y. Furukawa, and K. MorishimaTokyo University of Agriculture and Technology, JAPAN
W10ELEIDENFROST LIQUID DROPLETS ON MICRO/NANO RATCHETSJ.T. Ok, E. Lopez-Oña, H. Wong, and S. ParkLouisiana State University, USA
W11EMICROFLUIDIC CHIP OF FAST DNA HYBRIDIZATION USING DENATURE AND MOTION OF NUCLEICACIDSY.-C. Chung1, Y.-C. Lin2, C.-D. Chueh1, C.-Y. Ye1, and L.-W. Lai11Ming Chi University of Technology, TAIWAN and 2National Cheng Kung University, TAIWAN
MEMS & NEMS TechnologiesMicrofluidic Components
W15EA FLEXIBLE PARYLENE NEURAL PROBE COMBINED WITH A MICRODIALYSIS MEMBRANEN. Kotake1, T. Suzuki1, K. Mabuchi1, and S. Takeuchi1,2
1University of Tokyo, JAPAN and 2Japan Science and Technology Agency (JST), JAPAN
W16EMETAL-ORGANIC THIN-FILM ENCAPSULATION FOR GRAVIMETRIC GAS MICROSENSORSJ. Fang, J. Fu, and F. AyaziGeorgia Institute of Technology, USA
W17EOPTOFLUIDIC MANIPULATION AND PACKAGING OF SILICON MICROCHIPS USING RAILEDMICROFLUIDICSS.E. Chung, S.A. Lee, J. Kim, and S. KwonSeoul National University, KOREA
W18ETOWARDS AN INDUSTRIAL FABRICATION PROCESS FOR ELECTROWETTING CHIP USINGSTANDARD MEMS TECHNOLOGYC. Delattre, R. Blanc, G. Castellan, C. Chabrol, N. David, E. Dubard, O. Constantin, Y. Fouillet, D. Jary, A.Rival, and P. CaillatCEA-LETI-MINATEC, FRANCE
MEMS & NEMS TechnologiesHybrid Devices, Packaging & Components Interfacing
W19EAUTOMATED MICROFLUIDIC IMMUNOASSAY (AMI) SYSTEM UTILIZING A POLYMER CHIPEQUIPPED WITH A BLOOD FILTER AND REAGENT STORAGE CHAMBERSK.H. Chung, H.W. Song, Y.H. Choi, and D. LeeElectronics and Telecommunications Research Institute (ETRI), KOREA
W20EDEVELOPMENT OF PORTABLE AND RAPID HUMAN DNA ANALYSIS SYSTEM AIMING ON-SITESCREENINGM. Asogawa1, M. Sugisawa1, K. Aoki1, H. Hagiwara2, and Y. Mishina2
1NEC Corporation, JAPAN and 2Arbiotec Corporation, JAPAN
W21ELAB-ON-GLASS: INTEGRATED ELECTRONIC DISPOSABLES FOR RAPID MOLECULARDIAGNOSTICSM.W.G. Ponjée1, A.A.M. Hoevenaars1, D.A. Fish2, N.N. Kahya1, C.J.M. Lasance1, W.H.M. van Beek1,P. Collins2, and J.M.J. den Toonder11Philips Research Europe, THE NETHERLANDS and 2Philips Research Europe, UK
MEMS & NEMS TechnologiesIntegration "Sample to Result" Systems
W12EON-CHIP ACTUATION OF A THERMALLY SENSITIVE HYDROGEL VALVEE.J. Geiger1,2, D.A. Mair2, A.P. Pisano1, and F. Svec3
1University of California, Berkeley, USA, 2Fluigence, LLC, USA, and3Lawrence Berkeley National Laboratory, USA
W13EPOLYDIMETHYLSILOXANE (PDMS) PERISTALTIC PUMP CHARACTERIZATION FORPROGRAMMABLE LAB-ON-A-CHIP APPLICATIONSH.-S. Chuang1, A.M. Amin1, S.T. Wereley1, M. Thottethodi1, T.N. Vijaykumar1, and S.C. Jacobson2
1Purdue University, USA and 2Indiana University, USA
W14ESIMULATION AND EXPERIMENTAL VERIFICATION OF A QUASI DIGITAL MICROFLOW REGULATORJ. Casals-Terré1, M. Duch2, J.A. Plaza2, J. Esteve2, R. Pérez-Castillejos3, E. Vallés4, and E. Gómez4
1Technical University of Catalonia, SPAIN, 2Centro Nacional de Microelectrònica, SPAIN,3Harvard University, USA, and 4University of Barcelona, SPAIN
µTAS 2008 • San Diego 31
Wednesday ProgramSan Diego µTAS 2008
W22EBEAD BASED TEMPERATURE CONTROLLABLE MICROCHIP FOR CANCER DIAGNOSISM.-S. Kim, T.S. Sim, B.-R. Lee, H.-J. Yoon, B.-G. Kim, Y.-S. Lee, and Y.-K. KimSeoul National University, KOREA
W23ERAPID DETECTION OF METHICILLIN-RESISTANT STAPHYLOCOCCUS AUREUS (MRSA) USINGDIGITAL MICROFLUIDICSZ. Hua, D.J. Allen, P. Thwar, A.E. Eckhardt, V.K. Pamula, and M.G. PollackAdvanced Liquid Logic Inc., USA
W9FSIMPLE METHOD FOR QUANTITATIVE PCR USING FLOW-THROUGH PCR DEVICET. Fukuba1, M. Hiraga2, A. Takamatsu2, C. Provin1, T. Yamamoto1, and T. Fujii11University of Tokyo, JAPAN and 2Waseda University, JAPAN
W18FACCURATE WHOLE GENOME ANALYSIS FROM 150 CELLS SAMPLESD. Irimia1, M. Mindrions2, A. Russom1, W. Xiao2, R.W. Davis2, and M. Toner11Harvard University, USA and 2Stanford University, USA
W24EHIGH-FIDELITY FABRICATION OF MICROFLUIDIC CHANNELS SHAPED FOR ON-CHIP SELF-ACCUMULATION OF MICROTUBULESC.-T. Lin1,2, M.-T. Kao2, K. Kurabayashi2, and E. Meyhöfer21National Taiwan University, TAIWAN and 2University of Michigan, USA
W1FA PARRALLEL FERROFLUID-DRIVEN MICROCHIP FOR HIGH-THROUGHPUT POLYMERASECHAIN REACTIONY. Sun, N.T. Nguyen, and Y.C. KwokNanyang Technological University, SINGAPORE
W2FDEVELOPMENT OF A MICROFLUIDIC DEVICE FOR COMBINED RNA EXTRACTION ANDREAL-TIME, REVERSE TRANSCRIPTION POLYMERASE CHAIN REACTION E.M Hughes, K.J. Shaw, P.T. Docker, C.E. Dyer, J. Greenman, and S.J. HaswellUniversity of Hull, UNITED KINGDOM
W3FIN VITRO SYNTHESIS OF PROTEIN IN THREE PHASE FLOW VIA MERGING OF DROPLETS OF PCRAND TRANSLATIONAL MACHINERYA. Asthana, K.O. Kim, J. Perumal, D.M. Kim, and D.P. KimChungnam National University, KOREA
W4FMICRO TOTAL ANALYSIS ASSEMBLY FOR BACTERIAL TOTAL NUCLEIC ACID ANALYSISI.K. Lao1, C.-K. Yong2, and N. Thepsuparungsikul21A*Star (Agency for Science, Technology and Research), SINGAPORE and 2National University ofSingapore, SINGAPORE
W5FMICROFLUIDIC HUMAN GENETIC PROFILING USING FULLY NON-CONTACT TEMPERATURECONTROLD.C. Leslie, L.A. Legendre, E. Seker, B.C. Strachan, and J.P. LandersUniversity of Virginia, USA
W6FMULTIPLEXED NONCOMPETITIVE AFFINITY ASSAYS FOR PROTEIN QUANTIFICATION USINGTEMPERATURE GRADIENT FOCUSING OF APTAMERS FOLLOWED BY END-POINT PCRM.S. Munson, J.H. McDaniel, D. Ross, M. Salit, and L.E. LocascioNational Institute of Standards and Technology (NIST), USA
W7FON-CHIP INTEGRATION OF SAMPLE PRETREATMENT AND MULTIPLEX POLYMERASE CHAINREACTION (PCR) FOR DNA ANALYSISM. Brivio1, D. Snakenborg1, E. Søgaard1, A. Ahlford2, A.-C. Syvänen2, J.P. Kutter1, and A. Wolff11Technical University of Denmark (DTU), DENMARK and 2Uppsala University Hospital, SWEDEN
W8FPROTEIN EXPRESSION IN ARRAY DEVICES WITH PASSIVE PUMPINGR. Khnouf1, D.J. Beebe2, and Z.H. Fan1
1University of Florida, USA and 2University of Wisconsin, Madison, USA
MEMS & NEMS Technologies
ApplicationsGenomics & Proteomics
W10FA ONE-TOUCH TYPE HAND-OPERATED LOC FOR THE BIOELECTROCATALYTIC IMMUNOASSAYUSING BACKFILLING METHOD S.W. Park, K.-I. Kim, J.H. Lee, H.C. Yoon, and S.S. YangAjou University, KOREA
W11FAN OPTO-FLUIDIC SENSOR FOR MONITORING INTRACRANIAL PRESSURES.B. Kodandaramaiah and N. ChronisUniversity of Michigan, USA
W12FAUTOMATIC MICRO-ELISA SYSTEM AND APPLICATION TO RAPID hsCRP DIAGNOSIST. Ohashi1, K. Mawatari2, and T. Kitamori2,3
1Institute of Micro Chemical Technology, JAPAN, 2Kanagawa Academy of Science and Technology,JAPAN, and 3University of Tokyo, JAPAN
W13FPALM-SIZED REAL-TIME RT-PCR SYSTEMP. Neuzil1, L. Novak2, J. Pipper3, S. Lee4, L.F.P. Ng5, and C. Zhang3
1Institute of Microelectronics, SINGAPORE, 2Czech Technical University, CZECH REPUBLIC,3Institute of Bioengineering and Nanotechnology, SINGAPORE, 4Nanyang Polytechnic, SINGAPORE, and5Genome Institute of Singapore, SINGAPORE
W14FLAB-ON-A-CHIP CARTRIDGE FOR PROCESSING OF IMMUNOASSAYS WITH INTEGRATED SAMPLEPREPARATION S. Lutz1, P. Lang2, I. Malki1, D. Mark1, J. Ducree1, R. Zergerle1,2, and F. von Stetten1,2
1Institute for Micromachining and Information Technology (HSG-IMIT), GERMANY and2University of Freiburg (IMTEK), GERMANY
W15FMICROFLUIDIC CD-BASED SOMATIC CELL COUNTER FOR THE EARLY DETECTION OF BOVINEMASTITISJ.L. Garcia-Cordero1, L. Kent1, I.K. Dimov1, C. Viguier2, L.P. Lee1,3, and A.J. Ricco1
1Dublin City University, IRELAND, 2Enfer Diagnostics, IRELAND, and3University of California, Berkeley, IRELAND
W16FMULTIMODAL PARTICLES FOR BIOLOGICAL DETECTION AND THERAPYK. Hettiarachchi1, P.A. Dayton2, and A.P. Lee1
1University of California, Irvine, USA and 2University of North Carolina, Chapel Hill, USA
W17FRAPID AND QUANTITATIVE DETECTION OF MALARIAL ANTIGEN FOR MICROFLUIDICPOINT-OF-CARE DIAGNOSIS IN THE DEVELOPING WORLDD.Y. Stevens1, C.R. Petri2, J.L. Osborn1, P. Spicar-Mihalic1, K.G. McKenzie1, and P. Yager11University of Washington, USA and 2Boston College, USA
ApplicationsClinical Diagnostics
ApplicationsMicroarrays
µTAS 2008 • San Diego32
Wednesday Program µTAS 2008 San Diego
W19FHIGH PERFORMANCE MICROFLUIDIC DEVICE FOR SEQUENTIAL TRAPPING, LABELING ANDCONTENT EXTRACTION OF SINGLE CELLSY. Murakami1, T. Arakawa1,2, S. Nomura1, Y. Yamaguchi1, and S. Shoji11Waseda University, JAPAN and 2University of Tokyo, JAPAN
W20FINTRACELLULAR POTENTIAL MEASUREMENTS OF ADHERENTLY GROWING CELLS USINGMICRO-NEEDLE ARRAYSC. Tautorat1, P.J. Koester1, J. Held2, J. Gaspar2, P. Ruther2, O. Paul2, A. Cismak3, A. Heilmann3,J. Gimsa1, H. Beikirch1, L. Jonas1, and W. Baumann1
1University of Rostock, GERMANY, 2University of Freiburg (IMTEK), GERMANY, and3Fraunhofer Institute for Mechanics of Materials Halle, GERMANY
W21FONE-TO-ONE GENE-ENCODED FUNCTIONAL PROTEIN MICROARRAYM. Biyani1, T. Osawa1, N. Nemoto2, and T. Ichiki11University of Tokyo, JAPAN and 2Saitama University, JAPAN
W27F3D CELL CULTURE USING MONODISPERSE PEPTIDE HYDROGEL BEADSY. Tsuda1, Y. Morimoto1 and S. Takeuchi1,2
1University of Tokyo, JAPAN and 2Japan Science and Technology Agency (JST), JAPAN
W28FA CARDIOMYOCYTE-BASED BIOSENSOR FOR THE STUDY ON HYPERTROPHY INDUCED BYTUMOR NECROSIS FACTOR ALPLAY. Qiu1, R. Liao2, and X. Zhang1
1Boston University, USA and 2Harvard Medical School, USA
W29FA CONTINUOUS-FLOW CELL CULTURE ARRAY WITH CHAOTIC MIXERS FOR IDENTIFICATION OFTHE OPTIMUM GROWTH FACTORS COMBINATIONS FOR MOUSE EMBRYONIC STEM CELLSDIFFERENTIATION Y.-H. Hsiao, K.-Y. Lee, Y.-T. Lin, I-D. Yang, H.-Y. Chang, C.-C. Chieng, and L.-S. FanNational Tsing Hua University, TAIWAN
W30FA MICROFLUIDIC PLATFORM OPTIMIZING BEAD-BASED ELISA FOR THE DETECTION OF CELLSECRETIONB. Lincoln1, J. Garcia Cordero1, C.R. Poulsen1, and L.P. Lee1,2
1Dublin City University, IRELAND and 2University of California, Berkeley, USA
W31FA NOVEL MICROFLUIDIC DEVICE COMBINING DIELECTROPHORESIS-BASED CELL PATTERNINGAND 3D BIOMATERIALSJ.T. Lu, C.P. Huang, G. Lull, N.L. Jeon, E.S. Monuki, L.A. Flanagan, and A.P. LeeUniversity of California, Irvine, USA
W32FAN INTEGRATED MICROFLUIDIC PLATFORM FOR SYSTEMS-LEVEL INTERROGATION OFSIGNALING PATHWAYS INVOLVED IN INNATE IMMUNITYA.K. Singh, C.S. Branda, S.B. Branda, B. Carson, J. Brennan, C.D. James, J.N. Kaiser, T.W. Lane,R.P. Manginell, A. Martino, M.W. Moorman, J. Poschet, K.D. Patel, T.D. Perroud, R.F. Renzi,N.S. Srivastava, and M. WuSandia National Laboratories, USA
W33FATTACHMENT AND GROWTH BEHAVIOR OF METASTATIC BREAST CANCER CELLS INMEMS-BASED SILICON MICROENVIRONMENTSM. Nikkhah1, J.S. Strobl2, A. Omotosho1, and M. Agah1
1Virginia Polytechnic Institute and State University, USA and2Edward via Virginia College of Osteopathic Medicine, USA
W34FCELL MOTILITY ASSAY USING IMAGE-CONTROLLED OPTOELECTRONIC TRAPW. Choi1, S-W. Nam2, H. Hwang1, S. Park2, and J-K. Park1
1Korea Advanced Institute of Science and Technology (KAIST), KOREA and2Ewha Womans University, KOREA
W35FCONTINUOUS-FLOW CELL TRAPPING AND HYBRIDOMA-CELL PRODUCTION ON CHIP USINGLIQUID ELECTRODESA. Valero, R. Tornay, A. de Pablo, N. Demierre, and P. RenaudEcole Polytechnique Fédérale de Lausanne (EPFL), SWITZERLAND
W36FCONTROLLED ENCAPSULATION OF SINGLE-CELLS INTO MONODISPERSE PICOLITER DROPSJ.F. Edd1, D. Di Carlo1, K.J. Humphry2, S. Köster2, D. Irimia1, D.A. Weitz2, and M. Toner11Massachusetts General Hospital, USA and 2Harvard University, USA
W37FDIFFERENTIAL OPTICAL FLOW FOR AUTOMATED CELL MOTILITYE.G.R. Kim, P. Sivasubramaniam, J.P. Wikswo, and K.T. SealeVanderbilt University, USA
W38FDISPOSABLE MICROFLUIDIC TEMPERATURE CONTROL ON CHIP CELL STUDIES G. Velve Casquillas1, M. Le berre2, C.R. Terrena4, C. Fu4,A.M. Haghiri-Gosnet1, J.J. Greffet3, P.T. Tran4,5, and Y. Chen2
1Centre National de la Recherche Scientifique (CNRS), FRANCE, 2Ecole Normale Supérieure, FRANCE,3Ecole Centrale Paris Scientifique, FRANCE, 4University of Pennsylvania, USA, and5Institut Curie, FRANCE
W39FMICROFLUIDIC ELECTROPORATIVE FLOW CYTOMETRY FOR STUDY OF CELL MECHANICSN. Bao, Y. Zhan, and C. LuPurdue University, USA
W22FAN ON-CHIP WHOLE BLOOD/PLASMA SEPARATOR WITH COLLOIDAL SILICA BEAD-PACKEDMICROCHANNEL ON COC POLYMERJ.S. Shim, A.W. Browne, S.H. Lee, and C.H. AhnUniversity of Cincinnati, USA
W23FHIGH EFFICIENT SPERM MOTILITY SORTING BASED ON ENCOUNTERED CURVE-STRAIGHT MICROSTREAMING FLOWT.-L. Wu1, D.-J. Yao1, F.-G. Tseng1,2, and L.-C. Pan3
1National Tsing Hua University, TAIWAN, 2Academia Sinica, TAIWAN, and3Taipei Medical University, TAIWAN
W24FMICROFABRICATED SEMI-PACKED GAS CHROMATOGRAPHY COLUMN WITH FUNCTIONALIZEDPARYLENE AS THE STATIONARY PHASET. Nakai1, S. Nishiyama1, M. Shuzo1,2, J.-J. Delaunay1,2, and I. Yamada1,2
1University of Tokyo, JAPAN and 2Japan Science and Technology Agency (JST), JAPAN
W25FPRECISE MICROSCALE POLYMER GRADIENTS APPLIED TO ISOELECTRIC FOCUSING AND PORELIMIT ELECTROPHORESISG.J. Sommer, A.K. Singh, and A.V. HatchSandia National Laboratories, USA
W26FSELECTIVE TWO-PHASE MINERAL SEPARATION ON A MICROFLUIDIC CHIPS. Klink1, C. Priest1, J. Ralston1, R. Sedev1, K. Mawatari2, and T. Kitamori2,3
1University of South Australia, AUSTRALIA, 2Kanagawa Academy of Science and Technology, JAPAN,and 3University of Tokyo, JAPAN
ApplicationsSeparation Science
ApplicationsCell Handling & Analysis
µTAS 2008 • San Diego 33
Wednesday ProgramSan Diego µTAS 2008
W40FEXAMINING THE ROLE OF NEUREGULIN-1 IN SYNAPTOGENESIS USING MICROFLUIDICSA. Wu1, S. Koirala2, G. Corfas2, and A. Folch1
1University of Washington, USA and 2Harvard University, USA
W41FGUIDING OF PHOTOSENSITIVE CELLS BY MULTIPLE POINT ORGANIC LEDSH. Nakamura1, N. Misawa1, T. Yamamura1, and S. Takeuchi1,2
1University of Tokyo, JAPAN and 2Japan Science and Technology Agency (JST), JAPAN
W42FINDEPENDENT CONTROL OF OXYGEN CONCENTRATION FOR CELL CULTURE IN AN ADD-ONPLATFORM FOR MULTI-WELL PLATESS.C. Oppegard, K. Nam, and D.T. EddingtonUniversity of Illinois, Chicago, USA
W43FCELLULAR MICROPATTERNS WITH BUILT-IN BIOSENSORS FOR DETECTION OF EXTRACELLULARMETABOLITES J. Yan, J.Y. Lee, S. Shah, and A. RevzinUniversity of California, Davis, USA
W44FLONG-TERM STORAGE OF LIVING CELLS ON CHIP FOR CELL-BASED ASSAYSY. Xu, T. Konno, K. Sato, K. Ishihara, and T. KitamoriUniversity of Tokyo, JAPAN
W45FMICROFLUIDIC ALIGNMENT SYSTEM FOR SINGLE CELL MANIPULATION AND CULTURET. Arakawa1,2, N. Takeda1, Y. Edagawa1, Y. Yamaguchi1, and S. Shoji11Waseda University, JAPAN and 2University of Tokyo, JAPAN
W46FMICROFLUIDIC SYSTEM FOR THE STUDY OF MECHANICAL AND BIOCHEMICAL RESPONSE OFENDOTHELIAL CELLS TO FLOW-INDUCED MECHANICAL STIMULIM. Rossi1, R. Lindken1, B.P. Hierck2, and J. Westerweel1Delft University of Technology, THE NETHERLANDS and2Leiden University Medical Center, THE NETHERLANDS
W47FMICROPATTERNING OF HYDROGEL AND ON-CHIP LONG TIME MONITORING OF INDIVIDUALCELLS IN A CAGEF. Arai, H. Matsumoto, T. Shijuku, and N. UozumiTohoku University, JAPAN
W48FAPOPTOTIC RESPONSE OF OVARIAN CANCER CELLS IN HYPOXIC CONDITIONSC.R. Poulsen1, B. Lincoln1, I. Dimov1, J.L. Garcia-Cordero1, S. O’Toole2,M. Radomski3, J. O’Leary2, and L.P. Lee1,4
1Dublin City University, IRELAND, 2St. James’ Hospital, IRELAND,3Trinity College Dublin, IRELAND and 4University of California, Berkeley, USA
W49FON-CHIP FLOW CYTOMETRY AND SINGLE-CELL IMAGING IN TANDEM: INTEGRATION OF A µFACSWITH A SINGLE-CELL ARRAYK.D. Patel, T.D. Perroud, C.S. Branda, T.W. Lane, and A.K. SinghSandia National Laboratories, USA
W50FPARALLEL MULTI-TIME POINT CELL STIMULUS AND LYSIS IN A MICROFLUIDIC DEVICE USINGCHAOTIC MIXING AND PRESSURE RESISTANCEA. Hirsch, C. Rivet, B. Zhang, M. Kemp, and H. LuGeorgia Institute of Technology, USA
W51FREAL-TIME MEASUREMENT OF CELLULAR REFRACTIVE INDEX AND THICKNESS USING CELLCULTURE CHIPJ.J. Gu1, Y.F. Yu1, E.P. Li2, S.H. Ng3, P.H. Yap3, X.Q. Zhou4, T.H. Cheng1, and A.Q. Liu1
1Nanyang Technological University, SINGAPORE, 2Institute of High Performance Computing, SINGA-PORE, 3DSO National Laboratories, SINGAPORE, and 4Institute for Infocomm Research, SINGAPORE
W52FRECONSTRUCTION OF VASCULAR TISSUE USING A SEPARABLE MICROCHIPT. Yamashita1, N. Idota2, and T. Kitamori1,2
1University of Tokyo, JAPAN and 2Kanagawa Academy of Science & Technology, JAPAN
W53FSMALL MOLECULE GRADIENT GENERATOR FOR MICROFLUIDIC VISCOUS SHEAR-FREE CELLCULTURET. Kim1, M. Pinelis2, and M.M. Maharbiz1
1University of California, Berkeley, USA and 2University of Michigan, USA
W54FSTUDY OF SINGLE CELL KINASE ACTIVITY USING AN AUTOMATED MICROFLUIDIC DEVICEA.D. Hargis, C. Sims, N.L. Allbritton, and J.M. RamseyUniversity of North Carolina, Chapel Hill, USA
W55FTHE MICROFLUIDIC SAME-SINGLE-CELL ANALYSIS (SASCA) FOR MEDICAL DIAGNOSIS OFMULTI-DRUG RESISTANCE AND ITS INHIBITION X. Li, Y. Chen, and P.C.H. LiSimon Fraser University, CANADA
W56FYEAST CELLS DETECTION IN A VERY FAST AND HIGHLY VERSATILE MICROFABRICATEDCYTOMETERR. Rodriguez-Trujillo1,2, O. Castillo-Fernandez1,2, M. Arundell1,2,3, J. Samitier1,3, and G. Gomila1,3
1Institute for Bioengineering of Catalonia (IBEC), SPAIN, 2University of Barcelona, SPAIN, and3Centro de Investigación Biomédica en Red en Bioingenieria, Biomateriales y Nanomedicina(CIBER-BBN), SPAIN
W57FMICROFLUIDIC DEVICE TO CONSTRUCT MULTIFUNCTIONAL ENVELOPE-TYPE NANODEVICE FORGENE THERAPYK. Kitazoe1, N. Kaji1, Y. Okamoto1, M. Tokeshi1, K. Kogure2, H. Harashima3, and Y. Baba1,4
1Nagoya University, JAPAN, 2Kyoto Pharmaceutical University, JAPAN, 3Hokkaido University, JAPAN,and 4National Institute of Advanced Industrial Science and Technology (AIST), JAPAN
W58FMICROFLUIDIC BASED STRIP ASSAY FOR SURFACE BOUND INHIBITORS IN SPINAL CORD INJURYB. Vahidi, J.W. Park, H.J. Kim, and N.L. JeonUniversity of California, Irvine, USA
W59FVLSI MICROFLUIDIC WELL PLATES FOR COMBINATORIAL CHEMISTRYB.R. Schudel, C.J. Choi, B.T. Cunningham, and P.J.A. KenisUniversity of Illinois, Urbana-Champaign, USA
W60FMINIATURIZING THE WHOLE DEVICE: MICRO-TOTAL-ANALYSIS SYSTEM FOR IN-SITUCOLORIMETRIC WATER QUALITY MONITORINGC.R. Koch, J.D. Ingle, and V.T. RemchoOregon State University, USA
ApplicationsDrug Discovery
ApplicationsEnvironmental
W61FA COMBINATORIAL MULTICOMPONENT PLUG MIXER FOR SYSTEMS CHEMISTRYF. Azizi, Q. Wan, T. Radivoyevitch, C. Dealwis, and C.H. MastrangeloCase Western Reserve University, USA
ApplicationsChemical Synthesis
µTAS 2008 • San Diego34
Wednesday Program µTAS 2008 San Diego
W62FAN INTELLIGENT MICROREACTOR SYSTEM FOR REAL-TIME OPTIMIZATION OF A CHEMICALREACTIONJ.P. McMullen and K.F. JensenMassachusetts Institute of Technology, USA
W63FDEVELOPMENT OF A MICROFLUIDIC INSTRUMENT FOR PERFORMING ENZYME KINETICS ASSAYSM. Patel, J.T. Nevill, D.M. Hartmann, D. Tew, S. Thrall, G. Votaw, and H.C. CrenshawGlaxoSmithKline, USA
W64FIN SITU RAMAN SPECTROSCOPY OF SOLID CATALYZED REACTIONS IN SUPERCRITICAL CO2WITHIN A SI/GLASS MICROREACTORF. Trachsel, A. Urakawa, A. Baiker, and P. Rudolf von RohrETH Zurich, SWITZERLAND
W66FCONTINUOUS MEDIUM FLOW BASED PHOTOSYNTHETIC BACTERIA FUEL CELL USINGWATER-ABSORBING POLYMERT. Moriuchi, A. Furuya, K. Morishima, and Y. FurukawaTokyo University of Agriculture and Technology, JAPAN
W67FINSECT FLIGHT CONTROL BY NEURAL STIMULATION OF PUPAE-IMPLANTED FLEXIBLE MULTISITEELECTRODESW.M. Tsang1, Z. Aldworth2, A. Stone3, A. Permar3, R. Levine3, J.G. Hildebrand3, T. Daniel2,A.I. Akinwande1, and J. Voldman1
1Massachusetts Institute of Technology, USA, 2University of Washington, USA, and3University of Arizona, USA
W68FLIPOSOME FORMATION ON A MICRO-PATTERNED PHOSPHOLIPID FILM T. Shiomitsu and T. ToriiUniversity of Tokyo, JAPAN
W69FPROTEIN REFOLDING PROMOTED BY MULTI-DILUTION MICROCHIPH. Yamaguchi1, M. Miyazaki1,2, and H. Maeda1,2
1National Institute of Advanced Industrial Science and Technology (AIST), JAPAN and2 Kyushu University, JAPAN
W70FSPATIALLY TARGETED STIMULATION OF CELLS FOR QUANTITATIVE GAP JUNCTION ANALYSISS. Chen and L.P. LeeUniversity of California, Berkeley, USA
W65FA SMART POLYMER LAB-ON-A-TUBE (LOT) WITH SPIRALLY-ROLLED MICROCHANNELS FORIN-SITU DRUG DELIVERY AND BRAIN TUMOR MONITORINGC. Li, W. Jung, A. Browne, R.K. Narayan, and C.H. AhnUniversity of Cincinnati, USA
Applications
AUTOMATED HIGH-THROUGHPUT STRUCTURAL PROTEIN ANALYSIS USING SMALL ANGLE X-RAYSCATTERING COMBINED WITH A MICROFLUIDIC APPROACHS.S. Nielsen1, D. Snakenborg1,2, K.N. Toft2, M.G. Jeppesen2, J.K. Jacobsen3, B. Vestergaard2,L. Arleth2, and J.P. Kutter11Technical University of Denmark (DTU), DENMARK and 2Copenhagen University, DENMARK,3Novo Nordisk A/S, DENMARK
ENZYME KINETICS BY DIRECTLY IMAGING A POROUS SILICON MICROREACTOR USING DIOSMASS SPECTROMETRYK.P. Nichols and H.J.G.E. GardeniersMESA+, University of Twente, THE NETHERLANDS
16:20 - 16:40
Session 3B3Clinical and Biomolecular Analysis
Session 3A3Protein Expression and Characterization
A MICROFABRICATED DEVICE FOR PERFORMING COMPREHENSIVE ONLINE LC-CE-MS FORPROTEOMICS APPLICATIONSJ.S. Mellors, A.G. Chambers, W.H. Henley, and J.M. RamseyUniversity of North Carolina, Chapel Hill, USA
A FIELD-DEPLOYABLE SYSTEM FOR AUTOMATED MOLECULAR TESTING USING MODULARMICROFLUIDICSM.L. Hupert1, H. Wang1, H.-W. Chen1, W. Stryjewski2, D. Patterson1,2, M.A. Witek1, P. Datta1, J.Goettert1, M.C. Murphy1, and S.A. Soper1,2
1Louisiana State University, USA and 2BioFluidica Microtechnologies , USA
16:40 - 17:00
KINETICS OF PROTEIN EXPRESSION IN SINGLE CELLS USING MICROFLUIDICSJ.-U. Shim, L. Olguin, G. Whyte, D. Bratton, F. Hollfelder, C. Abell, and W. HuckUniversity of Cambridge, UK
ONE-STEP IMMUNOASSAY ON CAPILLARY DRIVEN MICROFLUIDICSL. Gervais1,2, M. Zimmermann1,2, P. Hunziker2, and E. Delamarche1
1IBM Zürich Research Laboratory, SWITZERLAND and 2University Hospital Basel, SWITZERLAND
17:00 - 17:20
17:20 Adjourn for the Day
Grand Ballroom A-B Grand Ballroom C
μTAS 2008 • San Diego 35
Thursday ProgramSan Diego μTAS 2008
A PLASMONIC LIQUID WAVEGUIDE SENSOR USING NANOPARTICLES FOR LABEL-FREEMEASUREMENT APPLICATIONSH.J. Huang1, D.P. Tsai2, and A.Q. Liu1
1Nanyang Technological University, SINGAPORE and 2National Taiwan University, TAIWAN
DROPLET-BASED MICROFLUIDIC PLATFORMS FOR SELECTING INHIBITORS OF VIRAL CELL-ENTRYC.A. MertenUniversite Louis Pasteur and CNRS UMR 7006, FRANCE
09:00 - 09:20
A NEW MICRO FLOW CYTOMETER USING OPTICALLY-INDUCED DIELECTROPHORETIC FORCESFOR CONTINUOUS MICROPARTICLE COUNTING AND SORTINGY.-H. Lin1 and G.-B. Lee1,2
1National Cheng Kung University, TAIWAN and 2Industrial Technology Research Institute, TAIWAN
ON-CHIP SUB-CELLULAR RESOLUTION WHOLE-ANIMAL MANIPULATION FOR HIGH-THROUGHPUTIN VIVO DRUG/GENETIC SCREENINGC.B. Rohde, F. Zeng, and M.F. YanikMassachusetts Institute of Technology, USA
09:20 - 09:40
A MULTI-COLOR MICROFLUIDIC COLLOIDAL LASERS.K.Y. Tang and G.M. WhitesidesHarvard University, USA
CROSSING STREAMLINES TO LYSE CELLS AND SIMULTANEOUSLY SEPARATE GENOMIC CONTENTSK.J. Morton, K. Loutherback, D.W. Inglis, J.C. Sturm, R.H. Austin, and S.Y. ChouPrinceton University, USA
09:40 - 10:00
Session 4B1In Vivo and Cellular Screening
Session 4A1Microfluidic Integrated Optics
FABRICATION OF THREE-DIMENSIONAL STRUCTURE BY SELF-FORMING MENISCUS ANDITS APPLICATION TO ON-CHIP CELL FUSIONM. Gel1, Y. Kimura1, B. Techaumnat1, O. Kurosawa2, and M. Washizu1
1University of Tokyo, JAPAN and 2ASTEM Research Inst Kyoto, JAPAN
MICROCHIP-BASED POLYMERIC MULTIFUNCTIONAL MICROBOTSG.-H. Kwon1, J.-Y. Park1, E.-J. Lee1, M.L. Frisk2, D.J. Beebe2, and S.-H. Lee1
1Korea University, KOREA and 2University of Wisconsin , USA
10:30 - 10:50
SINGLE CELL MICROINJECTION USING COMPLIANT FLUIDIC CHANNELSA. Noori and P.R. SelvaganapathyMcMaster University, CANADA
MEMS-BASED MILLIMETER-SCALE POWER SOURCE WITH ON-BOARD FUELAND PASSIVE CONTROL SYSTEMS. Moghaddam, E. Pengwang, K. Lin, R. Masel, and M. ShannonUniversity of Illinois, Urbana-Champaign, USA
10:50 - 11:10
A MICROFLUIDIC CULTURE SYSTEM FOR SCREENING OF CHEMICAL DEFINED CONDITIONSFOR HUMAN EMBRYONIC STEM CELLS (hESC)K. Kamei1, S. Guo1, M. Ohashi1, Z.T.F. Yu1, E. Gschweng1, J. Tang1, J. McLaughlin1, K.-B. Lee2,O.N. Witte1, and H.R. Tseng1
1University of California, Los Angeles, USA and 2Rutgers University, USA
DEVELOPMENT AND FIELD EVALUATION OF ISFET PH SENSOR INTEGRATED WITHSELF-CALIBRATION DEVICE FOR DEEP-SEA OCEANOGRAPHY APPLICATIONST. Fukuba1, Y. Tamai1, M. Kyo2, K. Shitashima3, Y. Koike4, and T. Fujii11University of Tokyo, JAPAN,2Japan Agency for Marine-Earth Science and Technology (JAMSTEC), JAPAN,3Central Research Institute of Electric Power Industry (CRIEPI), JAPAN and4Civil Engineering Research and Environmental Studies, JAPAN
11:10 - 11:30
Session 4B2Innovative Microfluidic Applications
Session 4A2Tools for Controlled Cell Culture II
Thursday, October 16, 2008
08:00 - 08:40 Poster Awards Ceremony
Monday, Tuesday and Wednesday Poster AwardsWidmer Poster Award
10:00 – 10:30 Break & Exhibit Inspection
11:30 Conference Adjourns
Grand Ballroom A-B Grand Ballroom C
Grand Ballroom A-B Grand Ballroom C
µTAS 2008 • San Diego36
Notes µTAS 2008 San Diego
Notes