MicroTAS 2012

Plenary 1

ETHOLOGY AND RHEOLOGY OF AN AMOEBOID CELL
T. Nakagaki^1,2, ¹ Future University Hakodate, JAPAN, and ²JST, CREST, JAPAN

1.A1-1

INDUCTION OF ANGIOGENESIS IN MICROFLUIDIC DEVICES USING PROLYL HYDROXYLASE INHIBITORS AND SPHINGOSINE-1 PHOSPHATE
S. H. Lim^1,3, A. R. Aref³, C. Kim², M. Raghunath¹, and R. D. Kamm^2,3, ¹ National University of Singapore, SINGAPORE, ²Massachusetts Institute of Technology, USA, and ³BioSystems and Micromechanics IRG, Singapore –MIT Alliance for Research and Technology, SINGAPORE

1.A1-2

CONTRACTILE SKELETAL MUSCLE MICROTISSUES IN MICROCHANNEL
K. Shimizu^1,2, H. Araki², W. Tonomura², M. Hashida², and S. Konishi¹, ¹ Kyoto University, JAPAN, and ²Ritsumeikan University, JAPAN

1.A1-3

IN VITRO GENERATION OF PANCREATIC PSEUDO-ISLETS USING FREE-STANDING MESH PATTERNED CELLULAR HYDROGEL
C. Y. Bae, M.-K. Min, H. Kim, and J.-K. Park, KAIST, KOREA

1.B1-1

LABEL-FREE, HIGH THROUGHPUT ELECTRICAL DETECTION OF CELLS IN DROPLETS
E. Kemna, L. Segerink, M. Odijk, F. Wolbers, I. Vermes, and A. van den Berg, University of Twente, THE NETHERLANDS

1.B1-2

FUSION OF VACCINIA VIRUS PARTICLES WITH SINGLE CELLS – A KINETIC STUDY FACILITATED BY MICROFLUIDIC TECHNOLOGY
P. Kuhn, F. I. Schmidt, J. Mercer, and P. S. Dittrich, ETH Zurich, SWITZERLAND

1.B1-3

IN-CELL WESTERN^TM ON DIGITAL MICROFLUIDICS FOR ANALYSIS OF SIGNALING PATHWAYS IN SINGLE CELLS
A. H. C. Ng, M. D. Chamberlain, K. Choi, R. Fobel, and A. R. Wheeler, University of Toronto, CANADA

1.C1-1

COLOCALIZATION OF Q-DOTS CARRIED BY MOTOR PROTEINS ON MICROTUBULE ARRAY IN NANOTRACKS
K. Fujimoto¹, M. Kitamura¹, M. Yokokawa³, H. Kotera¹, and R. Yokokawa^1,2, ¹ Kyoto University, JAPAN, ²Japan Science and Technology Agency (JST), JAPAN, and ³University of Tsukuba, JAPAN

1.C1-2

LABEL-FREE DETECTION OF REAL-TIME DNA AMPLIFICATION USING NANOWALL ARRAY STRUCTURES
K. Ogawa¹, T. Yasui¹, N. Kaji¹, Y. Okamoto¹, M. Tokeshi^1,2, Y. Horiike³, M. Nilsson⁴, and Y. Baba^1,5, ¹ Nagoya University, JAPAN, ²Hokkaido University, JAPAN, ³National Institute for Materials Science, JAPAN, ⁴Uppsala University, SWEDEN, and ⁵National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

1.C1-3

DETECTION OF SUB-PICOLITER-PER-MINUTE FLOWS BY ELECTROCHEMICAL AUTOCORRELATION SPECTROSCOPY
K. Mathwig, D. Mampallil, S. Kang, and S. G. Lemay, University of Twente, THE NETHERLANDS

1.A2-1

TISSUE MICROPROCESSING
G. V. Kaigala, R. D. Lovchik, and E. Delamarche, IBM Research GmbH, SWITZERLAND

1.A2-2

IN VITRO WOUND-HEALING ANALYTICAL SYSTEM COMPOSED OF A MICRO AUTOMATED SCRATCHER AND OXYGEN GRADIENT CHAMBER
H. Ota¹, N. Tanaka¹, K. Fukumori¹, N. Goda², M. Yamato¹, and T. Okano¹, ¹ Tokyo Women's Medical University, JAPAN, and ²Waseda University, JAPAN

1.A2-3

A PLATFORM FOR COMBINATORIAL MECHANOBIOLOGICAL STIMULATION OF ENGINEERED MICROTISSUES
B. M. Beca¹, C. Moraes¹, J. Nichol², A. Khademhosseini², Y. Sun¹, and C. A. Simmons¹, ¹ University of Toronto, CANADA, and ²Massachusetts Institute of Technology, USA

1.B2-1

10 MINUTE WESTERN BLOTTING WITH 54-PLEX THROUGHPUT FOR CLINICAL CONFIRMATORY HIV DIAGNOSIS IN HUMAN SERUM
A. J. Hughes, and A. E. Herr, UC Berkeley, USA

1.B2-2

DROPLET-BASED LIQUID-LIQUID EXTRACTION AND ON-CHIP IR-WAVEGUIDE-SPECTROSCOPY DETECTION OF COCAINE IN HUMAN SALIVA
P. Wägli¹, Y.-C. Chang², A. Homsy¹, L. Hvozdara², P. D. van der Wal¹, H. P. Herzig², and N. F. de Rooij¹, ¹ EPFL, STI IMT-NE, SAMLAB, SWITZERLAND, and ²EPFL, STI IMT-NE, OPT, SWITZERLAND

1.B2-3

LABEL-FREE DNA QUANTIFICATION VIA A 'PIPET, AGGREGATE AND BLOT' (PAB) APPROACH ON FILTER PAPER
J. Li, Q. Liu, and J. P. Landers, University of Virginia, USA

1.C2-1

MIICROFLUIDIC-BASED OIL-IMMERSION LENSES FOR HIGH RESOLUTION MICROSCOPY
M. N. Gulari, A. Tripathi, and N. Chronis, University of Michigan, USA

1.C2-2

REAL-TIME 3D SHAPE MEASUREMENT OF MICRO DROPLET USING DIGITAL HOLOGRAPHIC MICROSCOPY
T. Matsuo¹, H. Kinoshita², T. Fujii², and A. Moto¹, ¹ USHIO INC., JAPAN, and ²The University of Tokyo, JAPAN

1.C2-3

INTEGRATED ANGLE RESOLVED SPECTROSCOPY WITH NOVEL OPTICS 'CALDERA MIRROR'
Y. Kazama, and A. Hibara, The University of Tokyo, JAPAN

Plenary 2

INTERROGATING NEURODEGENERATIVE DISEASE STATES USING PLURIPOTENT STEM CELLS: A CASE OF STUDY IN HUNTINGTON DISEASE
E. Pecho-Vrieseling, C. Rieker, T. Bouwmeester, H. van der Putten, and F. Paolo Di Giorgio, Novartis Institute for Biomedical Research, SWITZERLAND

1.A3-1

CIRCULAR MICROCHANNELS ENHANCE DIODICITY PERFORMANCE AT ULTRA-LOW REYNOLDS NUMBER FOR MICROFLUIDIC BEAD-BASED DIODES
R. D. Sochol, J. Lei, A. Lu, E. L. Hicks, S. Gao, V. Menon, K. Iwai, L. P. Lee, and L. Lin, University of California, Berkeley, USA

1.A3-2

MEMS-BASED PILLARED SURFACE FOR HIGH-SPEED DROPLET MANIPULATION: FAILURE OF CASSIE-BAXTER MODEL
K. Morimoto, K. Fukumoto, and Y. Suzuki, The University of Tokyo, JAPAN

1.A3-3

ENGINEERING FLOW CROSS-SECTION VIA PROGRAMMED PILLARS
H. Amini^1,2, M. Masaeli^1,2, E. Sollier^1,2, Y. Xie³, B. Ganapathysubramanian³, H. A. Stone⁴, and D. Di Carlo^1,2, ¹ University of California, Los Angeles, USA, ²California NanoSystems Institute, USA, ³Iowa State University, USA, and ⁴Princeton University, USA

1.A3-4

MICROFLUIDIC SERIAL DAC FOR ANALOG PRESSURE GENERATION
F. Yu, V. Kibardin, M. A. Horowitz, and S. R. Quake, Stanford University, U.S.A

1.B3-1

DROPLET IMMOBILIZATION, SPLITTING, METERING AND ALIQUOTING WITH SURFACE ENERGY TRAPS CREATED USING SU8 SHADOW MASK
Y. Zhang, and T.-H. Wang, Johns Hopkins University, USA

1.B3-2

PASSIVE, LABEL-FREE DROPLET SORTING BY CHEMICAL COMPOSITION USING TENSIOPHORESIS
G. K. Kurup, and A. S. Basu, Wayne State University, USA

1.B3-3

A CONTINUOUS FLOW MICRODROPLET "LYSIS" SYSTEM
K. Iwai, R. D. Sochol, and L. Lin , University of California, Berkeley, USA

1.B3-4

REPLACING FLOWS WITH GRADIENTS OF CONFINEMENT IN DROPLET MICROFLUIDICS
R. Dangla, S. C. Kayi, and C. N. Baroud, Ecole Polytechnique, FRANCE

1.C3-1

GIANT VESICLE FORMATION THROUGH THE ASSEMBLY OF 2D SUPPORTED LIPID BILAYERS
N. Misawa¹, H. Oyama¹, R. Tero¹, and K. Sawada^1,2, ¹ Toyohashi University of Technology, JAPAN, and ²JST-CREST, JAPAN

1.C3-2

MICROFLUIDIC PASSIVE PERMEABILITY ASSAY USING ARRAYED DROPLET INTERFACE MEMBRANES
T. Nisisako^1,2, S. A. Portonovo¹, and J. J. Schmidt¹, ¹ University of California, Los Angeles, USA, and ²Tokyo Institute of Technology, JAPAN

1.C3-3

GENERATION OF MULTIPLE DROPLETS WITH DENSLY PACKED SEGMENTS FOR STUDYING CHEMICAL SIGNALING IN DROPLET NETWORKS
J. Guzowski, P. M. Korczyk, S. Jakieła, and P. Garstecki, Polish Academy of Sciences, POLAND

1.C3-4

UNIFORM SIZE LIPOSOMES ON A CHIP: OBSERVATION OF TRANSPORT KINETICS THROUGH NANOPORE MEMBRANE PROTEIN
T. Osaki¹, K. Kamiya¹, R. Kawano¹, and S. Takeuchi^1,2, ¹ Kanagawa Academy of Science and Technology, JAPAN, and ²The University of Tokyo, JAPAN

Plenary 3

DETECTION OF WATER BORNE MICROBES USING AN AUTONOMOUS UNDERWATER SENSOR, THE ENVIRONMENTAL SAMPLE PROCESSOR (ESP)
J. Birch¹, S. Jensen¹, B. Roman¹, D. Pargett¹, C. Preston¹, K. Yamahara², R. Marin III¹, E. Demir-Hilton¹, B. Ussler¹, and C. Scholin¹, ¹ Monterey Bay Aquarium Research Institute, USA, and ²Center for Ocean Solutions/Stanford University, USA

2.A1-1

ON-PLATE AND ON-DEMAND REMOVAL OF ADHERENT CELLS USING PHOTO-ACID-GENERATING SUBSTRATE AND MICRO-PROJECTION SYSTEM
K. Sumaru, K. Kikuchi, T. Takagi, M. Yamaguchi, T. Satoh, K. Morishita, and T. Kanamori, National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

2.A1-2

AN ANGLE-TUNABLE MICROFLAP TOWARD THE OBSERVATION OF PARASITE INVASION INTO HOST ADHERENT CELLS
T. Teshima¹, H. Onoe^1,3, H. Aonuma², K. Kuribayashi-Shigetomi¹, H. Kanuka², and S. Takeuchi^1,3, ¹ The University of Tokyo, JAPAN, ²Jikei University School of Medicine, JAPAN, and ³ERATO Takeuchi Biohybrid Innovation Project, JST, JAPAN

2.A1-3

SINGLE CELL SUSPENSION CULTURE USING POLYHEMA COATING FOR ANOIKIS ASSAY AND SPHERE FORMATION
Y.-C. Chen, P. Ingram, X. Lou, and E. Yoon, University of Michigan, USA

2.B1-1

ENCODING OF LIQUID CAPPED MICROCAPSULE AND HETEROGENEOUS ASSEMBLY FOR MULTIPLEXED ASSAY
Y. Song, T. Kwon, D. Lee, J. Kim, D. Oh, T. Park, and S. Kwon, Seoul Naional University, KOREA

2.B1-2

DIGITAL MICROFLUIDICS FOR ON-DEMAND 3D MICROGEL FORMATION AND FUNCTIONAL MYOCARDIAL TISSUE ASSAYS
I. A. Eydelnant, B. B. Li, and A. R. Wheeler, University of Toronto, CANADA

2.B1-3

MOSAIC HYDROGELS: ONE-STEP FORMATION OF MULTISCALE SOFT MATERIALS
L. Leng, A. Mcallister, B. Zhang, A. Ranu, M. Radisic, and A. Guenther, University of Toronto, CANADA

2.C1-1

ELECTROKINETICALLY INTEGRATED ISOLATION AND AMPLIFICATION OF PROTEIN-BINDING NUCLEIC ACIDS ON A MICROCHIP
J. Kim, J. P. Hilton, K.-A. Yang, R. Pei, M. Stojanovic, and Q. Lin, Columbia University, USA

2.C1-2

DNA-BASED MOLECULAR ECOSYSTEM ON A CHIP
A. Padirac¹, A. Estévez-Torres², T. Fujii¹, and Y. Rondelez¹, ¹ The University of Tokyo, JAPAN, and ²Laboratoire de Photonique et de Nanostructures, CNRS, FRANCE

2.C1-3

ARTIFICIAL DARWINIAN SELECTION TECHNOLOGY ON MICROARRAY CHIPS TOWARDS DIRECTED EVOLUTION USING SINGLE MOLECULE PROCESSING
S. Sato^1,2, M. Biyani^1,3, T. Akagi^1,3, and T. Ichiki^1,3, ¹ The University of Tokyo, JAPAN, ²Center for Medical System Innovation, JAPAN, and ³JST, JAPAN

2.A2-1

ON-CHIP SEQUENTIAL MOLECULE DELIVERY INTO ISOLATED CELLS USING VORTEX ASSISTED ELECTROPORATION
H. Yun, and S. C. Hur, Harvard University, USA

2.A2-2

BEAD-ASSISTED ACOUSTIC DIFFERENTIAL EXTRACTION OF SPERM CELLS IN DILUTE SAMPLES FOR POTENTIAL FORENSIC ANALYSES
K. Xu, B. L. Poe, J. A. Lounsbury, and J. P. Landers, University of Virginia, USA

2.A2-3

MANIPULATING SINGLE PARTICLES USING STANDING SURFACE ACOUSTIC WAVES
X. Ding¹, S.-C. S. Lin¹, S. Li¹, L. Wang², and T. J. Huang¹, ¹ The Pennsylvania State University, USA, and ²Ascent Bio-Nano Technologies Inc., USA

2.B2-1

AUTOMATED HIGH-THROUGHPUT CHARACTERIZATION OF CELLS USING MULTIMODAL ELECTRICAL AND OPTICAL CYTOMETRY (MULTIMEOC)
H.-W. Su, J. Prieto, and J. Voldman, Massachusetts Institude of Technology, USA

2.B2-2

HARNESSING ENZYMATICALLY MACHINED NANO- AND MICRO-SCALE SURFACE TOPOGRAPHIES FOR HIGH-THROUGHPUT SEPARATIONS
J. H. Huang, A. Priye, A. Jayaraman, and V. M. Ugaz, Texas A&M University, USA

2.B2-3

SINGLE-STEP UNTRAHIGH ENRICHMENT OF LEUKOCYTES FROM WHOLE BLOOD ENABLED BY CELL ROLLING ON BIOMIMETIC ADHESIVE SURFACES
S. Bose¹, C. Shen¹, R. Singh¹, M. Hanewich-Hollatz¹, C.-H. Lee¹, J. M. Karp², and R. Karnik¹, ¹ Massachusetts Institute of Technology, USA, and ²Brigham and Women's Hospital and Harvard Medical School, USA

2.C2-1

SHAPE-CONTROLLABLE SYNTHESIS OF HYBRID STRUCTURES BY THREE-DIMENSIONAL (3D) HYDRODYNAMIC FOCUSING METHOD
M. Lu¹, Q. Hao¹, A. A. Nawaz¹, L. Wang², and T. J. Huang¹, ¹ The Pennsylvania State University, USA, and ²Ascent Bio-Nano Technologies Inc., USA

2.C2-2

HIERARCHICAL TIO₂ BRUSH TYPE NANOSTRUCTURES FOR EFFICIENT PHOTOELECTROCHEMICAL WATER SPLITTING
Y. Pihosh^1,2, K. Mawatari^1,2, I. Turkevych³, T. H. H. Le¹, Y. Kajita¹, H. Chinen¹, M. Tosa⁴, and T. Kitamori^1,2, ¹ University of Tokyo, JAPAN, ²Japan Science and Technology Agency, JAPAN, ³National Institute of Advanced Industrial Science and Technology, JAPAN, and ⁴National Institute for Materials Science, JAPAN

2.C2-3

DROPLET-BASED 3D GRAPHENE STRUCTURE SYNTHESIS
D. J. Han, F. Liu, J. H. Jung, H. D. Ha, and T. S. Seo, Korea Advanced Institute of Science and Technology (KAIST), KOREA

2.A3-1

PROTEIN DIGEST SEPARATIONS IN SILICON PILLAR ARRAYS CONFORMALLY COATED WITH POROUS SILICA
W. De Malsche¹, S. De Bruyne^1,2, J. O. De Beeck¹, S. Eeltink¹, H. Gardeniers², and G. Desmet¹, ¹ Vrije Universiteit Brussel, BELGIUM, and ²Mesa+ Institute for Nanotechnology, THE NETHERLANDS

2.A3-2

RAPID SOUTHERN-BLOT-TYPE ASSAYS USING BIDIRECTIONAL ISOTACHOPHORESIS
C. M. Han, S. S. Bahga, and J. G. Santiago, Stanford University, USA

2.A3-3

FREE-STANDING HYDROGEL MICROARRAYS: OPEN-CHANNEL MICROFLUIDICS FOR MASSIVELY PARELLEL PROTEIN ELECTROPHORESIS
T. A. Duncombe¹, T. M. Tran¹, F. Benito-Lopez², D. Diamond², and A. E. Herr¹, ¹ UC Berkeley / UC San Francisco Joint Graduate Group in Bioengineering, USA, and ²Dublin City University, IRELAND

2.A3-4

ONE-STEP ISOLATION OF TRANSITORY PROTEIN COMPLEXES WITH IFAST
S. Berry, L. Strotman, E. Chin, S. Jackson, N. Thompson, S. Miyamoto, C. Alexander, R. Burgess, and D. J. Beebe, University of Wisconsin-Madison, USA

2.B3-1

WHY IS THE MINIMUM UNIT OF LIFE A CELL? : BUILDING AN "RNA WORLD" MODEL PROTOCELL USING DROPLET-BASED MICROFLUIDICS
S. Matsumura, F. M. Coldren, A. Marin, A. Fallah-Araghi, A. D. Griffiths, and M. Ryckelynck, Université de Strasbourg, FRANCE

2.B3-2

QUANTITATIVE DETECTION OF CIRCULATING TUMOR DNA IN PLASMA SAMPLES BY DROPLET DIGITAL PCR.
D. Pekin^1,2, S. Kotsopoulos³, L. Xinyu³, I. Atochin³, H. Gang³, D. Le Corre¹, L. Benhaim¹, J. B. Hutchison³, D. R. Link³, H. Blons¹, P. Laurent-Puig¹, and V. Taly¹, ¹ Université Paris Descartes, FRANCE, ²Université de Strasbourg, FRANCE, and ³RainDance Technologies, USA

2.B3-3

MULTIPLEX ANALYSIS OF ENZYME KINETICS AND INHIBITION BY DROPLET MICROFLUIDICS USING PICOINJECTORS
S. L. Sjostrom, H. N. Joensson, and H. A. Svahn, Royal Institute of Technology (KTH), SWEDEN

2.B3-4

A LOW COST AND HIGH THROUGHPUT MAGNETIC BEAD-BASED IMMUNO-AGGLUTINATION ASSAY IN CONFINED DROPLETS
B. Teste, A. Ali-Cherif, S. Descroix, J. L. Viovy, and L. Malaquin, Université Pierre et Marie Curie, FRANCE

2.SS-1

NEW APPROACH FOR CHEMICAL –BIOLOGICAL CHARACTERISTICS OF MICRO ECOSYSTEM IN CORAL
Y. Suzuki¹, S. Agostini², B. E. Casareto¹, H. Fujimura², T. Higuchi¹, and Y. Nakano², ¹ Shizuoka University, JAPAN, and ²University of the Ryukyus, JAPAN

2.SS-2

MICROFLUIDIC DEVICES FOR OCEAN SCIENCE AND EXPOLORATION
T. Fukuba¹, C. Provin², K. Mogi², H. Kinoshita², K. Okamura³, M. Kyo¹, and T. Fujii², ¹ Japan Agency for Marine-Earth Science and Technology, JAPAN, ²The University of Tokyo, JAPAN, and ³Kochi University, JAPAN

2.SS-3

DEVELOPMENT AND FIELD TESTING OF LASER-INDUCED BREAKDOWN SPECTROSCOPY FOR IN SITU MULTI-ELEMENT ANALYSIS DURING UNDERWATER SURVEYS
B. Thornton, T. Masamura, T. Takahashi, and T. Ura, The University of Tokyo, JAPAN

2.SS-4

DEVELOPMENT OF DEEP BOREHOLE LONG TERM OBSERVATORY TO MONITOR THE EARTH'S INTERIOR
M. Kyo, Y. Namba, T. Kimura, K. Kitada, and E. Araki, Japan Agency for Marine-Earth Science and Technology, JAPAN

Plenary 4

MICROFLUIDIC TOOLS TO MODEL AND ANALYZE THE BODY
S. Takayama^1,2, ¹ University of Michigan, USA, and ²Ulsan National Institute of Science and Technology, KOREA

3.A1-1

SINGLE CELL SURGERY WITH MONODISPERSED MICROBUBBLES GENERATED BY A PULSED DISCHARGE OF MICROELECTRIC KNIFE
H. Kuriki¹, Y. Yamanishi¹, S. Sakuma¹, S. Akagi², and F. Arai¹, ¹ Nagoya University, JAPAN, and ²National Agriculture and Food Research Organization, JAPAN

3.A1-2

FAST WHOLE BLOOD TESTING FOR DETECTING BIOMARKERS BY SIZE-EXCLUSION SPR SENSING
S. Hiramatsu¹, K. Terao¹, K. Shimizu¹, N. Miyanishi², T. Suzuki¹, H. Takao¹, F. Shimokawa¹, and F. Oohira¹, ¹ Kagawa University, JAPAN, and ²Toyo University, JAPAN

3.A1-3

IMPLANTABLE MICROFLUIDIC INTERFACE DEVICES WITH DRUG PERFUSION FUNCTION THROUGH HYDROGEL MEMBRANE
H. Takehara^1,2, A. Nagaoka^1,2, J. Noguchi¹, T. Akagi¹, H. Kasai¹, and T. Ichiki¹, ¹ The University of Tokyo, JAPAN, and ²Japan Society for the Promotion of Science, JAPAN

3.B1-1

MICROFLUIDIC THERMAL DIGESTION OF AQUEOUS SAMPLE AT TEMPERATURE HIGHER THAN 100^OC
F. Xie¹, B. Wang¹, T. Dong³, W. Wang^1,2, J. Tong³, S. Xia³, W. Wu^1,2, and Z. Li^1,2, ¹ Peking University, CHINA, ²National Key Laboratory of Micro/Nano Fabrication Technology, CHINA, and ³Institute of Electronics Chinese Academy of Sciences, CHINA

3.B1-2

A MEMS ISOTHERMAL TITRATION BIOCALORIMETER
B. Wang, Y. Jia, and Q. Lin, Columbia University, USA

3.B1-3

HIGH EFFICIENCY ENERGY CONVERSION FROM LIQUID JET FLOW
Y. Xie, L. de Vreede, T. Nguyen, H. L. de Boer, A. Sprenkels, A. van den Berg, and J. C. T. Eijkel , University of Twente, THE NETHERLANDS

3.C1-1

A LOW-COST, LABEL-FREE DNA DETECTION METHOD BASED ON DIRECT ELECTRONIC READ IN LAB-ON-CHIP FORMAT, WITH APPLICATION TO LONG-RANGE PCR
M. L. Diakite, J. Champ, S. Descroix, L. Malaquin, F. Amblard, and J.-L. Viovy, Centre National de la Recherche Scientifique et Université Pierre et Marie Curie, FRANCE

3.C1-2

SINGLE-MOLECULE TUNNEL-CURRENT BASED IDENTIFICATION OF DNA/RNA TOWARDS SEQUENCING BY USING NANO-MCBJ
T. Ohshiro, M. Tsutsui, K. Matsubara, M. Furuhashi, M. Taniguchi, and T. Kawai, Osaka University, JAPAN

3.C1-3

ON-CHIP ISOTACHOPHORESIS AND FUNCTIONALIZED HYDROGEL CAPTURE FOR SENSITIVE MICRO-RNA DETECTION
G. Garcia-Schwarz, and J. G. Santiago, Stanford University, USA

3.A2-1

NEURAL STEM CELL DIFFERENTIATION IN VASCULAR MICROENVIRONMENT
S. Han¹, Y. Shin¹, H. E. Jeong¹, K. Yang², R. D. Kamm³, S.-W. Cho², and S. Chung¹, ¹ Korea University, KOREA, ²Yonsei University, KOREA, and ³Massachusetts Institute of Technology, USA

3.A2-2

A MICROFLUIDIC PLATFORM FOR PROBING MULTIPLE INTACT BLOOD VESSELS
B.-U. Moon, S. Sebastian-Bolz, and A. Günther, University of Toronto, CANADA

3.A2-3

MICROFLUIDIC KIT-ON-A-LID: A VERSATILE PLATFORM FOR NEUTROPHIL CHEMOTAXIS ASSAYS AND ASTHMA DIAGNOSTICS
E. K. Sackmann^1,3, E. Berthier^1,3, E. W. K. Young^1,3, M. A. Shelef^2,3, P. Fichtinger^2,3, E. Schwantes^2,3, M. Evans^2,3, S. Mathur^2,3, A. Huttenlocher², and D. J. Beebe^1,3, ¹ Wisconsin Institute for Medical Research, USA, ²University of Wisconsin Hospital and Clinics, USA, and ³University of Wisconsin-Madison, USA

3.B2-1

DYNAMICALLY PROGRAMMABLE PARYLENE-C BONDING LAYER FLUORESCENCE FOR RE-WRITABLE DATA STORAGE ON A MICROFLUIDIC CHIP
A. T. Ciftlik, and M. A. M. Gijs, École Polytechnique Fédérale de Lausanne (EPFL), SWITZERLAND

3.B2-2

OPTICAL NEAR-FIELD INDUCED CHEMICAL PARTIAL HYDROPHOBIC/ HYDROPHILIC MODIFICATION WITH SUB-DIFFRACTION LIMIT RESOLUTION
T. H. H. Le, K. Mawatari, N. Hasumoto, Y. Pihosh, K. Kitamura, T. Yatsui, T. Kawazoe, M. Naruse, M. Ohtsu, and T. Kitamori, University of Tokyo, JAPAN

3.B2-3

HIGH-RESOLUTION MICROPATTERNING OF OFF-STOCHIOMETRIC THIOL-ENES (OSTE) VIA A NOVEL LITHOGRAPHY MECHANISM
J. M. Karlsson, C. F. Carlborg, F. Saharil, F. Forsberg, F. Niklaus, W. van der Wijngaart, and T. Haraldsson, KTH Royal Institute of Technology, SWEDEN

3.C2-1

SINGLE DNA MANIPULATION IN SUBLITHOGRAPHIC NANOWIRE ARRAY CHIPS
T. Yasui¹, S. Rahong², T. Yanagida², N. Kaji¹, M. Kanai², K. Doi², M. Tokeshi^1,3, S. Kawano², T. Kawai², and Y. Baba^1,4, ¹ Nagoya University, JAPAN, ²Osaka University, JAPAN, ³Hokkaido University, JAPAN, and ⁴National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

3.C2-2

ZIF-COUPLED MICRORESONATOR FOR HIGHLY SENSITIVE AND SELECTIVE GAS DETECTION
Y. Hwang¹, A. Phan², K. Galatsis¹, O. M. Yaghi³, and R. N. Candler¹, ¹ University of California, Los Angeles, USA, ²Molecular and NanoArchitecture Center, VIETNAM, and ³University of California, Berkeley, USA

3.C2-3

THE IMPLEMENTATION OF POLYSILICON NANOWIRE BASED BIOMOLECULAR SENSOR SYSTEM-ON-CHIP
C.-W. Huang¹, Y.-J. Huang¹, P.-W. Yen¹, H.-T. Hsueh¹, C.-Y. Lin², M.-C. Chen², C.-H. Ho², F.-L. Yang², H.-H. Tsai³, H.-H. Liao³, Y.-Z. Juang³, C.-K. Wang¹, S.-S. Lu¹, and C.-T. Lin¹, ¹ National Taiwan University, TAIWAN, ²National Nano Device Laboratories, TAIWAN, and ³National Chip Implementation Center, National Applied Research Laboratories, TAIWAN

Plenary 5

SMART MICROPARTICLES, PARTIPETTING, AND LIQUID MICROARRAYS : FROM BASIC TECHNOLOGIES TO APPLICATIONS
S. Kwon^1,2, ¹ Seoul National University, KOREA, and ²Quanta Matrix Corp., KOREA

Plenary 6

MICROFLUIDIC APPS ON STANDARD LAB-INSTRUMENTS
R. Zengerle^1,2, J. Hoffmann^1,2, G. Roth^1,2, O. Strohmeier^1,2, A. R. Fiebach², L. Drechsel², S. Zhang², A. Kloke², N. Paust^1,2, D. Mark^1,2, and F. von Stetten^1,2, ¹ University of Freiburg, GERMANY, and ²HSG-IMIT - Institut für Mikro- und Informationstechnik, GERMANY

4.A1-1

DEFORMATION ANALYSIS OF INDIVIDUAL RED BLOOD CELLS IN LARGE POPULATIONS USING A SINGLE CELL MICROCHAMBER ARRAY (SiCMA) CHIP
I. Doh^1,2,3, W. C. Lee^1,3, Y.-H. Cho², A. P. Pisano¹, and F. A. Kuypers³, ¹ University of California at Berkeley, USA, ²Korea Advanced Institute of Science and Technology (KAIST), KOREA, and ³Children's Hospital Oakland Research Institute (CHORI), USA

4.A1-2

LEUKOCYTE MECHANOPHENOTYPING BY DEFORMABILITY CYTOMETRY
D. R. Gossett¹, H. T. K. Tse¹, K. Goda¹, O. Adeyiga¹, T. A. Woods², S. W. Graves², O. O. Yang¹, and D. Di Carlo¹, ¹ University of California, Los Angeles, USA, and ²University of New Mexico, USA

4.A1-3

SIZE- AND DEFORMABILITY-BASED SORTING OF PARTICLES USING ASYNCHRONOUS LOGIC CIRCUITS
M. A. Cartas-Ayala, L. Gilson, and R. Karnik, Massachusetts Institute of Technology, USA

4.B1-1

A NOVEL INTERFACE COUPLING DROPLET MICROFLUIDICS WITH MALDI-MASS SPECTROMETRY
S. K. Küster¹, S. R. Fagerer¹, P. E. Verboket¹, K. Eyer¹, K. Jefimovs², R. Zenobi¹, and P. S. Dittrich¹, ¹ ETH Zurich, SWITZERLAND, and ²EMPA, SWITZERLAND

4.B1-2

SUSPENDED MICROFLUIDICS: AN OPEN AND USER-FRIENDLY TECHNOLOGY PLATFORM FOR HIGH-THROUGHPUT METABOLOMIC STUDIES
E. Berthier¹, A. Theberge¹, B. Casavant¹, C. Guo², C. Wang², D. Beebe¹, and N. Keller¹, ¹ University of Wisconsin-Madison, USA, and ²University of South California, USA

4.B1-3

A HIGH-THROUGHPUT PLATFORM FOR PATTERNED DIFFERENTIATION OF EMBRYOID BODIES USING AIR BUBBLES
X. He, H. Kimura, J. Kawada, and T. Fujii, University of Tokyo, JST CREST, JAPAN

4.C1-1

HIGH-RESOLUTION NMR SPECTROSCOPY ON A CHIP BY STRUCTURAL COMPENSATION OF MAGNETIC SUSCEPTIBILITY MISMATCH
H. Ryan¹, J. P. Landers¹, M. R. Begley², and M. Utz³, ¹ University of Virginia, USA, ²University of California, USA, and ³University of Southampton, UK

4.C1-2

MONOTONIC TUNING OF PLASMON RESONANCE USING DEFORMABLE NANOPLASMONIC MEMBRANE FOR SURFACE-ENHANCED RAMAN SCATTERING
M. Kang, J.-J. Kim, Y.-J. Oh, and K.-H. Jeong, Korea Advanced Institute of Science and Technology (KAIST), KOREA

4.C1-3

FABRICATION AND DEMONSTRATION OF ULTRA-SENSITIVE AND FAST FLUORESCENCE IMMUNOASSAY USING NOVEL NANOPLASMONIC SENSOR INSIDE MICROFLUIDIC CHANNELS
R. Peng, C. Wang, L. Zhou, Q. Zhang, W. Zhang, and S. Y. Chou, Princeton University, USA

4.A2-1

PORTABLE LAB-ON-A-DISC SYSTEM INTEGRATING PHOTO-SWITCHABLE MICRO-VALVES FOR IN-SITU AQUATIC ENVIRONMENTAL MONITORING
M. Czugala, D. Maher, R. Burger, K. J. Fraser, J. Ducree, D. Diamond, and F. Benito-Lopez, Dublin City University, IRELAND

4.A2-2

DNA FIBER PREPARATION TECHNIQUE ON A CHIP FOR CLINICAL DIAGNOSIS
T. Suzuki¹, K. Terao¹, H. Suzuki¹, Y. Nitta¹, H. Takao¹, F. Shimokawa¹, F. Oohira¹, D. Hiramaru², and H. Kotera², ¹ Kagawa University, JAPAN, and ²Kyoto University, JAPAN

4.A2-3

SPERM QUALITY ASSESSMENT VIA SEPARATION AND SEDIMENTATION IN A MICROFLUIDIC DEVICE
T.-C. Chiang, C.-Y. Chen, H.-K. Liu, S.-S. Lin, C.-M. Lin, D.-S. Jong, V. F.-S. Tsai, J.-T. Hsieh, and A. M. Wo, National Taiwan University, TAIWAN

4.B2-1

RECORDING SIGNAL TRANSDUCTION DYNAMICS WITH UNPRECEDENTED TEMPORAL RESOLUTION
Y.-Y. Chiang¹, J. Stewart², C. Gizewski³, P. Ehrhard³, D. Janasek¹, and J. West^1,4, ¹ Leibniz-Institut für Analytische Wissenschaften, GERMANY, ²Leibniz Research Center for Working Environment and Human Factors, GERMANY, ³Technische Universität Dortmund, GERMANY, and ⁴University of Southampton, UK

4.B2-2

C.L.I.P – CONTINUOUS LIVE IMAGING PLATFORM FOR C. elegans AT PHYSIOLOGICAL CONDITIONS
J. Krajniak, and H. Lu, Georgia Institute of Technology, USA

4.B2-3

CYTOTOXICITY ANALYSIS ON A CHIP
M. Hamon¹, A. Khademhosseini², and J. W. Hong¹, ¹ Auburn University, USA, and ²Brigham and Women's Hospital, Harvard Medical School, USA

M.1.1

PRE-PROGRAMMED, SELF-POWERED CIRCUITS BUILT FROM MICROFLUIDIC CAPILLARY ELEMENTS
R. Safavieh, and D. Juncker, McGill University, CANADA

M.1.2

THREE-DIMENSIONAL HYDRODYNAMIC FOCUSING ACHIEVED BY A SINGLE CHANNEL LAYER, SINGLE SHEATH-FLOW INLET MICROFLUIDIC DEVICE
S.-C. Lin¹, P.-W. Yen¹, and Y.-C. Tung², ¹ National Taiwan University, TAIWAN, and ²Academia Sinica, TAIWAN

M.1.3

TWO-STAGE LIQUID DRIVING USING VACUUM TRANSFORMERS WITH BATTERY-POWERED MINI-HOTPLATES FOR SIMPLE-TO-USE MICROFLUIDIC BIOCHIPS
C.-H. Tsai, C.-C. Hong, and W. Chung, National Tsing Hua University, TAIWAN

M.1.4

WALL-LESS MICROFLUIDIC CHANNELS USING 3-DIMEMSIONAL RING ARRAYS
W. C. Lee^1,2, Y. J. Heo^1,2, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²Japan Science and Technology Agency, JAPAN

M.1.5

ON-CHIP LIQUID CONTROL USING STRIPED SURFACE TOPOGRAPHY FABRICATED BY POLYMER INJECTION MOLDING
K. S. Sørensen^1,2, P. F. Østergaard¹, R. J. Taboryski¹, and M. F. Hansen¹, ¹ Technical University of Denmark, DENMARK, and ²Center for Integrated Point of Care Technologies (CiPoC), DENMARK

M.1.6

ON-CHIP AEROSOL GENERATION FOR ORGANS-ON-CHIPS
K. Domansky¹, M. Karpelson¹, R. J. Wood^1,2, and D. E. Ingber^1,2, ¹ Wyss Institute for Biologically Inspired Engineering at Harvard University, USA, and ²Harvard School of Engineering and Applied Sciences, USA

M.1.7

A POWERLESS VALVING SYSTEM FOR FLUID FLOW IN PAPER NETWORKS
B. J. Toley, E. Fu, and P. Yager, University of Washington, USA

M.1.8

A MULTIPORT METERING VALVE TECHNOLOGY FOR ON-CHIP VALVING
H. Becker, R. Klemm, R. Sewart, and C. Gärtner, microfluidic ChipShop GmbH, GERMANY

M.1.9

FAST SURFACE-TOPOGRAPHY-DRIVEN DROPLET TRANSPORTATION ON THE MAGNETIC ELASTOMER WITH A SUPERHYDROPHOBIC SURFACE
K. Seo, J. Oh, J. Kim, R. Wi, and D. H. Kim, KAIST, KOREA

M.1.10

INVESTIGATION OF ENZYME REACTION IN EXTENDED-NANO SPACE MIMICKING CELLULAR ENVIRONMENTS
T. Saruko, K. Mawatari, and T. Kitamori, The University of Tokyo, JAPAN

M.1.11

BUBBLE-GATE FOR IN-PLANE FLOW CONTROL IN MICROFLUIDIC CHANNELS
A. Oskooei, and A. Günther, University of Toronto, CANADA

M.1.12

CHAOTIC FLUID MIXING BY ALTERNATING MICRO-PARTICLE TOPOLOGIES TO ENHANCE BIOCHEMICAL REACTIONS
Y. Gao¹, A. van Reenen¹, M. A. Hulsen¹, A. M. De Jong¹, M. W. J. Prins^1,2, and J. M. J. den Toonder^1,2, ¹ Eindhoven University of Technology, THE NETHERLANDS, and ²Philips Research, THE NETHERLANDS

M.1.13

NANOBUBBLES AND GAS DYNAMICS DURING CAPILLARY FILLING OF NANOCHANNELS
F. Chauvet^1,2, S. Geoffroy², A. Hamoumi^1,2, M. Prat², A.-M. Gué^1,2, and P. Joseph^1,2, ¹ CNRS, LAAS, FRANCE, and ²Univ de Toulouse, FRANCE

M.1.14

CONTROL OF INTERPARTICLE SPACING USING STRUCTURED MICROFLUIDIC CHANNELS
D. Pulido¹, A. Chung¹, H. Amini¹, M. Masaeli¹, and D. Di Carlo^1,2, ¹ University of California, Los Angeles, USA, and ²California NanoSystems Institute, USA

M.1.15

NONSPHERICAL MICROFLUIDIC DROPLETS WITH CONTROLLED MORPHOLOGY TO INDUCE RAPID PROTEIN PHASE TRANSITION
G. Simone¹, and P. A. Netti^1,2, ¹ University of Napoli "Federico II, ITALY, and ²Istituto Italiano di Tecnologia, ITALY

M.1.16

A DROPLET-BASED MICROFLUIDIC SYSTEM FOR HIGH-THROUGHPUT SCREENING OF PHOTOSENSITISERS AGAINST MICROBIAL ORGANISMS
S. Cho¹, D.-K. Kang², S. Sim¹, F. Geier¹, J.-Y. Kim¹, S.-I. Chang³, J. Edel¹, R. Wootton⁴, and A. deMello⁴, ¹ Imperial College London, UK, ²University of California, Irvine, USA, ³Chungbuk National University, KOREA, and ⁴ETH Zurich, SWITZERLAND

M.1.17

DETERMINISTIC SPLITTING OF ELECTROWETTING MICROCHANNELS
A. Banerjee, Y. Liu, J. Heikenfeld, and I. Papautsky, University of Cincinnati, USA

M.1.18

DIGITAL READOUT PLATFORM FOR WATER-IN-OIL DROPLET IMMUNOASSAYS RUNNING ON A CELL-PHONE FOR POINT OF CARE VIRAL LOAD SENSING
P. A. Sandoz, A. F. Coskun, A. J. Chung, W. M. Weaver, O. Adeyiga, D. Khodadadi, A. Ozcan, and D. Di Carlo, University of California, Los Angeles, USA

M.1.19

ON-CHIP BLADE FOR ACCURATE SPLITTING OF DROPLETS IN LIGHT-ACTUATED DIGITAL MICROFLUIDICS
S. N. Pei, and M. C. Wu, University of California, Berkeley, USA

M.1.20

WIRELESS EWOD (ELECTROWETTING-ON-DIELECTRIC) DEVICE USING PLANAR COILS
S. H. Byun¹, M.-G. Yoon^1,2, and S. K. Cho¹, ¹ University of Pittsburgh, USA, and ²Gangneung-Wonju National University, KOREA

M.1.21

ON-CHIP PROCEDURES FOR MAGNETIC PARTICLE-BASED ASSAY IN DROPLETS
H. Lee, L. Xu, and K. W. Oh, University at Buffalo, The State University of New York (SUNY) at Buffalo, USA

M.1.22

DROPLET-TRAIN SPR MICROCHIP FOR LABEL-FREE DETECTION OF BIO-INTERACTION USING NANOLITERS OF DRUG SAMPLE
T. Ghosh, Y. Xie, and C. H. Mastrangelo, University of Utah, USA

M.1.23

A RAPID SCREENING FOR HEMOGLOBIN-SPECIFIC APTAMERS BY USING A CONTINUOUS MICROFLUIDIC SYSTEM
C.-C. Wu¹, H.-I. Lin², C.-H. Weng¹, S.-C. Shiesh², and G.-B. Lee¹, ¹ National Tsing Hua University, TAIWAN, and ²National Cheng Kung University, TAIWAN

M.1.24

AUTOMATED INJECTION FROM EWOD DIGITAL MICROFLUIDIC CHIP INTO HPLC PURIFICATION SYSTEM
G. J. Shah^1,2, J. Lei¹, S. Chen¹, C.-J. Kim¹, P. Y. Keng¹, and R. M. van Dam¹, ¹ University of California, Los Angeles, USA, and ²Sofie Biosciences, USA

M.1.25

ELECTROCHEMICAL ANALYSIS OF MICRODROPLET FORMATION
M. Fukuyama¹, Y. Yoshida², J. C. T. Eijkel³, A. van ven Berg³, and A. Hibara¹, ¹ The University of Tokyo, JAPAN, ²Kyoto Institute of Thechnology, JAPAN, and ³University of Twente, THE NETHERLANDS

M.1.26

ION CONCENTRATION POLARIZATION IN A SING AND OPEN MICROCHANNEL USING SURACE-PATTERNED NAFION: EXPERIMENTAL AND THEORETICAL STUDY
M. Kim, M. Jia, and T. Kim, Ulsan National Institute of Science and Technology (UNIST), KOREA

M.1.27

ADDRESSABLE LIGHT-INDUCED HEAT KNOCKDOWN (aLINK) FOR CAENORHABDITIS (C.) ELEGANS IMMOBILIZATION
H.-S. Chuang, W.-T. Chiu, and C.-S. Chen, National Cheng Kung University, TAIWAN

M.1.28

MEASUREMENT OF THE IMAGINARY PART OF THE CLAUSIUS-MOSSOTTI FACTOR
Y. Y. Lin, and U. Lei, National Taiwan University, TAIWAN

M.1.29

NANO/MICRO JETS IN THIN FILMS FOR BIOMATERIAL MANIPULATION AND CHARACTERIZATION
S. Xiong¹, Tandiono², K. Ando¹, C. D. Ohl¹, and A. Q. Liu¹, ¹ Nanyang Technological University, SINGAPORE, and ²A*STAR, SINGAPORE

M.1.30

DROPLET-BASED MICROFLUIDIC DEVICE TO ENRICH AND TO SEPARATE HYDROPHOBICALLY FUNCTIONALIZED OLIGONUCLEOTIDE IN FREE-FLOW MICRODROPLETS
W.-F. Fang, C.-W. Hsu, and J.-T. Yang, National Taiwan University, TAIWAN

M.2.31

ENCODED GEL PARTICLE ARRAY FOR RAPID, MULTIPLEXED PROTEIN DETECTION IN COMPLEX MEDIA
R. L. Srinivas¹, D. Shasha², Q. Han¹, S. C. Chapin¹, B. D. Walker², J. C. Love¹, and P. S. Doyle¹, ¹ Massachusetts Institute of Technology, USA, and ²Ragon Institute of MGH, MIT, and Harvard, USA

M.2.32

QCM DETECTION OF MEMBRANE PROTEIN-LIGAND INTERACTIONS USING CELL-DERIVED LIPOSOMES
M. Yamanaka, and T. Yasuda, Kyushu Institute of Technology, JAPAN

M.2.33

EXERCISE- AND DRUG DOSE-DEPENDENT METABOLIC ASSAY DEVICE USING THE HYDROGEL-SUPPORTED SKELETAL MUSCLE CELLS
K. Nagamine^1,2, H. Kaji^1,2, M. Kanzaki^1,2, and M. Nishizawa^1,2, ¹ Tohoku University, JAPAN, and ²JST-CREST, JAPAN

M.2.34

MICRO CONTAINERS WITH SOLID POLYMER DRUG MATRIX FOR ORAL DRUG DELIVERY
J. Nagstrup¹, S. S. Keller¹, A. Müllertz², and A. Boisen¹, ¹ Technical University of Denmark, DENMARK, and ²University of Copenhagen, DENMARK

M.2.35

HIGH THROUGHPUT AND PICOLITER-SCALE DRUG SCREENING WITH AUTOMATED DROPLET MICTROARRAY SYSTEM
Y. Zhu, Y. Zhang, L. Cai, and Q. Fang, Zhejiang University, CHINA

M.2.36

3D TUMOR SPHEROID CHIP USING BALANCED DROPLET DISPENSING FOR PHARMACOKINETIC DRUG ELIMINATION MODEL
T. Kim, I. Doh, H.-J. Jin, and Y.-H. Cho, Korea Advanced Institute of Science and Technology (KAIST), KOREA

M.2.37

CONTINUOUS EXCHANGE OF BUFFERS OVER A LIPID BILAYER MEMBRANE FORMED IN A GLASS MICROFLUIDIC DEVICE
Y. Watanabe^1,3, and S. Takeuchi^1,2, ¹ BEANS Project, JAPAN, ²The University of Tokyo, JAPAN, and ³Olympus Co, JAPAN

M.2.39

HIGH-THROUGHPUT BIOPHYSICAL MEASUREMENT OF HUMAN RED BLOOD CELLS
Y. Zheng¹, E. Shojaei-Baghini¹, A. Azad², C. Wang², and Y. Sun¹, ¹ University of Toronto, CANADA, and ²Mount Sinai Hospital, CANADA

M.2.40

STUDY OF AXON-GUIDANCE INTERACTIONS IN CONTROLLED MICROFLUIDIC ENVIRONMENTS
S. Moorjani, S.-E. Huh, N. Bhattacharjee, and A. Folch, University of Washington, U.S.A

M.2.41

FLEXIBLE PHOSPHORESCENT OXYGEN MICROSENSOR ARRAY DEVICES FOR NONINVASIVE MONITORING OF CELLULAR OXYGEN METABOLISM DURING CULTIVATION
M. Kojima^1,3, H. Takehara^1,2, T. Akagi¹, H. Shiono³, and T. Ichiki¹, ¹ The University of Tokyo, JAPAN, ²Japan Society for the Promotion of Science, JAPAN, and ³Nikon Co., JAPAN

M.2.42

MULTIWELL PLATE READER-COMPATIBLE MICROFLUIDIC SYSTEM FOR LONG-TERM MULTICELLULAR SPHEROID CULTURE AND MONITORING
K. Ziółkowska, M. Rybka, K. Stępień, R. Kwapiszewski, K. Żukowski, M. Chudy, A. Dybko, and Z. Brzózka, Warsaw University of Technology, POLAND

M.2.43

COMBINED MICROFLUIDIC SINGLE-CELL ELECTROPORATION AND IMPEDANCE SPECTROSCOPY ANALYSIS
S. C. Bürgel¹, C. Escobedo¹, S. Kemmerling², N. Sauter², N. Haandbæk¹, O. Frey¹, and A. Hierlemann¹, ¹ ETH Zürich, SWITZERLAND, and ²Universität Basel, SWITZERLAND

M.2.44

REAL-TIME DETECTION OF BACTERIAL BIOFILM GROWTH USING SURFACE PLASMON RESONANCE IMAGING
P. N. Abadian, N. Tandogan, T. A. Webster, and E. D. Goluch, Northeastern University, USA

M.2.45

AN INTEGRATED MICROFLUIDIC PROBE FOR MULTIPLEXED SINGLE CELL KINASE KINASE ACTIVITY MEASUREMENT
A. Sarkar, S. Kolitz, D. A. Lauffenburger, and J. Han, Massachusetts Institute of Technology, USA

M.2.46

CELLJET: LABEL-FREE CELL PRINTING VIA REAL-TIME IMPEDANCE FLOW CYTOMETRY FOR SINGLE CELL ANALYSIS
J. Schoendube¹, D. Wright², A. Yusof¹, R. Zengerle^1,3, and P. Koltay^1,4, ¹ University of Freiburg, GERMANY, ²Zurich Instruments AG, SWITZERLAND, ³HSG-IMIT, GERMANY, and ⁴BioFluidiX GmbH, GERMANY

M.2.47

A MULTIPLE-ELECTRIC-FIELD MICROFLUIDIC CHIP WITH UNIFORM FLOW FIELD FOR STUDY OF LUNG ADENOCARCINOMA CELL ELECTROTAXIS
H.-F. Tsai^1,2, and J.-Y. Cheng^1,2,3, ¹ National Yang-Ming University, TAIWAN, ²Academia Sinica, TAIWAN, and ³National Taiwan Ocean University, TAIWAN

M.2.48

HIGH YIELD CELL FUSION CHIP VIA HYDRODYNAMIC APPROACH AND 3D LIQUID METAL ELECTRODES
H.-P. Chen¹, K.-W. Chang¹, S.-M. Yang², J.-P. Chen¹, C.-W. Lin¹, S. Sivashankar¹, S. V. Puttaswamy¹, Y.-T. Lu³, and C.-H. Liu¹, ¹ National Tsing-Hua University, TAIWAN, ²National Chiao Tung University, TAIWAN, and ³Mackay Memorial Hospital, TAIWAN

M.2.49

SINGLE CELL MICRORNA QUANTIFICATION WITH TWO STEP RT-QPCR BASED ON FLEXIBLE NANOLITER-SCALE DROPLET ARRAY SYSTEM
Y.-X. Zhang, Y. Zhu, Q. Fang, and B. Yao, Zhejiang University, CHINA

M.2.51

CELL ROLLING CYTOMETER FOR CHARACTERIZING DYNAMIC ADHESION OF MESENCHYMAL STEM CELLS
S. Choi¹, O. Levy², M. B. Coelho², J. M. Karp², and R. Karnik¹, ¹ Massachusetts Institute of Technology, USA, and ²Brigham and Women's Hospital and Harvard Stem Cell Institute, USA

M.2.52

FAST TARGET-SELECTIVE CHEMICAL & OPTICAL STIMULATION BASED ON HIGH-THROUGHPUT MULTI-CHANNEL IMAGING DEVICE
H. Lee¹, S. A. Kim¹, G. Aubry¹, P. Mugno², M. Hilliard², and H. Lu¹, ¹ Georgia Institute of Technology, USA, and ²The University of Queensland, AUSTRALIA

M.2.53

MICROFLUIDIC INTEGRATED OPTOELECTRONIC TWEEZERS FOR SINGLE-CELL SAMPLE PREPARATION AND ANALYSIS
K.-W. Huang, Y.-C. Wu, S. Sattar, J.-A. Lee, and P.-Y. Chiou, University of California, Los Angeles, USA

M.2.54

LARGE SCALE ANALYSIS OF MAMMALIAN AXON GUIDANCE AND NEURON POLARIZATION USING ARRAYS OF MICROFLUIDIC GRADIENT GENERATORS
N. Bhattacharjee, and A. Folch, University of Washington, USA

M.2.55

MESENCHYMAL STEM CELLS PROMOTE THE INVASION IN SALIVARY GLAND CANCER ON THE BIOMIMETIC MICROSYSTEM
H. Ma, and J. Qin, Dalian Institute of Chemical Physics, CHINA

M.2.56

HYDRODYNAMIC EFFECTS ON DEVELOPMENT OF MAT-LIKE BIOFILM IN A MICROFLUIDIC ENVIRONMENT
J. Kim, S. Han, S. Chung, and H.-D. Park, Korea University, KOREA

M.2.57

UNRAVELING MECHANO-STRESS RESPONSIVE SIGNALING NETWORKS IN BUDDING YEAST VIA MICROFLUIDIC DEVICES
S. Oh¹, S. S. Lee², H. R. Ryu¹, J. W. Park¹, M. Peter², and N. L. Jeon¹, ¹ Seoul National University, KOREA, and ²ETH Zurich, SWITZERLAND

M.2.58

A CONTROLLED-RELEASE CAPSULE DEVICE FOR TRANSSCLERAL DRUG DELIVERY TO THE RETINA
H. Kaji^1,2, N. Nagai¹, T. Yamada², M. Nishizawa^1,2, and T. Abe¹, ¹ Tohoku University, JAPAN, and ²ST, CREST, JAPAN

M.2.59

ELASTOMERIC PILLAR ARRAYS FOR INTEGRATED MEASUREMENT OF C. ELEGANS LOCOMOTION FORCES
S. Johari¹, V. Nock², M. M. Alkaisi², and W. Wang^1,2,3, ¹ University of Canterbury, NEW ZEALAND, ²The MacDiarmid Institute for Advanced Materials and Nanotechnology, NEW ZEALAND, and ³Tsinghua University, CHINA

M.2.61

SIZE BASED NANOPARTICLE SEPARATION USING DIELECTROPHORETIC FOCUSING FOR FEMTOSECOND NANOCRYSTALLOGRAPHY OF MEMBRANE PROTEINS
B. Abdallah, T.-C. Chao, P. Fromme, and A. Ros, Arizona State University, USA

M.2.62

SMALL VOLUME HYPERMETHYLATED DNA ENRICHMENT FOR EPIGENETICS
A. de, W. Sparreboom, L. de Vreede, E. T. Carlen, and A. van den Berg, University of Twente, THE NETHERLANDS

M.2.63

PLASMA SEPARATION FROM HUMAN BLOOD USING SPIRAL MICROCHANNELS FOR DRY EYE TREATMENT
J. Morikawa¹, T. Yasui¹, N. Kaji¹, Y. Okamoto¹, M. Tokeshi^1,2, K. Tsubota³, and Y. Baba^1,4, ¹ Nagoya University, JAPAN, ²Hokkaido University, JAPAN, ³Keio University, JAPAN, and ⁴National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

M.3.64

SURFACE ENERGY TRAP ASSISTED RAPID SERIAL DILUTION ON DROPLET PLATFORM FOR BACTERIA ANTIBIOTICS SUSCEPTIBILITY TEST
Y. Zhang, and T.-H. Wang, Johns Hopkins University, USA

M.3.65

REVERSIBLY-ASSEBMLED PERFUSION CULTURE CHIP WITH MICROWELL ARRAY FOR CONTROLLABLE SPHEROID CULTURE AND POST-CULTURE ANALYSIS
S. Sugiura¹, K. Hattori¹, Y. Sakai^2,3, K. Nakazawa², and T. Kanamori¹, ¹ National Institute of Advanced Industrial Science and Technology (AIST), JAPAN, ²The University of Kitakyushu, JAPAN, and ³Japan Society for the Promotion of Science (JSPS), JAPAN

M.3.66

MICRO IN-FOCAL CELL STRETCHING PLATFORM WITH PARALLEL PROGRAMMABLE CONTROL
Y. Huang¹, and N.-T. Nguyen^1,2, ¹ Nanyang Technological University, SINGAPORE, and ²Mechanobiology Institute, SINGAPORE

M.3.67

COMBINATION OF HYDROSTATIC PRESSURE AND SHEAR STRESSES CONTRIBUTE TO ENDOTHELIAL CELL GROWTH IN A MICROFLUIDIC DEVICE
M.-C. Liu¹, H.-C. Shih¹, T.-W. Weng², C.-Y. Wu¹, and Y.-C. Tung¹, ¹ Academia Sinica, TAIWAN, and ²National Taiwan University, TAIWAN

M.3.68

A PERFUSION 3D CELL CULTURE BIOCHIP WITH ON-CHIP VERTICAL ELECTRODES FOR DETECTING CELL NUMBER BY ELECTRICAL IMPEDANCE MEASUREMENT
C.-W. Hsu, K. F. Lei, C.-Y. Lin, and M.-H. Wu, Chang Gung University, TAIWAN

M.3.69

MICROFLUIDIC SUSPENSION CELL CULTURE PLATFORM FOR STUDYING POPULATION HETEROGENEITY IN NF-KB SIGNALING
E. W. K. Young, C. Pak, S. Miyamoto, and D. J. Beebe, University of Wisconsin-Madison, USA

M.3.70

FABRICATION OF A CIRCULAR PDMS MICROCHANNEL TO CONSTRUCT 3D CULTURE MICROSYSTEM
J. S. Choi, Y. Piao, and T. S. Seo, KAIST, KOREA

M.3.71

RAPID CONSTRUCTION OF MULTILAYERED TISSUES ON CURVED SUBSTRATE BY WATER TRANSFER PRINTING
T. Masuda¹, N. Takei¹, H. Owaki¹, M. Matsusaki², M. Aakashi², and F. Arai¹, ¹ Nagoya University, JAPAN, and ²Osaka University, JAPAN

M.3.72

A PARALLEL ARRAY MICROFLUIDIC BLOOD-BRAIN BARRIER MODEL FOR HIGH-THROUGHPUT QUANTITATION OF SHEAR STRESS EFFECTS
R. H. Booth, and H. Kim, University of Utah, USA

M.3.73

BIO-INSPIRED MICROSCALE TOPOGRAPHIES ON DRIE DEFINED TITANIUM SURFACE FOR SOFT TISSUE REGENERATION IN IMPLANT DENTISTRY
F. Mao, N. Li, S. Chen, Y. Zhang, S. He, S. Wei, and J. Chen, Peking University, CHINA

M.3.74

ANALYSIS OF TRAPPING AND STREAMING IN AN ULTRASOUND-ACTUATED MULTI-WELL MICROPLATE FOR SINGLE-CELL STUDIES
M. Ohlin, A. E. Christakou, T. Frisk, B. Önfelt, and M. Wiklund, Royal Institute of Technology, SWEDEN

M.3.75

UNIFORM AND HIGH THROUGHPUT AGAROSE GEL MICRO DROPLET GENERATION DEVICE FOR SINGLE CELL ANALYSIS
T. Hirose, Y. Hoshino, D. H. Yoon, A. Nakahara, T. Mori, T. Sekiguchi, H. Takeyama, and S. Shoji, Waseda University, JAPAN

M.3.76

MICRODEVICE FOR STUDYING INTERCELLULAR MECHANICAL TRANSDUCTION
Q. Wang, and Y. Zhao, The Ohio State University, USA

M.3.77

HIGH-THROUGHPUT MUTAGENIZED CELL SCREENING SYSTEM CAPABLE OF SELECTIVE SINGLE CELL EXTRACTION
H. S. Kim, T. L. Weiss, T. P. Devarrenne, and A. Han, Texas A&M University, USA

M.3.78

PHOTO-ASSISTED MICRO-GLUING FOR ASSEMBLING THREE-DIMENSIONAL MICROSTRUCTURES WITH LIVING CELLS
S. Yoshida¹, K. Sato^1,2, K. Kuribayashi-Shigetomi¹, T. Teshima¹, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²Japan Science and Technology (JST), JAPAN

M.3.79

HUNDRED-FOLD VOLUME CONCENTRATION OF CELLS AND PARTICLES USING CONTINUOUS FLOW MULTISTAGE ACOUSTOPHORESIS
M. Nordin¹, and T. Laurell^1,2, ¹ Lund University, SWEDEN, and ²Dongguk University, KOREA

M.3.80

ACOUSTIC TRAPPING EFFICIENCY OF NANOPARTICLES AND BACTERIA
M. Evander, B. Hammarström, P. Ohlsson, T. Laurell, and J. Nilsson, Lund University, SWEDEN

M.3.81

HIGH RESOLUTION SIZE BASED MICRO PARTICLE/CELL SEPARATOR WITH TRAPEZOIDAL CROSS SECTION SPIRAL MICROCHANNELS
G. Guan^1,2, A. A. Bhagat², L. Wu³, Z. Li^2,4, C. J. Ong¹, P. C. Y. Chen^1,2, and J. Han^2,3, ¹ National University of Singapore, SINGAPORE, ²Singapore-MIT Alliance for Research and Technology (SMART), SINGAPORE, ³Massachusetts Institute of Technology, USA, and ⁴Wenzhou University, CHINA

M.3.82

A MASS-PRODUCIBLE FILTRATION CHIP FOR ISOLATION OF CIRCULATING TUMOR CELLS FROM HUMAN BLOOD
C.-M. Lin, P.-C. Chuang, C.-Y. Chen, C.-L. Chen, G.-S. Huang, and A. M. Wo, National Taiwan University, TAIWAN

M.3.83

LABEL-FREE ISOLATION OF CIRCULATING TUMOR CELLS (CTCs) FROM BREAST CANCER PATIENTS USING PARALLEL MULTI-ORIFICE FLOW FRACTIONATION (p-MOFF)
K.-A. Hyun, J.-H. Lee, S.-I. Kim, and H.-I. Jung, Yonsei University, KOREA

M.3.84

DEVELOPMENT OF A MULTI-COMPARTMENT MICROFILTRATION DEVICE FOR PARTICLE FRACTIONATION
M.-C. Lo, and J. D. Zahn, Rutgers University, USA

M.3.85

A HIGH-THROUGHPUT DETERMINISTIC LATERAL DISPLACEMENT DEVICE FOR RAPID AND SENSITIVE FIELD-DIAGNOSIS OF SLEEPING SICKNESS
S. H. Holm¹, J. P. Beech¹, M. P. Barrett², and J. O. Tegenfeldt^1,3, ¹ Lund University, SWEDEN, ²University of Glasgow, UK, and ³University of Gothenburg, SWEDEN

M.3.86

CONTINUOUS RARE CELL EXTRACTION USING SELF-RELEASING VORTEX IN AN INERTIAL MICROFLUIDIC DEVICE
X. Wang, J. Zhou, and I. Papautsky, University of Cincinnati, USA

M.3.87

QUANTITATIVE ANALYSIS OF DEFORMABILITY-BASED CELL SEPARATION USING DETERMINISTIC LATERAL DISPLACEMENT AND OPTICAL STRETCHING
D. Holmes¹, G. Whyte², A. Ekpenyong³, J. Guck^3,4, and T. Duke¹, ¹ University College London, UK, ²Friedrich-Alexander Universitat, GERMANY, ³University of Cambridge, UK, and ⁴TU Dresden, GERMANY

M.3.88

HIGH-EFFECIENCY BLOOD CELL SEPARATION USING STANDING SURFACE ACOUSTIC WAVES
X. Ding¹, L. Wang², and T. J. Huang¹, ¹ The Pennsylvania State University, USA, and ²Ascent Bio-Nano Technologies Inc. State College, USA

M.3.89

3D PULSED LASER TRIGGERED HIGH SPEED MICROFLUIDIC FLUORESCENCE ACTIVATED CELL SORTER
Y. Chen, T.-H. Wu, Y.-C. Kung, and P.-Y. Chiou, University of California, Los Angeles, USA

M.3.90

SIZE BASED PARTICLE SEPARATION USING ACOUSTIC MICROSTREAMING AND ALCAT PUMPS
M. V. Patel, A. Doria, A. R. Tovar, and A. P. Lee, University of California, Irvine, USA

M.3.91

APPLYING MICRODROPLETS AS SENSORS
T. W. Hofmann, S. Rausch, S. Hänselmann, J.-W. Janiesch, C. Nguyen, C. H. J. Böhm, and H. Böhm, Max Planck Institute for Intelligent Systems, and Heidelberg University, GERMANY

M.3.92

MULTISTEP BRANCHED-MICROCHANNEL NETWORK FOR PURITY-CONTROLLED BLOOD PLASMA SKIMMING
K. Morimoto¹, T. Ito², and S. Konishi², ¹ The University of Tokyo, JAPAN, and ²Ritsumeikan University, JAPAN

M.3.93

DYNAMIC THREE-DIMENSIONAL MICROPATTERNED COCULTURE USING PHOTOCURABLE AND CHEMICALLY DEGRADABLE HYDROGELS FOR STEM CELL DIFFERENTIATION
S. Sugiura^1,2,3, J. M. Cha^1,2, F. Yanagawa^1,2, P. Zorlutuna^1,2, H. Bae^1,2, and A. Khademhosseini^1,2,4, ¹ Brigham and Women's Hospital, Harvard Medical School, USA, ²Massachusetts Institute of Technology, USA, ³National Institute of Advanced Industrial Science and Technology (AIST), JAPAN, and ⁴Wyss Institute for Biologically Inspired Engineering, Harvard University, USA

M.3.94

MICROFLUIDICS-BASED FORMATION OF HETEROGENEOUS HYDROGEL SHEETS FOR HIGH-DENSITY COCULTURE OF MULTIPLE CELL TYPES
A. Kobayashi, K. Yamakoshi, Y. Yajima, M. Yamada, and M. Seki, Chiba University, JAPAN

M.3.95

DIGITAL MICROFLUIDIC PLATFORM FOR THE CREATION, MAINTENANCE AND ASSAY OF LIVER-LIKE ORGANOIDS
S. H. Au, S. Mahesh, and A. R. Wheeler, University of Toronto, CANADA

M.3.96

BONE MARROW-ON-A-CHIP
Y. Torisawa¹, C. S. Spina^1,2, J. J. Collins^1-3, and D. E. Ingber^1,4, ¹ Harvard University, USA, ²Boston University School of Medicine, USA, ³Boston University, USA, and ⁴Harvard Medical School, USA

M.3.97

ENCAPSULATION OF CELLS TO FEIGN VASCULAR NETWORK FOR LIVER TISSUE ENGINEERING
S. Sivashankar¹, S. V. Puttaswamy¹, K.-W. Chang¹, H.-P. Chen¹, S.-M. Yang², and C.-H. Liu¹, ¹ NTHU, TAIWAN, and ²NCTU, TAIWAN

M.3.98

CELL-LADEN MICROGELS ASSEMBLY BY DIELECTROPHORESIS
M.-R. Yang¹, M.-Y. Chiang¹, and S.-K. Fan², ¹ National Chiao Tung University, TAIWAN, and ²National Taiwan University, TAIWAN

M.3.99

CONSTRUCTION OF VASCULAR TISSUES VIA MULTILAYER CELL DEPOSITION INSIDE HYDROGEL MICROCHANNELS
M. Iwase, M. Yamada, and M. Seki, Chiba University, JAPAN

M.3.100

GENERATION AND ASSEMBLY OF CELL-LADEN HYDROGELS ON A DIGITAL MICROFLUIDIC PLATFORM
M.-Y. Chiang¹, and S.-K. Fan², ¹ National Chiao Tung University, TAIWAN, and ²National Taiwan University, TAIWAN

M.3.101

TUNABLE CELL LYSING OF DENSE BLOOD CELL SAMPLES WITH AIR-LIQUID CAVITY ACOUSTIC TRANSDUCERS
A. Doria, N. E. Martin, and A. P. Lee, University of California - Irvine, USA

M.3.102

QUANTITATIVE ANALYSIS OF GENE EXPRESSION LEVEL OF INDIVIDUAL iPS CELLS BY USING ELECTROACTIVE MICROWELL ARRAY
S. H. Kim^1,2, X. He^1,2, S. Kaneda^1,2, J. Kawada^1,2, D. Fourmy³, H. Noji^1,2, and T. Fujii^1,2, ¹ University of Tokyo, JAPAN, ²CREST, JST, JAPAN, and ³CNRS, FRANCE

M.4.104

DRY REAGENT PAPER-COUPLED ELECTROPHORESIS MICROCHIP TOWARDS MULTI ASSAY OF BIOLOGICAL COMPONENTS
Y. Miyahara, N. Funauchi, T. Endo, and H. Hisamoto, Osaka Prefecture University, JAPAN

M.4.105

FAST ANALYSIS OF BIOLOGICAL COMPOUNDS BY GRADIENT LIQUID CHROMATOGRAPHY USING PILLAR ARRAY COLUMN
Y. Song¹, M. Noguchi², K. Takatsuki², T. Sekiguchi², J. Mizuno², T. Funatsu¹, S. Shoji², and M. Tsunoda¹, ¹ University of Tokyo, JAPAN, and ²Waseda University, JAPAN

M.4.106

EFFECT OF BLOOD CELL SEDIMENTATION ON IMMUNOMAGNETIC ISOLATION OF CIRCULATING TUMOR CELLS IN MICROFLUIDIC CHANNELS
P. Chen, K. Hoshino, Y.-Y. Huang, and X. Zhang, University of Texas at Austin, USA

M.4.108

MICROFLUIDIC EXTRACTION OF RNA FROM BLOOD
A. Rogacs, and J. G. Santiago, Stanford University, USA

M.4.109

FLOW FIELD EFFECT TRANSISTOR WITH POLARISABLE INTERFACE FOR ENHANCED SAMPLE SORTING IN MICRO-TAS
S. Méance¹, A. Plecis², S. Chebil¹, S. Korchane^3,4, I. Charhrouchni¹, A. Pallandre^3,4, and A.-M. Haghiri-Gosnet¹, ¹ Laboratoire de Photonique et de Nanostructures, FRANCE, ²Elvesys, Pépinière Paris Santé Cochin, FRANCE, ³Univ Paris-Sud, FRANCE, and ⁴Institut Galien Paris-Sud, FRANCE

M.4.110

SUB-MILLISECOND SEPARATION OF DNA AND MICRO-RNA BY NANOPILLAR ARRAY CHIPS
Q. Wu¹, K. Motoyama¹, T. Yasui¹, S. Rahong², T. Yanagida², M. Kanai², Y. Okamoto¹, N. Kaji¹, M. Tokeshi^1,3, K. Nagashima², T. Kawai², and Y. Baba^1,4, ¹ Nagoya University, JAPAN, ²Osaka University, JAPAN, ³Hokkaido University, JAPAN, and ⁴National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

M.4.111

CREATION OF A CELL-BASED SEPARATION MICRODEVICE USING HUMAN RENAL PROXIMAL TUBULE EPITHELIAL CELLS
X. Gao¹, K. Mawatari¹, Y. Kazoe¹, Y. Tanaka², and T. Kitamori¹, ¹ The University of Tokyo, JAPAN, and ²Riken, JAPAN

M.4.112

VIRUS DETECTION BY ON-CHIP HYDROXYAPATITE CHROMATOGRAPHY
M. Niimi¹, T. Masuda¹, K. Kaihatsu², N. Kato², and F. Arai¹, ¹ Nagoya University, JAPAN, and ²Osaka University, JAPAN

M.4.113

A CHEMICAL OSCILLATOR IN A NANO-LITER SCALE MICROFLUIDIC OPEN REACTOR
J.-C. Galas, and A. Estevez-Torres, Laboratory for Photonics and Nanostructures, FRANCE

M.4.114

AN INTEGRATED MICROSYSTEM FOR ALLELE-SPECIFIC PCR AMPLIFICATION OF GENOMIC DNA DIRECTLY FROM HUMAN BLOOD
B. Jones¹, H. Tanaka^1,2, S. Peeters¹, P. Fiorini¹, B. Majeed¹, L. Zhang^1,3, and I. Yamashita², ¹ imec, BELGIUM, ²Panasonic Corporation, JAPAN, and ³KU Leuven, BELGIUM

M.4.115

A MICROFLUIDIC-BASED THERMAL DIGESTION CHIP FOR DISSOLVED ORGANIC NITROGEN DETECTION
J. Tong, T. Dong, C. Bian, J. Sun, and S. Xia, Chinese Academy of Sciences, CHINA

M.4.116

MULTI-STEP ORGANIC SYNTHESIS OF FOUR DIFFERENT MOLECULAR PROBES IN DIGITAL MICROFLUIDIC DEVICES
H.-K. Kim, S. Chen, M. R. Javed, J. Lei, C.-J. "CJ" Kim, P. Y. Keng, and R. M. van Dam, University of California, Los Angeles, USA

M.4.117

ELECTROKINETICALLY ACTUATED, HEATED MICROREACTOR FOR METABOLOMICS
T. Sikanen¹, M.-E. Moilanen¹, S. Aura², T. Kotiaho¹, S. Franssila², and R. Kostiainen¹, ¹ University of Helsinki, FINLAND, and ²Aalto University, FINLAND

M.4.118

STRAIGHTFORWARD MODULATION OF TWO DIMENSIONALLY FEATURED MICROFIBERS USING OPTOFLUIDIC SYSTEM FOR MULTIPLEX IMMUNOASSAYS
S. Cho^1,2, T. S. Shim^1,2, and S.-M. Yang^1,2, ¹ KAIST, KOREA, and ²National Creative Research Initiative Center for Integrated Optofluidic Systems, KOREA

M.4.119

DROPLET MICROFLUIDICS WITH INTEGRATED GAS-PERMEABLE MEMBRANES FOR NANOMATERIALS SYNTHESIS WITH REACTIVE GASES
P. G. Krishnamurthy¹, M. T. Rahman³, P. Parthiban¹, A. Jain¹, C. P. Park⁴, D.-P. Kim⁵, and S. A. Khan^1,2, ¹ National University of Singapore, SINGAPORE, ²Singapore-MIT Alliance, SINGAPORE, ³The Queen's University of Belfast, UK, ⁴Chungnam National University, KOREA, and ⁵POSTECH, KOREA

M.4.120

SOLID-PHASE [¹⁸F]FLOURINATION ON A FLOW-THROUGH GLASS MICROFLUIDIC CHIP
R. Ismail, A. Machness, R. M. van Dam, and P. Y. Keng, University of California, Los Angeles, USA

M.4.121

CONTINUOUS FLOW "RAIL-AND-TRAP" MICROFLUIDIC PROCESSORS FOR AUTONOMOUS BEAD-BASED MIXING AND VISUALIZATION
R. D. Sochol, W. E. R. Krieger, M. Liu, S. Hesse, J. Lei, L. P. Lee, and L. Lin, University of California, Berkeley, USA

M.4.122

PORTABLE AUTOMATED OSMOLALITY AND pH ADJUSTING APPARATUS FOR PRETREATMENT OF ENVIRONMENTAL WATER SAMPLES DELIVERED INTO A CELL-BASED BIOSENSOR
S. Talaei¹, Y. Fujii², F. Truffer³, P. D. van der Wal¹, and N. F. de Rooij¹, ¹ Ecole Polytechnique Fédérale de Lausanne (EPFL), SWITZERLAND, ²University of Tokyo, JAPAN, and ³University of Applied Sciences (HES-SO), SWITZERLAND

M.4.123

MEMS VISCOSITY SENSOR USING DUAL SPIRAL SHAPED VIBRATING STRUCTURE
Y. Yamamoto¹, S. Matsumoto¹, H. Yabuno², M. Kuroda¹, K. Fujii¹, and T. Yamamoto¹, ¹ National Institute of Advanced Industrial Science and Technology (AIST), JAPAN, and ²Keio University, JAPAN

M.4.124

FLOW-THROUGH MICROFLUIDIC DIGITAL IMPEDANCE DETECTION
V. Liang, S. Woo, C. Wu, S. Cheung, S. Sadeghi, and R. M. van Dam, University of California, Los Angeles (UCLA), USA

M.5.125

FABRICATION OF MONO-DISPERSED SPHERICAL ASSEMBLIES AND THESE STRUCTURAL COLORS BY USING MICROFLOW DEVICE
M. Teshima¹, Y. Takeoka¹, T. Seki¹, R. Kawano², S. Yoshioka³, and S. Takeuchi⁴, ¹ Nagoya University, JAPAN, ²Kanagawa Academy of Science and Technology, JAPAN, ³Osaka University, JAPAN, and ⁴The University of Tokyo, JAPAN

M.5.126

3D MICROCOIL FABRICATED ON THE CAPILLARY SURFACE BY CYLINDRICAL PROJECTION LITHOGRAPHY FOR NMR APPLICATION
Z. Yang^1,2, S. Uchiyama^1,3, Y. Zhang¹, M. Hayasei³, T. Itoh¹, and R. Maeda¹, ¹ National Institute of Advanced Industrial Science and Technology (AIST), JAPAN, ²Shanghai Jiao Tong University, CHINA, and ³Tokyo University of Science, JAPAN

M.5.127

DEVELOPMENT OF GATING NANOPORE TOWARDS SINGLE-BIOMOLECULE ELECTRICAL IDENTIFICATION
Y. Sasaki, T. Ohshiro, S. Kawano, M. Taniguchi, and T. Kawai, Osaka University, JAPAN

M.5.128

SIMPLE AND LOW-COST FABRICATION PROTOCOL FOR PRODUCING 100'S OF PNEUMATIC MICROVALVES IN ALL-PDMS SUBSTRATES FOR MICROFLUIDICS RESEARCH
R. Samuel, C. Thacker, A. V. Maricq, and B. K. Gale, University of Utah, USA

M.5.129

ONE-STEP MULTI-DEPTH POLYSTYRENE MOLDS FOR PDMS SOFT-LITHOGRAPHY THROUGH LASER-INDUCED BUMPING
H. Li, Y. Fan, and I. G. Foulds, King Abdullah University of Science and Technology (KAUST), SAUDI ARABIA

M.5.130

A DOUBLE-SIDED MICROMOULDING PROCESS FOR REPRODUCIBLE MANUFACTURING OF THIN LAYERS AND 3D MICROCHANNELS IN PDMS
J. M. Karlsson, T. Haraldsson, C. F. Carlborg, and W. van der Wijngaart, KTH Royal Institute of Technology, SWEDEN

M.5.131

A HIGHLY EFFICIENT 3D MICROMIXER FABRICATED BY STANDARD SOFT-LITHOGRAPHY EQUIPMENT
T. Naito¹, R. Arayanarakool², N. Kaji¹, S. Le Gac², M. Tokeshi³, A. van den Berg², and Y. Baba^1,4, ¹ Nagoya University, JAPAN, ²University of Twente, THE NETHERLANDS, ³Hokkaido University, JAPAN, and ⁴National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

M.5.132

FAST AND VERSATILE FABRICATION OF PDMS NANOWRINKLING STRUCTURES
K. Wei, and Y. Zhao, The Ohio State University, USA

M.5.134

THIN FILM PATTERNING USING A WATER-SOLUBLE ETCH MASK
S. M. Grist, L. Chrostowski, and K. C. Cheung, The University of British Columbia, CANADA

M.5.135

A PHOTODEGRADABLE HYDROGEL SHEET FOR MICROSCALE OPTICAL CONTROL OF CELL ADHESION AND DETACHMENT
S. Sugiura, T. Takagi, M. Yamaguchi, K. Sumaru, and T. Kanamori, National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

M.5.136

COMPLEX MODULUS OF PDMS AND ITS APPLICATION IN CELLULAR FORCE MEASUREMES
P. Du¹, C. Cheng², H. Lu², and X. Zhang¹, ¹ Boston University, USA, and ²University of Texas at Dallas, USA

M.5.137

RAPID PERMANENT HYDROPHILIC AND HYDROPHOBIC PATTERNING OF POLYMER SURFACES VIA OFF-STOICHIOMETRY THIOL-ENE (OSTE) PHOTOGRAFTING
C. F. Carlborg, F. Moraga, F. Saharil, W. van der Wijngaart, and T. Haraldsson, KTH Royal Institute of Technology, SWEDEN

M.5.138

MICROCHANNEL FABRICATION BY USE OF PHOTOACID-GENERATOR-TETHERED GEL
T. Satoh, K. Sumaru, T. Takagi, and T. Kanamori, National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

M.5.139

RAPID PERFUSION SYSTEM FOR INHIBITION INVESTIGATION OF MEMBRANE PROTEINS IN PLANAR LIPID BILAYER
Y. Tsuji^1,3, R. Kawano¹, T. Osaki¹, K. Kamiya¹, N. Miki^1,3, and S. Takeuchi^1,2, ¹ Kanagawa Academy of Science and Technology, JAPAN, ²The University of Tokyo, JAPAN, and ³Keio University, JAPAN

M.5.140

MICROFLUIDIC POLYIMIDE CHIPS FABRICATED BY LAMINATION PROCESSES FOR X-RAY SCATTERING APPLICATIONS
G. Perozziello^1,2, R. Catalano¹, G. Simone³, P. Candeloro¹, N. Malara¹, S. Santoriello⁴, R. La Rocca⁴, F. De Angelis⁴, A. Accardo⁴, M. Burghammer⁵, E. Di Cola⁵, G. Cuda^1,2, C. Riekel⁵, and E. Di Fabrizio^4,1, ¹ University of Catanzaro, ITALY, ²Biotecnomed Scarl, ITALY, ³Univerity of Naples (Federico II), ITALY, ⁴Italian Institute of Technology, ITALY, and ⁵European Synchrotron Radiation Facility, FRANCE

M.5.142

THERMAL BONDING OF POLYMER MICRODEVICES USING A PRESSURE-ASSISTED BOILING POINT CONTROL SYSTEM
T. Park¹, I.-H. Song², D. S. Park¹, B. H. You², and M. C. Murphy¹, ¹ Louisiana State University, USA, and ²Texas State University, USA

M.5.143

CELLULAR MECHANICAL IMEPEDANCE MEASUREMENT BY ROBOT INTEGRATED MICROFLUIDIC CHIP WITH WIDTH TUNABLE MICROCHANNEL
S. Sakuma¹, M. Kaneko², and F. Arai¹, ¹ Nagoya University, JAPAN, and ²Osaka University, JAPAN

M.5.144

DEFORMABLE-CHANNEL CLOSED-LOOP MICROFLUIDIC PLATFORM FOR CONTINUOUS AND CONSTANT-PRESSURE FLUID CIRCULATION
H.-T. Kim, J. Son, and H. Kim, University of Utah, USA

M.5.145

MICROFLUIDIC GLUCOSE DETECTION WITH AN LASER-INDUCED FLUORESCENCE DETECTION DEVICES
T. Kamei, S. Ito, M. Ogiso, R. Takigawa, K. Sumitomo, T. Kobayashi, and R. Maeda, National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

M.6.146

DEVELOPMENT OF DIELECTRIC CONSTANT MEASUREMENT METHOD FOR UNIQUE REACTION IN EXTENDED-NANO SPACE
K. Morikawa¹, Y. Kazoe¹, K. Mawatari¹, T. Tsukahara², and T. Kitamori¹, ¹ The University of Tokyo, JAPAN, and ²Tokyo Institute of Technology, JAPAN

M.6.147

SELF-REGENERATING PHOTOCATALYTIC SENSOR BASED ON DIELECTROPHORETICALLY ASSEMBLED TiO₂ NANOWIRES FOR POLLUTANT VAPOR SENSING
S. Wang, Z.-X. Lin, C. L. Kuo, K. C. Hwang, and C.-C. Hong, National Tsing Hua University, TAIWAN

M.6.148

INTRANEURONAL TRANSPORT IN VITRO: DEVELOPMENT OF A HIGHLY SENSITIVE MICROTUBULE BASED ASSAY
M. C. Tarhan¹, Y. Orazov¹, R. Yokokawa^2,3, S. L. Karsten⁴, and H. Fujita¹, ¹ The University of Tokyo, JAPAN, ²Kyoto University, JAPAN, ³JST, JAPAN, and ⁴NeuroInDx, Inc., USA

M.6.149

SINGLE CELL-LIPOSOME FUSION FOR DELIVERY OF MOLECULES INTO THE CYTOSOL
P. Kuhn, K. Eyer, and P. S. Dittrich, ETH Zurich, SWITZERLAND

M.6.150

PATTERNING OF BIOMOLECULES IN EXTENDED NANOCHANNEL USING LOW-TEMPERATURE BONDING
K. Shirai¹, K. Mawatari^1,2, and T. Kitamori^1,2, ¹ The University of Tokyo, JAPAN, and ²CREST, Japan Science and Technology Agency, JAPAN

M.6.151

COLORIMETRIC SCREENING OF OLIGONUCLEOTIDE BASED ON THE HYBRIDIZATION-MEDIATED GROWTH SIZE OF GOLD NANOPARTICLE PROBES
W.-F. Fang, and J.-T. Yang, National Taiwan University, TAIWAN

M.6.152

ELECTRODE NANOGAP ENHANCED AND DIELECTROPHORESIS-ENABLED RAMAN SPECTROSCOPY OF SINGLE BIOMOLECULES WITH SIMULTANEOUS REAL-TIME ELECTRONIC MONITORING
L. Lesser-Rojas^1,2, A. Erbe³, P. Ebbinghaus³, M.-L. Chu¹, and C.-F. Chou¹, ¹ Academia Sinica, TAIWAN, ²National Tsing Hua University, TAIWAN, and ³Max-Planck-Institut für Eisenforschung GmbH, GERMANY

M.6.153

DEVELOPMENT OF METHOD FOR SIMULTANEOUS MEASUREMENT OF VISCOSITY AND SURFACE TENSION FORCE IN BIO-MIMETIC EXTENDED-NANO SPACE
L. Li, Y. Kazoe, K. Mawatari, Y. Sugii, and T. Kitamori, The University of Tokyo, JAPAN

M.6.154

WASHING-FREE ALL-IN-ONE IMMUNOSTAINING REACTION OF MULTI-STEP QUANTUM DOT LABELING REAGENTS
S. Kwon, C. H. Cho, and J.-K. Park, KAIST, KOREA

M.6.155

MICROFLUIDIC SYNTHESIS OF MULTI-LAYER NANOPARTICLES FOR DRUG & GENE DELIVERY
P. Chan, A. Qi, A. R. Semper, J. Friend, and L. Yeo, RMIT University, AUSTRALIA

M.7.156

INTRAOCULAR PRESSURE SENSORS: NEW APPROACHES FOR REAL-TIME INTRAOCULAR PRESSURE MEASUREMENT USING A PURELY MICROFLUIDIC CHIP
K.-M. Lin, H. J. Sant, B. K. Ambati, and B. K. Gale, University of Utah, USA

M.7.158

DEVELOPMENT OF OPTO-CHEMICAL MICROSCOPE SYSTEM FOR SPATIO-TEMPORAL ANALYSIS OF SIGNALS IN SELF-ORGANIZED NEURONS
T. Sakurai^1,2, H. Taki¹, J. Nishimoto¹, K. Takahashi^1,2, M. Ishida^1,2, K. Okumura^1,2, and K. Sawada^1,2, ¹ Toyohashi University of Technology, JAPAN, and ²JST CREST, JAPAN

M.7.159

ePetri PLATFORM FOR CONTINUOUS ON-CHIP MONITORING OF MICROORGANISMS
S. A. Lee, G. Zheng, N. Mukherjee, and C. Yang, California Institute of Technology, USA

M.7.160

VACUUM FLOW FOCUSING MICROFLUIDICS TO STUDY BLOOD CELL DYNAMICS UNDER SHEAR GRADIENT AGGREGATION MECHANISM
F. J. Tovar-Lopez¹, M. Nasabi¹, V. Sivan¹, K. Khoshmanesh^1,3, S. Jackson², G. Rosengarten¹, A. Mitchell¹, and W. S. Nesbitt², ¹ RMIT University, AUSTRALIA, ²Monash University, AUSTRALIA, and ³Standford University, USA

M.7.161

DESIGN OF OPTO-MECHANICALMICRO TRANSCUCER FOR CELL CULTURE AND IN PLANE FORCE MEASUREMENT
X. Zheng, and X. Zhang, Boston University, USA

M.7.162

LABEL-FREE THROMBIN DETECTION IN A MICROCHANNEL USING AN APTAMER MODIFIED GRAPHENE OXIDE SURFACE
Y. Ueno, K. Furukawa, S. Inoue, K. Hayashi, H. Hibino, and E. Tamechika, NTT Corporation, JAPAN

M.7.163

BACTERIAL SENSING USING PHAGE-FUNCTIONALIZED WHISPERING GALLERY MICROCAVITIES
H. Ghali¹, P. Bianucci¹, H. Chibli², J. L. Nadeau², and Y.-A. Peter¹, ¹ École Polytechnique de Montréal, CANADA, and ²McGill University, CANADA

M.7.164

HIGH-THROUGHPUT ANALYSIS OF PROTEIN-PROTEIN INTERACTIONS IN DROPLET-BASED MICROFLUIDICS USING FLUORESCENCE POLARIZATION
J.-W. Choi¹, D.-K. Kang², H. Park¹, A. J. deMello³, and S.-I. Chang¹, ¹ Chungbuk National University, KOREA, ²University of California at Irvine, USA, and ³ETH Zürich, SWITZERLAND

M.7.165

DUAL FORCE AGGREGATION OF MAGNETIC PARTICLES FOR LABEL-FREE DETECTION AND QUANTIFICATION OF DNA THROUGH IMAGE ANALYSIS
D. A. Nelson, B. C. Strachan, H. S. Sloane, J. Li, and J. P. Landers, University of Virginia, USA

M.7.166

GLASS NANOPILLAR ARRAY BASED NANOPLASMONIC LAB-ON-A-CHIP FOR HIGHLY SENSITIVE SURFACE ENHANCED RAMAN SPECTROSCOPY
Y.-J. Oh, J.-J. Kim, and K.-H. Jeong, KAIST, KOREA

M.7.167

A NEW SOLUTION-PHASE ELECTROCHEMICAL DNA DETECTION PLATFORM WITH TARGET RECYCLING-BASED SIGNAL AMPLIFICATION
F. Xuan, X. Luo, and I.-M. Hsing, The Hong Kong University of Science and Technology, HONG KONG

M.7.168

COPPER-BASED SENSOR FOR POINT-OF-CARE MEASUREMENT OF ZINC IN SERUM
X. Pei¹, W. Kang¹, W. Yue¹, A. Bange², H. R. Wong³, W. R. Heineman¹, and I. Papautsky¹, ¹ University of Cincinnati, USA, ²Xavier University, USA, and ³Cincinnati Children's Hospital, USA

M.7.169

DETECTION OF METALLIC ELEMENTS IN A SINGLE CANCER CELL USING MICROFLUIDIC DEVICES COUPLED WITH ICP-MS
Y. Miyazaki¹, T. Yasui¹, K. Inagaki², Y. Okamoto¹, N. Kaji¹, T. Umemura¹, M. Tokeshi^1,3, and Y. Baba^1,4, ¹ Nagoya University, JAPAN, ²National Institute of Advanced Industrial Science and Technology (AIST), JAPAN, ³Hokkaido University, JAPAN, and ⁴National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

M.7.170

REAL-TIME FISH USING OPTICALLY DRIVEN MICROSPHERES FUNCTIONALIZED BY THE HOMOLOGOUS RECOMBINATION PROTEIN, RecA
H. Oana, T. Shino, K. Nishikawa, and M. Washizu, The University of Tokyo, JAPAN

M.7.171

GOLD NANOPARTICLE-BASED HYDROGEL CONTRAST AGENT PARTICLES WITH TUNABLE ELASTICITY FOR X-RAY COMPUTED TOMOGRAPHY IMAGING
C. Wang¹, X. Wang¹, S. Anderson², and X. Zhang¹, ¹ Boston University, USA, and ²Boston University Medical Center, USA

M.8.172

SUB-ATTOMOLE DETECTION OF MicroRNA IN TWENTY MINUTES USING POWER-FREE MICROFLUIDIC CHIP: TOWARDS POINT-OF-CARE TESTING
H. Arata, H. Komatsu, K. Hosokawa, and M. Maeda, RIKEN (Institute for Physical and Chemical Research), JAPAN

M.8.173

DNA BASED SAMPLE-TO-ANSWER DETECTION OF BACTERIAL PATHOGENS ON A CENTRIFUGAL MICROFLUIDIC FOIL CARTRIDGE
O. Strohmeier¹, B. Kanat¹, D. Bär², P. Patel³, J. Drexler⁴, M. Weidmann⁵, T. van Oordt¹, G. Roth^1,2, D. Mark¹, R. Zengerle^1,2, and F. von Stetten^1,2, ¹ HSG-IMIT, GERMANY, ²University of Freiburg, GERMANY, ³Centre for Biological Security, GERMANY, ⁴QIAGEN Lake Constance, GERMANY, and ⁵University Medical Center Göttingen, GERMANY

M.8.174

SAMPLE-TO-ANSWER LABDISK FOR POINT-OF-CARE ANALYSIS OF TOTAL CHOLESTEROL FROM WHOLE BLOOD
M. Rombach¹, S. Lutz¹, D. Mark¹, G. Roth², R. Zengerle^1,2, C. Dumschat³, A. Witt³, S. Hensel³, S. Frenzel³, F. Aßmann³, F. Gehring⁴, T. Reiner⁴, H. Drechsel⁴, P. Szallies⁴, and F. von Stetten², ¹ HSG-IMIT – Institut für Mikro- und Informationstechnik, GERMANY, ²University of Freiburg, GERMANY, ³EKF-diagnostic GmbH, GERMANY, and ⁴Hettich Zentrifugen GmbH & Co.KG, GERMANY

M.8.175

A MULTI-STEP IMMUNOASSAY USING DRY, PATTERNED REAGENTS IN A TWO-DIMENSIONAL PAPER NETWORK FORMAT
G. E. Fridley, H. Le, E. Fu, and P. Yager, University of Washington, USA

M.8.176

DISSOLVABLE FLUIDIC TIME DELAYS FOR AUTOMATED PAPER DIAGNOSTICS
B. Lutz, T. Liang, E. Fu, S. Ramachandran, P. Kauffman, and P. Yager, University of Washington, USA

M.8.178

STATIONARY FLUIDICS: MOVING TARGET MOLECULES ON BEADS THROUGH NON-MOVING LIQUIDS FOR MOLECULAR DIAGNOSTIC ASSAYS
H. Becker¹, C. Carstens¹, D. Kuhlmeier², C. Zilch³, and C. Gärtner¹, ¹ microfluidic ChipShop GmbH, GERMANY, ²Fraunhofer Institut for Cell Therapy and Immunology, Leipzig, GERMANY, and ³Magna Diagnostics, GERMANY

M.8.179

INTEGRATED BLOOD PRETREATMENT MODULE OF DUAL FUNCTION USING ANTI-BLOOD SERUM AND ALBUMIN-ADSORPTION BEADS
Y. H. Choi¹, K. H. Chung¹, J. H. Shin², and G. Y. Sung¹, ¹ Electronics and Telecommunications Research Institute, KOREA, and ²Korea Advanced Institute of Science and Technology, KOREA

M.8.180

DNA MELTING CURVE ANALYSIS ON SEMI-TRANSPARENT THIN FILM MICROHEATER ON FLEXIBLE LAB-ON-FOIL SUBSTRATE
A. Ohlander¹, T. Hammerle¹, G. Klink¹, C. Zilio⁴, F. Damin⁴, M. Chiari⁴, A. Russom², and K. Bock^1,3, ¹ Fraunhofer EMFT, GERMANY, ²KTH Royal Institute of Technology, SWEDEN, ³Center for Technologies of Microperipherics, GERMANY, and ⁴ICRM-CNR, ITALY

M.8.181

PINWHEEL ASSAY FOR COST EFFECTIVE AND LABEL FREE ENUMERATION OF CD4+ T LYMPHOCYTES
Q. Liu, J. Li, D. M. Haverstick, and J. P. Landers , University of Virginia, USA

M.8.182

MICROFLUIDIC SAMPLE PREPARATION OF PLEURAL EFFUSIONS FOR CYTODIAGNOSTICS
A. J. Mach, D. E. Go, J. Che, I. Talati, Y. Ying, R. Kulkarni, J. Rao, and D. Di Carlo, University of California, Los Angeles, USA

M.8.183

DESIGN AND SYNTHESIS OF FLUORESCENT ENZYME SUBSTRATE MONOMER AND ITS APPLICATION TO THE DEVELOPMENT OF HYDROGEL-BASED SINGLE STEP IMMUNOASSAY MICRODEVICE
H. Wakayama, S. Odaka, S. Funano, T. G. Henares, T. Endo, and H. Hisamoto, Osaka Prefecture University, JAPAN

M.8.184

FABRICATION OF CAPILLARY-DRIVEN TONER-BASED MICROFLUIDIC DEVICES FOR CLINICAL DIAGNOSTICS WITH COLORIMETRIC DETECTION
F. R. de Souza^1,2, G. L. Alves^1,2, K. A. Oliveira^1,2, P. B. M. e Silva^1,2, and W. K. T. Coltro^1,2, ¹ Federal University of Goias, BRAZIL, and ²Instituto Nacional de Ciência e Tecnologia de Bioanalítica, BRAZIL

M.8.185

RAPID URINE-BASED CLINICAL DIAGNOSIS OF DIABETIC NEPHROPATHY WITH FEMTO-MOLAR SENSITIVITY BY IMMUNO-PILLAR DEVICES
M. Sun¹, T. Kasama^1,2, N. Kaji¹, S. Akiyama¹, Y. Yuzawa³, S. Matsuo¹, M. Tokeshi^1,2,4, and Y. Baba^1,2,5, ¹ Nagoya University, JAPAN, ²"The Knowledge Hub" of AICHI, The Priority Research Project, JAPAN, ³Fujita Health University, JAPAN, ⁴Hokkaido University, JAPAN, and ⁵National Institute of Advanced Industrial Science and Technology, JAPAN

M.8.186

A MICROFLUIDIC DEVICE FOR EXPOSING TUMOR BIOPSY TISSUE TO MULTIPLE DRUGS
T. Chang, R. J. Monnat, Jr, and A. Folch, University of Washington, USA

M.8.187

RAPID ANTIBIOTIC SUSCEPTIBILITY TEST BASED ON THE MICROFLUIDIC AGAROSE CHANNEL WITH SINGLE CELL IMAGING PROCESS
J. Choi^1,2, Y.-G. Jung³, H. Na^1,2, J. Kim¹, S. Kim¹, U. Jung^1,2, and S. Kwon^1,2,3, ¹ Seoul National University, KOREA, ²Inter-university Semiconductor Research Center (ISRC), KOREA, and ³QuantaMatrix Inc., KOREA

M.8.188

INTEGRATION OF NEURAMINIDASE INHIBITOR ASSAY INTO SINGLE STEP OPERATION USING COMBINABLE PDMS CAPILLARY (CPC) SENSOR
T. Ishimoto, K. Jigawa, T. G. Henares, T. Endo, and H. Hisamoto, Osaka Prefecture University, JAPAN

M.8.189

MICROFLUIDIC BIOMIMETIC ARTERIOLAR NETWORKS TO STUDY DRUG ELUTION FROM EMBOLISATION BEADS
D. Carugo¹, B. Roy², L. Capretto¹, M. Hill¹, T. K. Maiti², S. Chakraborty², and X. Zhang¹, ¹ University of Southampton, UK, and ²Indian Institute of Technology, INDIA

M.8.190

DEVELOPMENT OF PROGRAMMABLE BIOSENSOR USING SOLID PHASE PEPTIDE SYNTHESIS ON MICRO CHIP
B. Rahul, Y. Ukita, and Y. Takamura, Japan Advanced Institute of Science and Technology, JAPAN

M.8.191

ACCELERATE SEPSIS DIAGNOSIS BY SEAMLESS INTEGRATION OF DNA PURIFICATION AND QPCR
B.-N. Hsu, A. C. Madison, and R. B. Fair, Duke University, USA

M.8.192

A HIGH-SPEED HIGH-PERFORMANCE FULLY INTEGRATED RT-PCR MICROCHIP
N. Han, and K.-H. Han, Inje University, KOREA

M.8.193

INTEGRATED MICROFLUIDIC HUB FOR AUTOMATED PREPRATION OF DNA LIBRARIES FOR PERSONALIZED SEQUENCING SYSTEMS
M. J. Jebrail, H. Kim, N. Thaitrong, M. S. Bartsch, R. F. Renzi, and K. D. Patel, Sandia National Laboratories, USA

M.9.194

HUMAN BODY HEAT ENERGY HARVESTING USING FLEXIBLE THERMOELECTRIC GENERATOR FOR AUTONOMOUS MICROSYSTEMS
S.-E. Jo, M.-S. Kim, M.-K. Kim, H.-L. Kim, and Y.-J. Kim, Yonsei University, KOREA

M.9.195

ANALYSIS OF POLYCHLORINATED BIPHENYLS IN OIL USING MICROFLUIDIC BASED PRETREATMENT METHOD AND IMMUNOASSAY
A. Aota¹, Y. Date^1,2, S. Terakado¹, and N. Ohmura¹, ¹ Central Research Institute of Electric Power Industry, JAPAN, and ²Tohoku University, JAPAN

M.9.196

PORTABLE MEMBRANE PROTEIN CHIP: DEVELOPMENT OF MEMBRANE PROTEIN SENSORS FOR ENVIRONMENT ANALYSIS
R. Kawano¹, Y. Tsuji^1,3, T. Osaki¹, K. Kamiya¹, N. Miki^1,3, Y. Tanaka⁴, and S. Takeuchi^1,2, ¹ Kanagawa Academy of Science and Technology, JAPAN, ²The University of Tokyo, JAPAN, ³Keio University, JAPAN, and ⁴Tecella Co. Ltd., US

M.9.197

ION-SELECTIVE MEMBRANE FORMED IN A MICROFLUIDIC CHIP UTILIZING SURFACE TENSION FORCE FOR HIGH SENSITIVE AMMONIA ION SENSING
T.-Y. Chiang¹, L.-M. Fu², C.-H. Tsai², and C.-H. Lin¹, ¹ National Sun Yat-sen University, TAIWAN, and ²National Pingtung University of Science and Technology, TAIWAN

M.9.198

MULTIPLE PATHOGEN DETECTION FOR POULTRY BY ULTILIZING INTEGRATED MICROFLUIDIC SYSTEM
Y.-C. Su¹, C.-H. Wang¹, W.-H. Chang¹, L.-H. Lee², and G.-B. Lee¹, ¹ National Tsing Hua University, TAIWAN, and ²National Chung Hsing University, TAIWAN

M.9.199

IMPLANTABLE DEVICE FOR LATE-PHASE HEMORRHAGIC SHOCK PREVENTION USING A NOVEL NON-ENZYMATIC FUEL CELL
V. Oncescu, S. Lee, and D. Erickson, Cornell University, USA

M.9.200

EVALUATION OF ETHANOL TOXICITY TO OIL PRODUCING ALGAE USING A MICROFLUIDIC DEVICE
K. Mogi, and T. Fujii, The University of Tokyo, JAPAN

M.9.201

PATTERNED MICROCLEANSING AND PARTICLE RECOVERY WITH OPEN ACOUSTIC MICROFLUIDICS
A. Doria, N. E. Martin, and A. P. Lee, University of California - Irvine, USA

T.1.1

WATER DROPLET MANIPULATION BY TUNABLE WETTING ON SMART POLYMER AT ULTRA-LOW VOLTAGES
Y.-T. Tsai, C.-H. Choi, and E.-H. Yang, Stevens Institute of Technology, USA

T.1.2

DESIGN AND FABRICATION OF A CD-LIKE DISPOSABLE MICROFLUIDIC PLATFORM FOR SERIAL DILUTION
Y. Ouyang¹, J. Li¹, C. Phaneuf², S. Wang¹, P. S. Riehl¹, and J. P. Landers¹, ¹ University of Virginia, USA, and ²Georgia Institute of Technology, USA

T.1.3

MICROFLUIDIC CENTRIFUGO-PNEUMATIC SIPHON ENABLES FAST BLOOD PLASMA EXTRACTION WITH HIGH YIELD AND PURITY
S. Zehnle¹, M. Rombach¹, F. von Stetten^1,2, R. Zengerle^1,2, and N. Paust¹, ¹ HSG-IMIT – Institut für Mikro- und Informationstechnik, GERMANY, and ²University of Freiburg, GERMANY

T.1.4

ICE DROPLET COLLIDER: ULTIMATE ACCELERATION OF DROPLET USING MICROSCALE PHASE TRANSITION FOR CHEMICAL REACTION BY KINETIC ENERGY
T. Matsuno, Y. Kazoe, K. Mawatari, and T. Kitamori, The University of Tokyo, JAPAN

T.1.5

FABRICATION OF DISPOSABLE ELECTROPHORESIS MICROCHIPS BASED ON USING OF COLORED TONER
E. F. M. Gabriel¹, E. Carrilho², C. L. do Lago², and W. K. T. Coltro¹, ¹ Federal University of Goias, BRAZIL, and ²University of Sao Paulo, BRAZIL

T.1.6

INSTANTANEOUS SOLIDIFICATION OF A CENTRIFUGE-DRIVEN CAPILLARY JET WITH CONTROLLED HYDRODYNAMIC INSTABILITY IN A CENTRIFUGE-BASED DROPLET SHOOTING DEVICE THROUGH OBSERVATIONAL ANALYSIS
K. Maeda¹, H. Onoe^1,2, M. Takinoue³, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, ²Japan Science and Technology Agency (JST), JAPAN, and ³Tokyo Institute of Technology, JAPAN

T.1.7

INDIRECT MANIPULATION OF PARTICLES USING A SCANNING OPTOFLUIDIC TWEEZER
G. K. Kurup, and A. S. Basu, Wayne State University, USA

T.1.8

A MULTIFUNCTIONAL VENT VALVE SYSTEM IN A CENTRIFUGAL MICROFLUIDIC PLATFORM
S.-S. Lin, W.-H. Lian, C.-L. Chen, C.-W. Yang, and A. M. Wo, National Taiwan University, TAIWAN

T.1.9

NOVEL NON-EQUILIBRIUM ELECTROKINETIC MICROMIXER WITH NANOPOROUS MEMBRANE FABRICATED BY LASER POLYMERIZATION TECHNIQUE
S. Hwang, and S. Song, Hanyang University, KOREA

T.1.10

JANUS HYDROGEL BEADS FOR ELECTRONIC PAPER USING SHRINKAGE-GELATION TECHNIQUE
K. Aketagawa¹, H. Hirama¹, H. Moriguchi², and T. Torii¹, ¹ The University of Tokyo, JAPAN, and ²RIKEN, JAPAN

T.1.11

CENTRIFUGAL MULTIPLEX FIXED-VOLUME DISPENSER (C-MUFID) ON A DISPOSALBE PLASTIC LAB-ON-A-DISK FOR BIOCHEMICAL ASSAYS
M. La, Y. D. Seo, and D. S. Kim, Pohang University of Science and Technology, KOREA

T.1.12

MECHANISTIC CHARACTERIZATION OF ALTERNATING CURRENT CLOUD POINT EXTRACTION IN A MICROCHANNEL: EXTRACTION UNDER PHYSIOLOGICAL TEMPERATURE
N. Sasaki, A. Takemura, and K. Sato, Japan Women's University, JAPAN

T.1.13

NOVEL SIMULATION TOOL COUPLING NON-LINEAR ELECTROPHORESIS AND REACTION KINETICS
O. Dagan, and M. Bercovici, Technion - Israel Institute of Technology, ISRAEL

T.1.14

A MICROFLUIDIC CULTURE SYSTEM FOR ANALYSIS OF NEUROTOXICITY OF OLIGOMERIC ASSEMBLIES OF AMYLOID BETA PROTEINS
Y. J. Choi¹, S. Chae¹, J. H. Kim¹, J. Y. Park², and S.-H. Lee¹, ¹ Korea University, KOREA, and ²Chung-Ang University, KOREA

T.1.15

PERFORMANCES OF HIGH-K DIELECTRIC MATERIALS (Al₂O₃, HfO₂, ZrO₂) FOR LIQUID DIELECTROPHORESIS (LDEP) MICROFLUIDIC DEVICES
R. Renaudot¹, V. Agache¹, L. Jalabert², M. Kumemura², D. Collard², and H. Fujita², ¹ CEA-LETI, FRANCE, and ²The University of Tokyo, JAPAN

T.1.16

A NOVEL MICROFLUIDIC CONCENTRATION GRADIENT DROPLET ARRAY GENERATOR FOR PREPARING OPTICAL ENCODING NANOPARTICLES
C.-G. Yang^1,2, Z.-R. Xu¹, A. P. Lee², and J.-H. Wang¹, ¹ Northeastern University, CHINA, and ²University of California, Irvine, USA

T.1.17

ON-CHIP PROCESSING AND DNA EXTRACTION FROM LARGE VOLUME URINE SAMPLES FOR THE DETECTION OF HERPES SIMPLEX VIRUS TYPE 2
C. Kemp, J. M. Wojciechowska, M. N. Esfahani, G. Benazzi, K. J. Shaw, S. J. Haswell, and N. Pamme, University of Hull, UK

T.1.18

HIGH-THROUGHPUT PRODUCTION OF SINGLE AND COMPOUND EMULSIONS VIA ON-CHIP MICROFLUIDIC PARALLELIZATION COUPLED WITH COAXIAL MULTIPLE ANNULAR WORLD-TO-CHIP INTERFACES
T. Nisisako^1,2, T. Ando¹, and T. Hatsuzawa¹, ¹ Tokyo Institute of Technology, JAPAN, and ²University of California, Los Angeles, USA

T.1.19

FIELD-FREE PARTICLE SEGREGATION AND EXTRACTION FOR BEAD-BASED ASSAYS IN PLUGS
G. K. Kurup, and A. S. Basu, Wayne State University, USA

T.1.20

FUSION AND SORTING OF TWO PARALLEL TRAINS OF DROPLETS USING A RAIL-ROAD-LIKE CHANNEL NETWORK AND GUIDING TRACKS
L. Xu, H. Lee, R. Panchapakesan, and K. W. Oh, University at Buffalo, The State University of New York (SUNY) at Buffalo, USA

T.1.21

AUTOMATED SYSTEM FOR RAPID GENERATION AND TRANSPORT OF LIBRARIES OF NANOLITER DROPLETS
T. S. Kaminski, S. Jakiela, M. A. Czekalska, W. Postek, and P. Garstecki, Polish Academy of Sciences, POLAND

T.1.22

ACCELERATED TARGET CAPTURE BY DYNAMIC MAGNETIC PARTICLE ACTUATION
A. van Reenen¹, Y. Gao¹, A. M. de Jong¹, M. A. Hulsen¹, J. M. J. den Toonder^1,2, and M. W. J. Prins^1,2, ¹ Eindhoven University of Technology, THE NETHERLANDS, and ²Philips Research, THE NETHERLANDS

T.1.23

DOUBLE BILAYER LIPID MEMBRANE (dBLM) CHIPS FOR STUDIES OF BIOMEMBRANE INTERACTION AND FUSION
C. Shao, E. L. Kendall, and D. L. DeVoe, University of Maryland, USA

T.1.24

MULTIPLEX SNP ANALYSIS MICRODEVICE USING ALLELE-SPECIFIC POLYMERASE CHAIN REACTION-MICROARRAY
J. Y. Choi¹, Y. T. Kim¹, J.-Y. Byun², J. Ahn¹, D.-G. Gweon¹, M.-G. Kim³, and T. S. Seo¹, ¹ Korea Advanced Institute of Science and Technology (KAIST), KOREA, ²Chungnam National University, KOREA, and ³Gwangju Institute of Science and Technology (GIST), KOREA

T.1.25

A SIMPLE YET EFFECTIVE MICROFLUIDIC SYSTEM FOR TRAPPING AND RELEASING SINGLE MICROBEADS
H. Kim, and J. Kim, Pohang University of Science and Technology (POSTECH), KOREA

T.1.27

INTEGRATED PASSIVE BUBBLE TRAP FOR LONG-TERM CELL CULTURE MICROFLUIDIC SYSTEMS
K. Ziółkowska, I. Hofman, A. Dybko, and Z. Brzózka, Warsaw University of Technology, POLAND

T.1.28

NANOPARTICLE CRYSTAL BASED NANOFLUIDIC BIOSENSOR AND ITS SIGNAL ENHANCEMENT
J. Sang¹, W. Wang^{1, 2}, M. Chu¹, Y. Wang¹, H. Li¹, H. A. Zhang^1,2, W. Wu^1,2, and Z. Li^1,2, ¹ Peking University, CHINA, and ²National Key Laboratory of Science and Technology on Micro/Nano Fabrication, CHINA

T.1.30

MICROFLUIDIC SYNTHESIS OF MICROMETER-SIZE COLLAGEN HYDROGEL PARTICLES FOR CELL MANIPULATION APPLICATIONS
S. Sugaya, M. Yamada, and M. Seki, Chiba University, JAPAN

T.2.31

CELL-FREE PROTEIN SYNTHESIS IN FEMTOLITER MICROCHAMBERS FOR ARRAYING ULTRA-HIGH DENSITY PROTEIN SPOTS
S. H. Kim^1,2, S. Yoshizawa^1,3, S. Takeuchi^1,2, T. Fujii^1,2, and D. Fourmy^1,3, ¹ University of Tokyo, JAPAN, ²JST, JAPAN, and ³CNRS, FRANCE

T.2.32

DEVELOPMENT OF LABEL-FREE BIOSENSOR FOR THE DETECTION OF ADENOSINE DIPHOSPHATE AS A UNIVERSAL KINASE/ATPASE ASSAY USING NANOIMPRINTED FLEXIBLE TWO-DIMENSIONAL PHOTONIC CRYSTAL
T. Endo, B. M. Henares, and H. Hisamoto, Osaka Prefecture University, JAPAN

T.2.33

A MEMBRANE MICROCONTACTOR AS A TOOL FOR SAMPLE PRE-TREATMENT OF PHARMACEUTICAL COMPOUNDS
J. Hereijgers^1,2, M. Callewaert¹, H. Ottevaere¹, T. Breugelmans², D. Cabooter³, and W. De Malsche¹, ¹ Vrije Universiteit Brussel, BELGIUM, ²Artesis University College, BELGIUM, and ³University of Leuven, BELGIUM

T.2.34

RAPID AND ACCURATE IC₅₀ DETERMINATION USING LOGARITHMIC CONCENTRATION GENERATOR
Y. Abe^1,3, H. Sasaki¹, T. Osaki¹, K. Kamiya¹, R. Kawano¹, N. Miki^1,3, and S. Takeuchi^1,2, ¹ Kanagawa Academy of Science and Technology, JAPAN, ²The University of Tokyo, JAPAN, and ³Keio University, JAPAN

T.2.35

A DROPLET BASED MULTI-DRUG SCREENING SYSTEM CONTROLLED WITH ELECTROSTATIC MICROVALVES
E. Yıldırım¹, E. Özgür², and H. Külah², ¹ Çankaya University, TURKEY, and ²METU, TURKEY

T.2.36

ELECTRICALLY MEDIATED GENE DELIVERY AND THEIR DIFFUSION MECHANISM ON LOCALIZED SINGLE CELL USING ITO MICROELECTRODE BASED TRANSPARENT CHIP
T. S. Santra¹, S.-C. Chen¹, C.-J. Chang¹, T.-J. Chen¹, P.-C. Wan¹, and F.-G. Tseng^1,2, ¹ National Tsing Hua University, TAIWAN, and ²Academia Sinica, TAIWAN

T.2.37

CELL-BASED SCHEDULE DEPENDENT DRUG COMBINATION SCREENING WITH A DROPLET-BASED MICROFLUIDIC SYSTEM
G. Du^1,2, J. M. J. den Toonder^2,3, and Q. Fang¹, ¹ Zhejiang University, CHINA, ²Eindhoven University of Technology, THE NETHERLANDS, and ³Philips Research Laboratories, THE NETHERLANDS

T.2.38

LYMPHATIC CAPILLARY INVASION ASSAY BY A SINGLE CELL MIGRATION CHIP
Y.-C. Chen, S. G. Allen, Z.-F. Wu, S. D. Merajver, and E. Yoon, University of Michigan, USA

T.2.39

AMPLIFICATION AND TEMPORAL FILTERING DURING GRADIENT SENSING BY NERVE GROWTH CONES REVEALED WITH A SHEAR FREE MICROFLUIDIC DEVICES
M. Morel^1,3, V. Shynkar¹, J.-C. Galas¹, I. Dupin-Vallois², V. Studer², and M. Dahan¹, ¹ Laboratoire Kastler Brossel, FRANCE, ²Interdisciplinary Institute for Neuroscience, FRANCE, and ³Weizmann Institute of Science, ISRAEL

T.2.40

DEFORMABILITY CYTOMETRY OF EMBRYONIC STEM CELLS REVEALS CONSISTENT MECHANICAL PROPERTIES ACROSS CELL LINES
M. Masaeli^1,2, H. T. K. Tse^1,2, D. R. Gossett^1,2, A. T. Clark^1,3, and D. Di Carlo^1,2, ¹ University of California, Los Angeles, USA, ²California NanoSystems Institute, USA, and ³Eli and Edythe Broad Center of Regenerative Medicine and Stem Cell Research, USA

T.2.41

PARALLEL DISCRETE CHEMICAL STIMULATIONS OF MATRIX-ARRAYED NEUROSPHERES USING A MICROHOLE ARRAY DEVICE
T. Yasuda¹, G. Takase¹, K. Y. Jung¹, M. Yamanaka¹, T. Tamura², and K. Yahiro², ¹ Kyushu Institute of Technology, JAPAN, and ²STEM Biomethod Corporation, JAPAN

T.2.42

A MICROFLUIDIC DEVICE FOR REAL-TIME MONITORING OF FLAGELLAR LENGTH IN SINGLE LIVING CELLS OF CHLAMYDOMONAS
X. Ai, Q. Liang, J. Pan, and G. Luo, Tsinghua University, CHINA

T.2.43

SINGLE CELL ELISA
K. Eyer, S. Stratz, P. Kuhn, S. K. Kuester, and P. S. Dittrich, ETH Zurich, SWITZERLAND

T.2.44

MICROFLUIDIC STRATEGY FOR SPATIOTEMPORALLY RESOLVED MOLECULAR SAMPLING FROM LIVE OVARY SLICES
D. S. Dandy, M. Mensack, J. Wydallis, C. S. Henry, C. Eitel, and S. Tobet, Colorado State University, USA

T.2.45

AN INTEGRATED MICROFLUIDIC PLATFORM FOR IN-SITU CELLULAR CYTOKINE SECRETION IMMUNOPHENOTYPING
N.-T. Huang, W. Chen, B.-R. Oh, J. Fu, and K. Kurabayashi, University of Michigan, USA

T.2.46

HYDROGEL-FREE AND PUMP-LESS MICROFLUIDIC DEVICE FOR BACTERIAL CHEMOTAXIS UNDER CHEMICAL GRADIENT
H.-H. Jeong¹, S.-H. Jin¹, S.-C. Jang¹, S.-H. Lee², and C.-S. Lee¹, ¹ Chungnam National University, KOREA, and ²Korea Institute of Industrial Technology (KITECH), KOREA

T.2.47

ELECTRICAL-IMPEDANCE-SPECTROSCOPY CHARACTERIZATION OF INDIVIDUALLY IMMOBILIZED SINGLE PARTICLES AND YEAST CELLS
Z. Zhu, O. Frey, N. Haandbæk, D. Ottoz, F. Rudolf, and A. Hierlemann, ETH Zürich, SWITZERLAND

T.2.48

SAMPLE PREPARATION FOR SINGLE-CELL WHOLE CHROMOSOME ANALYSIS
J. P. Beech¹, K. Adolfsson¹, S. Holm¹, F. Yadegari¹, C. Freitag², J. Fritzsche², K. U. Mir³, and J. O. Tegenfeldt^1,2, ¹ Lund University, SWEDEN, ²University of Gothenburg, SWEDEN, and ³University of Oxford, UK

T.2.49

MICROFLUIDIC DEVICE FOR MEASURING THE DEFORMABILITY OF RED CELLS PARASITIZED BY PLASMODIUM FALCIPARUM
Q. Guo, M.-E. Myrand-Lapierre, and H. Ma, University of British Columbia, CANADA

T.2.50

THE ROLE OF MEMBRANE LIPID RAFTS IN OSTEOBLASTIC SENSING AND PROPAGATION OF MECHANICAL FORCES: A MICROFLUIDIC BASED SINGLE CELL ANALYSIS STUDY
B. Roy¹, D. Carugo², X. Zhang², T. K. Maiti¹, and S. Chakraborty¹, ¹ Indian Institute of Technology, INDIA, and ²University of Southampton, UK

T.2.51

MICROFLUIDIC DEVICES FOR INTEGRATED SYNCHRONIZATION AND ANALYSIS OF BACTERIA
S. M. Madren, M. D. Hoffman, P. J. B. Brown, D. T. Kysela, Y. V. Brun, and S. C. Jacobson, Indiana University, USA

T.2.52

ENHANCED CELL STIFFNESS EVALUATION BY TWO-PHASE DECOMPOSITION
C-H. D. Tsai¹, M. Kaneko¹, S. Sakuma², and F. Arai², ¹ Osaka University, JAPAN, and ²Nagoya University, JAPAN

T.2.53

MEASUREMENT OF INFLAMMATORY CYTOKINE SECRETION FROM HUMAN MONOCYTES AFTER INFLAMMASOME ACTIVATION
Y. Shirasaki^1,2, A. Nakahara², N. Shimura¹, K. Izawa³, N. Suzuki¹, M. Yamagishi¹, J. Mizuno², T. Sekiguchi², R. Nishikomori³, S. Shoji², and O. Ohara^1,4, ¹ Riken, JAPAN, ²Waseda University, JAPAN, ³Kyoto University Graduate School of Medicine, JAPAN, and ⁴Kazusa DNA Research Institute, JAPAN

T.2.54

STABLE GENERATION OF MULTIPLE CHEMICAL GRADIENTS USING IN-SITU FORMED NANOPOROUS MEMBRANES
E. Choi¹, H.-K. Chang¹, C. Y. Lim¹, T. Kim², and J. Park¹, ¹ Sogang University, KOREA, and ²Ulsan National Institute of Science and Technology, KOREA

T.2.55

3D CIRCULATORY PERFUSION-CULTURE SYSTEM BY USING HIGH EFFICIENCY PROPORTIONAL CELL CONTACT
Y.-S. Chen, L.-Y. Ke, Y.-C. Huang, and C.-H. Liu, National Tsing Hua University, TAIWAN

T.2.56

A BRONCHIAL EPITHELIUM-MIMETIC MICROFLUIDIC CHIP SYSTEM FOR INVESTIGATING MICROENVIRONMENTAL CHANGE-INDUCED INFLAMMATORY PROCESS
T. H. Punde¹, W.-H. Wu¹, P.-C. Lien¹, P.-C. Shih¹, M. D.-T. Chang¹, K.-Y. Lee², H.-P. Kuo², and C.-H. Liu¹, ¹ National Tsing Hua University, TAIWAN, and ²Chang Gung University, TAIWAN

T.2.57

A NEUROSPHEROID CULTURED ON THE TIP OF A FLEXIBLE MICROELECTRODE FOR CORTICAL MICROSTIMULATION
K. Okita¹, M. Kato-Negishi^1,2, K. Sato^1,2, H. Onoe^1,2, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²Japan Science and Technology (JST), JAPAN

T.2.58

PLANT-ON-A-CHIP MICROFLUIDIC-SYSTEM FOR QUANTITATIVE ANALYSIS OF POLLEN TUBE GUIDANCE BY SIGNALING MOLECULE: TOWARDS CELL-TO-CELL COMMUNICATION STUDY
M. Horade, Y. Mizuta, N. Kaji, T. Higashiyama, and H. Arata, JST-ERATO/Nagoya University, JAPAN

T.2.59

MICROFLUIDICS FOR ALZHEIMER'S DISEASE: SCREENING AND DIFFUSION TO STUDY AMYLOID-β AGGREGATION
V. Picot^1,2, M. Rossi^1,2, B. Alies², C. Hureau², P. Faller², and P. Joseph^1,2, ¹ CNRS, LAAS, FRANCE, and ²Univ de Toulouse, FRANCE

T.2.60

MULTICHANNEL INCUBATION TYPE PLANAR PATCH CLAMP BIOSENSOR USING PLASTIC (PMMA) SUBSTRATES AND CHARACTERIZATION BY LASER-GATED ION-CHANNEL PROTEIN
Z.-H. Wang^1,2, H. Uno^1,2, N. Takada³, O.-S. Kumar^1,2, T. Ishizuka^2,4, H. Yawo^2,4, and T. Urisu^1,2, ¹ Nagoya University, JAPAN, ²JST, CREST, JAPAN, ³Institute for Molecular Science, JAPAN, and ⁴Tohoku University, JAPAN

T.2.61

FABRICATION OF OPTICAL AND GRAPHICAL CODES CONTAINED MICRODISK FOR MULTIPLEXED BIOASSAY
Y. Koh, H. Kang, S. Jeong, Y.-S. Lee, D. H. Jeong, S. H. Lee, Y.-T. Seo, and Y.-K. Kim, Seoul National University, KOREA

T.2.62

INVESTIGATING THE EFFECTS OF MEMBRANE TENSION AND SHEAR STRESS ON LIPID DOMAINS IN MODEL MEMBRANES
T. Robinson, D. Hess, P. Kuhn, and P. S. Dittrich, ETH Zurich, SWITZERLAND

T.2.63

FERROMAGNETIC PARTICLES FOR AN IMPROVED HETEROGENEOUS BIOASSAY PERFORMANCE ON A DIGITAL LAB-ON-A-CHIP
S. Vermeir¹, D. Witters¹, N. Vergauwe¹, K. Knez¹, M. Gijs², R. Puers¹, and J. Lammertyn¹, ¹ KU Leuven-University of Leuven, BELGIUM, and ²Ecole Polytechnique Federale de Lausanne, SWITZERLAND

T.3.64

A MICROFLUIDIC ARRAY PLATFORM FOR SIMULTANEOUS CELL CULTURE UNDER VARIOUS OXYGEN TENSIONS
C.-C. Peng, W.-H. Liao, C.-Y. Wu, and Y.-C. Tung, Academia Sinica, TAIWAN

T.3.65

TEMPERATURE-FLEXIBLE CELL MICROCONTAINERS FABRICATED WITH A PHOSPHORYLCHOLINE POLYMER HYDROGEL ON CHIP
Y. Xu¹, K. Mawatari², T. Konno², K. Ishihara², and T. Kitamori², ¹ Osaka Prefecture University, JAPAN, and ²The University of Tokyo, JAPAN

T.3.66

ANALYSIS FOR EFFECT OF CELL SHAPE ON HIPPO SIGNALING PATHWAY USING MICRO-FABRICATED CELL CULTURE PLATFORM
K. Wada^1,2,4, K. Itoga³, T. Okano³, S. Yonemura², and H. Sasaki^2,4, ¹ RIKEN Advanced Science Institute, JAPAN, ²RIKEN Center for Developmental Biology, JAPAN, ³Tokyo Women's Medical University ABMES, JAPAN, and ⁴Kumamoto University, JAPAN

T.3.67

SEQUENTIAL ASSEMBLY OF THE FUNCTIONAL MATERIAL MICROPATTERNS ON THE HYDROGEL SHEET FOR CONSTRUCTING SKELETAL MUSCLE CELL-BASED ASSAY SYSTEM
K. Nagamine^1,2, S. Otani¹, S. Ito¹, H. Kaji^1,2, M. Kanzaki^1,2, and M. Nishizawa^1,2, ¹ Tohoku University, JAPAN, and ²JST-CREST, JAPAN

T.3.68

HANGING DROP CULTURE DEVICE FOR EMBRYONIC STEM CELL
Y. Yamaguchi, M. M. Hossain, T. Ikeuchi, A. Hashimoto, S. R. Rao, M. Saito, and E. Tamiya, Osaka University, JAPAN

T.3.69

MICROFLUIDIC CULTURE PLATFORM FOR STUDYING NEURONAL RESPONSE TO AXONAL STRETCH INJURY
Y. C. Yap¹, T. C. Dickson¹, A. E. King², M. C. Breadmore², and R. M. Guijt², ¹ Menzies Research Institute, AUSTRALIA, and ²University of Tasmania, AUSTRALIA

T.3.70

PHENOTYPIC MODULATION OF PLURIPOTENT STEM CELLS (PSCs) INDUCED BY MICROFABRICATION MATERIALS
K. Kamei, Y. Hirai, Y. Makino, M. Yoshioka, L. Liu, M. Nakajima, Q. Yuan, Y. Chen, and O. Tabata, Kyoto University, JAPAN

T.3.71

DISTINCT AUTO-REGULATION OF EMBRYONIC STEM CELL BEHAVIOR BY CELL-SECRETED SOLUBLE FACTORS IN A MEMBRANE-BASED TWO-CHAMBERED MICROBIOREACTOR
M. M. Chowdhury, H. Kimura, T. Fujii, and Y. Sakai, The University of Tokyo, JAPAN

T.3.72

TUBLOGENESIS OF ENDOTHELIAL CELLS IN CORE-SHELL HYDROGEL MICROFIBERS
H. Onoe^1,2, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²Japan Science and Technology (JST), JAPAN

T.3.73

A STUDY OF AXONAL PROTEIN TRAFFICKING IN NEURONAL NETWORKS VIA THE MICROFLUIDIC PLATFORM
Y. Fu^1,2,3, A. Vandongen², T. Bourouina³, W. M. Tsang⁴, M. Je⁴, and A. Q. Liu¹, ¹ Nanyang Technological University, SINGAPORE, ²Duke-NUS Graduate Medical School, SINGAPORE, ³University of Paris, FRANCE, and ⁴A*STAR, SINGAPORE

T.3.74

MICROFLUIDIC SYSTEM FOR PULSED STIMULATION AND TIME COURSE ANALYSIS OF MAMMALIAN CELLS: IDENTIFICATION OF THE MINIMAL TNF-ALPHA PULSE DURATION FOR NF-KAPPAB ACTIVATION IN HELA CELLS
M. A. Qasaimeh^1,2, R. Lee¹, S. Gaudet¹, and D. Juncker², ¹ Dana Farber Cancer Institute and Harvard Medical School, USA, and ²McGill University, CANADA

T.3.75

GENOME-LEVEL MAMMALIAN CELL RESPONSES TO DIGITAL MICROFLUIDIC ACTUATION
S. H. Au, and A. R. Wheeler, University of Toronto, CANADA

T.3.76

SMOOTH-TIP DIELECTROPHORESIS BASED TWEESERS FOR SINGLE LIPOSOME HANDLING
T. Kodama^1,2, T. Osaki¹, R. Kawano¹, K. Kamiya¹, N. Miki^1,2, and S. Takeuchi^1,3, ¹ Kanagawa Academy of Science and Technology, JAPAN, ²Keio University, JAPAN, and ³The University of Tokyo, JAPAN

T.3.77

CONCENTRATION/SEPARATION OF CRYPTOSPORIDIUM OOCYSTS BY ON-CHIP HYBRID AC-ELECTROKINETICS FOR DIGITAL MICROFLUIDICS
R. Lejard¹, J. Follet², A. Vlandas¹, A. Follet³, V. Thomy¹, and V. Senez¹, ¹ Institut d'Electronique, de Microélectronique et de Nanotechnologie (CNRS/IEMN), FRANCE, ²Institut Supérieur d'Agriculture (ISA), FRANCE, and ³Faculté Libre des Sciences et Technologies (FLST), FRANCE

T.3.78

MICROFABRICATED PARTICLE ASSEMBLIES FOR VERSATILE CELL PATTERNING
X. Zhang, and Y. Zhao, The Ohio State University, USA

T.3.79

IN SITU MICROFLUIDIC BIOFUNCTIONALISATION TO FORM MULTIVALENT INTERACTIONS AND INVESTIGATE CELL ROLLING AND PHENOTYPE MODIFICATION
G. Perozziello^1,2, G. Simone³, R. La Rocca⁴, F. Pardeo¹, P. Candeloro¹, N. Malara¹, C. Liberale⁴, F. De Angelis⁴, G. Cuda^1,2, E. Carbone⁵, and E. Di Fabrizio^4,1, ¹ University of Catanzaro, ITALY, ²Biotecnomed Scarl, ITALY, ³University of Naples (Federico II), ITALY, ⁴Italian Institute of Technology, ITALY, and ⁵Karolinska Institute, SWEDEN

T.3.80

AN OPTICALLY-INDUCED DIELECTROPHORETIC (ODEP) MICROFLUIDIC PLATFORM FOR ISOLATION OF CIRCULATING TUMOR CELLS (CTCS) AFTER CONVENTIONAL CTC ISOLATION PROCESS
S.-B. Huang¹, M.-H. Wu¹, C.-H. Hsieh^1,2, C.-L. Yang¹, Y.-H. Lin¹, H.-C. Lin¹, C.-P. Tseng¹, and G.-B. Lee³, ¹ Chang Gung University, TAIWAN, ²Chang Gung Memorial Hospital, TAIWAN, and ³National Tsing Hua University, TAIWAN

T.3.81

RAPID AND SIMPLE DISCRIMINATION OF CELLS WITH SPECIFIC SURFACE ANTIGEN WITH DIELECTROPHORESIS
T. Yasukawa^1,2, H. Hatanaka¹, and F. Mizutani¹, ¹ University of Hyogo, JAPAN, and ²JST-CREST, JAPAN

T.3.82

CONTINUOUS RBC REMOVAL USING SPIRAL MICROCHANNEL WITH TRAPEZOID CROSS-SECTION
L. Wu¹, G. Guan^2,3, H. W. Hou¹, A. A. S. Bhagat³, and J. Han^1,3, ¹ Massachusetts Institute of Technology, USA, ²National University of Singapore, SINGAPORE, and ³Singapore-MIT Alliance for Research and Technology (SMART), SINGAPORE

T.3.83

MULTI-COMPONENT SEPARATION CHIP UTILIZING MICROPILLAR ARRAYS IN SPLITLEVEL SPIRAL CHANNEL
Y. Ju¹, Z. Geng^1,2, Q. Wang¹, and Z. Li¹, ¹ Peking University, CHINA, and ²Minzu University of China, CHINA

T.3.84

DYNAMICALLY CELL SEPARATING THERMO-RESPONISIVE BIOINTERFACES HAVING DENSE POLYMER BRUSHES
K. Nagase¹, A. Kimura², T. Shimizu¹, K. Matsuura¹, M. Yamato¹, N. Takeda², and T. Okano¹, ¹ Tokyo Women's Medical University, JAPAN, and ²Waseda University, JAPAN

T.3.85

MICROFLUIDIC RARE CANCER CELL COLLECTION WITH ANTI-EpCAM ANTIBODY MODIFIED EUGLENA BY PHOTOTAXIS INSIDE MICROCHANNELS
Y. Okamoto¹, Y. Nakakita¹, T. Sano¹, N. Kaji¹, M. Tokeshi^1,2, and Y. Baba^1,3, ¹ Nagoya University, JAPAN, ²Hokkaido University, JAPAN, and ³National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

T.3.86

MICROCHIP FILTER USING 3-DIMENSIONAL FLOW FOR RARE CELLS SEPARATION
J.-Y. Lee, H.-S. Moon, T. S. Sim, M. S. Kim, H. Jeong, Y. J. Kim, J.-G. Lee, S. Baek, J.-M. Oh, H. J. Lee, J. C. Park, N. Huh, and S. S. Lee, Samsung Advanced Institute of Technology (SAIT), KOREA

T.3.87

ISOLATION OF CIRCULATING TUMOR CELLS WITH HIGH RECOVERY AND PURITY BY CELL SIZE AMPLIFICATION AND A MIRO SLIT FILTER HAVING EXTREMELY HIGH ASPECT RATIO
T. S. Sim, M. S. Kim, H.-S. Moon, J.-Y. Lee, J.-G. Lee, H. Jeong, Y. J. Kim, H. J. Lee, S. Baek, J.-M. Oh, J. C. Park, and S. S. Lee, Samsung Advanced Institute of Technology (SAIT), KOREA

T.3.88

PATTERNED NANOMAGNETS ON-CHIP FOR SCREENING CIRCULATING TUMOR CELLS IN BLOOD
Y.-Y. Huang¹, P. Chen¹, K. Hoshino¹, C.-H. Wu¹, N. Lane², M. Huebschman², J. Uhr², K. Sokolov¹, E. Frenkel², and X. Zhang¹, ¹ The University of Texas at Austin, USA, and ²The University of Texas Southwestern Medical Center, USA

T.3.89

MICROFLUIDIC CELL SORTER AIDED LIVE CELL SCREENING FOR IMPROVED FLUORESCENT PROTEIN
Y. Zhao, H. Hoi, R. E. Campbell, and D. J. Harrison, University of Alberta, CANADA

T.3.90

DEVELPOEMENT OF NOVEL CIRCULATING TUMOR CELLS SEPARATION AND NON-LABELING DETECTION BY CIRCULATING TUMOR CELLS' SPECIFIC PROPERTIES
K. Ootsuka¹, Y. Okamoto¹, T. Hase¹, M. Tokeshi^1,2, N. Kaji¹, Y. Hasegawa¹, and Y. Baba^1,3, ¹ Nagoya University, JAPAN, ²Hokkaido University, JAPAN, and ³National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

T.3.91

IMMUNOMAGNETIC PURIFICATION OF CANCER CELLS FROM WHOLE BLOOD ON A CENTRIFUGAL MICROFLUIDIC PLATFORM
D. Kirby¹, G. Kijanka¹, J. Siegrist¹, R. Burger¹, O. Sheils², J. O'Leary², and J. Ducrée¹, ¹ Dublin City University, IRELAND, and ²Trinity College, IRELAND

T.3.92

TRAPPING SINGLE CELLS IN MICROFLUIDIC DEAD ZONE BY USING PEG-BASED OPTOELECTRONIC TWEEZERS FOR IMMUNE ACTIVITY
L.-Y. Ke¹, Z.-K. Kuo², Y.-S. Chen¹, H.-W. Tseng², and C.-H. Liu¹, ¹ National Tsing Hua University, TAIWAN, and ²Industrial Technology Research Institute, TAIWAN

T.3.93

AN APPLICATION OF INTERDIGITATED ARRAY OF Pt ELECTRODES FOR ELECTRICAL STIMULATION OF ENGINEERED MUSCLE TISSUE
S. Ahadian¹, J. Ramón-Azcón¹, S. Ostrovidov¹, H. Kaji¹, H. Shiku¹, A. Khademhosseini^1,2, and T. Matsue¹, ¹ Tohoku University, JAPAN, and ²Brigham and Women's Hospital, Harvard Medical School and Massachusetts Institute of Technology, USA

T.3.94

SKELETAL MUSCLE TISSUE IMPROVEMENT BY CO-CULTURE SYSTEM IN GELATIN METHACRYLATE HYDROGEL
S. Ostrovidov¹, S. Ahadian¹, H. Kaji¹, M. Ramalingam^1,2, and A. Khademhosseini^1,3, ¹ Tohoku University, JAPAN, ²University of Strasbourg, FRANCE, and ³Brigham and Women's Hospital, Harvard Medical School and Massachusetts Institute of Technology, USA

T.3.95

THREE-DIMENSINAL NEURON CULTURE METHOD CONTROLLING THE DIRECTION OF NEURITE ELONGATION AND THE POSITION OF SOMA
A. Odawara, I. Suzuki, A. Alhebshi, and M. Gotoh, Tokyo University of Technology, JAPAN

T.3.96

THREE-DIMENSIONAL MECHANICAL COMPRESSION OF BIOMATERIALS IN A MICROFABRICATED BIOREACTOR WITH ON-CHIP STRAIN SENSORS
L. MacQueen, O. Chebotarev, M. Chen, J. Usprech, Y. Sun, and C. A. Simmons, University of Toronto, CANADA

T.3.97

SINGLE NEURON OBSERVATION IN A 3D NEURONAL TISSUE BLOOK
M. Kato-Negishi^1,2, H. Onoe^1,2, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²Japan Science and Technology (JST), JAPAN

T.3.98

SELF-VASCULAIZING THREE DIMENSIONAL COLLAGEN BY RECOMBINANT BACTERIOPHAGES
J. Yoon¹, N. Korkmaz², S. Han¹, C.-H. Nam², and S. Chung¹, ¹ Korea University, KOREA, and ²Korea Institute of Science and Technology in Europe, GERMANY

T.3.99

DIFFERENTIATION OF MULTIPOTENT DFAT CELLS INTO SMOOTH MUSCLE-LIKE CELLS IN 3D TUBULAR MICROENVIRONMENT FOR TISSUE REGENERATION APPLICATIONS
A. Y. Hsiao¹, T. Okitsu^1,2, H. Onoe^1,2, M. Kiyosawa², H. Teramae³, S. Iwanaga², S. Miura², T. Kazama⁴, T. Matsumoto⁴, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, ²Japan Science and Technology Agency (JST), JAPAN, ³Shumei University, JAPAN, and ⁴Nihon University School of Medicine, JAPAN

T.3.100

FABRICATION AND SELF-ASSEMBLY OF MOVABLE MICROSTRUCTURES EMBEDDING CELLS INSIDE MICROFLUIDIC DEVICES
T. Yue, M. Nakajima, C. Hu, Y. Shen, H. Tajima, and T. Fukuda, Nagoya University, JAPAN

T.3.101

BIO-HYBRID CAPILLARY PULSATION DRIVEN BY A HEART MUSCLE OF INSECT
K. Funakoshi¹, Y. Akiyama¹, T. Hoshino¹, K. Iwabuchi², and K. Morishima¹, ¹ Osaka University, JAPAN, and ²Tokyo University of Agriculture and Technology, JAPAN

T.3.102

PHOTODYNAMIC THERAPY PROCEDURES ON LUNG CARCINOMA AND NORMAL CELLS COCULTURE IN THE MICROFLUIDIC SYSTEM
E. Jedrych, I. Grabowska-Jadach, M. Chudy, A. Dybko, and Z. Brzozka, Warsaw University of Technology, POLAND

T.4.103

ATTOLITER LIQUID CHROMATOGRAPHY USING EXTENDED-NANO CHANNEL FOR SEPARATION OF PROTEINS IN A SINGLE CELL
H. Shimizu¹, R. Ishibashi¹, K. Mawatari^1,2, and T. Kitamori^1,2, ¹ The University of Tokyo, JAPAN, and ²CREST, Japan Science and Technology Agency, JAPAN

T.4.105

MICROFLUIDIC DEVICES FOR FRACTIONATION OF DNA FRAGMENTS
K. Sun¹, Z. Li¹, K. Ueno², N. Ren¹, and H. Misawa², ¹ Harbin Institute of Technology, CHINA, and ²Hokkaido University, JAPAN

T.4.106

ON-CHIP NANOFILTERS FOR BIOLOGICAL SAMPLE PRE-TREATMENT FOR ELECTROPHORETIC ANALYSIS OF SMALL MOLECULES IN WHOLE BLOOD
A. Shallan, A. Gaudry, R. Guijt, and M. Breadmore, University of Tasmania, AUSTRALIA

T.4.107

DEVELOPMENT OF A HIGHLY-RELIABLE METAL MICROCHANNEL PLATE APPICABLE TO SEPARATION COLUMN OF GAS CHROMATOGRAPHY
M. Kanai, M. Nishino, S. Matsuoka, T. Nishimoto, and M. Ueda, Shimadzu Corporation, JAPAN

T.4.108

AUTOMATED MICROFLUIDIC SYSTEM FOR RNA PURIFICATION USING A CENTRIFUGAL FORCE
B. H. Park¹, J. H. Jung¹, H. Zhang², N. Y. Lee², and T. S. Seo¹, ¹ Korea Advanced Institute of Science and Technology (KAIST), KOREA, and ²Gachon University, KOREA

T.4.109

THE EFFECT OF MATRIX ORDER IN DNA CAPILLARY ZONE ELECTROPHORESIS
W. Ye, and D. J. Harrison, University of Alberta, CANADA

T.4.110

MAGNETICALLY-ACTUATED BLOOD FILTER UNIT ATTACHABLE TO BIOCHIPS
K. H. Chung, and Y. H. Choi, Electronics and Telecommunications Research Institute, KOREA

T.4.111

PORTABLE LIQUID CHROMATOGRAPHY SYSTEM BASED ON BATTERY-POWERED ELECTROOSOMOTIC PUMP AND MICROCHIP WITH PACKED COLUMN AND ELECTROCHEMICAL DETECTOR
A. Ishida¹, T. Fujimoto¹, S. Yokogawa¹, H. Tani¹, M. Tokeshi¹, and I. Yanagisawa², ¹ Hokkaido University, JAPAN, and ²Nano Fusion Technologies (present affiliation, Science Solutions International Laboratory), JAPAN

T.4.112

NANOPILLAR PARALLEL-ARRAY STRUCTURE WITH DNA TRAPPING AND TORQUE-ASSISTED ESCAPE MODE FOR DNA SEPARATION
T. Yasui¹, K. Motoyama¹, N. Kaji¹, Y. Okamoto¹, M. Tokeshi^1,2, Y. Horiike³, and Y. Baba^1,4, ¹ Nagoya University, JAPAN, ²Hokkaido University, JAPAN, ³National Institute for Materials Science, JAPAN, and ⁴National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

T.4.113

YIELD IMPROVEMENT BY AN EFFECTIVE MICROREACTOR FOR PHOTOREACTIONS USING A BLACK ALUMINUM OXIDE CHANNEL SUBSTRATE
Y. Asano¹, S. Togashi¹, and Y. Endo², ¹ Hitachi, Ltd., JAPAN, and ²Hitachi Plant Technologies, Ltd., JAPAN

T.4.114

AUTOMATIC ELISA ANALYTICAL SYSTEM FOR A TRACE AMOUNT OF ENVIRONMENTAL CHEMICALS USING A 3-DIMENSIONAL MICROREACTOR WITH A NOVEL ANTIGEN-BOUND MICROFILTER
M. Takeo¹, I. Kawaji¹, A. Nakasuji¹, T. Tone¹, Y. Ukita², D. Kato¹, S. Negoro¹, S. Yusa¹, M. Katayama³, and Y. Utsumi¹, ¹ University of Hyogo, JAPAN, ²Japan Advanced Institute of Science and Technology, JAPAN, and ³Innovation Core SEI, Inc., USA

T.4.115

DISRUPTION OF BACTERIAL SPORES BY SUPERHEATING - A METHOD FOR FAST DNA RELEASE
M. O. Altmeyer¹, A. Přibylka^1,2, A. V. Almeida¹, P. Neužil^1,2, J. Petr², J. Ševčík², and A. Manz¹, ¹ KIST Europe, GERMANY, and ²CPTM at UPOL, CZECH REPUBLIC

T.4.116

INTEGRATED HEATING AND COOLING MULTI-ZONE SILICON MICROREACTOR (MZSM) FOR INCREASED MONODISPERSITY IN TiO₂ NANOPARTICLE SYNTHESIS
E. Y. Erdem, J. C. Cheng, F. M. Doyle, and A. P. Pisano, University of California at Berkeley, USA

T.4.117

CHEMICAL SCREENING FOR SINGLE BACTERIAL ACTIVITY USING BACTERIA IMMOBILIZATION INTO MICROPOROUS
T. Kano, T. Inaba, K. Higashi, and N. Miki , Keio University, JAPAN

T.4.118

GENERATION, SEPARATION, AND REACTIONS OF ETHYL DIAZOACETATE USING INTEGRATED MICROFLUIDIC SYSTEM
R. A. Maurya^1,2, K.-I. Min¹, and D.-P. Kim¹, ¹ Pohang University of Science and Technology, KOREA, and ²CSIR-Indian Institute of Chemical Technology, INDIA

T.4.119

MICRO-FLOW REACTION SYSTEMS FOR PHOTOCATALYTIC CARBON DIOXIDE RECYCLING AND HYRDROGEN GENERATION
Y. Matsushita^1,2, H. M. A. Mohamed¹, and S. Ookawara^1,2, ¹ Egypt-Japan University of Science and Technology, EGYPT, and ²Tokyo Institute of Technology, JAPAN

T.4.120

DROPLET-BASED MICROFLUIDIC SYNTHESIS OF GIANT UNI-LAMELLAR LIPID VESICLES CONTAINING QUANTUM DOTS
Y.-H. Park, D.-H. Lee, E. Um, and J.-K. Park, KAIST, KOREA

T.4.121

MICROFLUIDIC SYNTHESIS OF METAL ORGANIC FRAMEWORKS CRYSTALS INTO CONFINED MICRODROPLETS
M. Faustini¹, J. Kim², W.-S. Ahn², and D. P. Kim¹, ¹ Pohang University of Science and Technology, KOREA, and ²Inha University, KOREA

T.4.122

PHARMACEUTICAL CRYSTAL ENGINEERING IN MICROFLUIDIC EMULSIONS
A. I. Toldy¹, A. Z. M. Badruddoza², L. Zheng², T. A. Hatton^1,3, R. Gunawan⁴, R. Rajagopalan^1,2, and S. A. Khan^1,2, ¹ Singapore-MIT Alliance, SINGAPORE, ²National University of Singapore, SINGAPORE, ³Massachusetts Institute of Technology, USA, and ⁴ETH Zürich, SWITZERLAND

T.4.123

AN APROACH FOR SINGLE CRYSTALLIZATION OF PROTEIN BY USING DROPLET BASED MICROFLUIDICS
M. Maeki¹, Y. Teshima¹, S. Yosizuka¹, H. Yamaguchi², K. Yamashita^1,3, H. Maeda³, and M. Miyazaki^1,3, ¹ Kyushu University, JAPAN, ²Tokai University, JAPAN, and ³AIST, JAPAN

T.5.124

COMPUTER AIDED MICROFLUIDICS (CAMF) – HIGH-RESOLUTION PROJECTION LITHOGRAPHY FOR THE RAPID CREATION OF LARGE-SCALE MICROFLUIDIC STRUCTURES
A. Waldbaur, B. Carneiro, P. Hettich, and B. E. Rapp, Institute of Microstructure Technology (IMT), Karlsruhe Institute of Technology (KIT), GERMANY

T.5.125

A ROOM-TEMPERATURE BONDING OF GLASS NANOFLUIDIC CHIPS UTILIZING A SURFACE ACTIVATION WITH A FLUORINE-CONTAINING PLASMA TREATMENT
Y. Xu¹, C. Wang², K. Jang², L. Li², N. Matsumoto¹, Y. Dong², K. Mawatari², T. Suga², and T. Kitamori², ¹ Osaka Prefecture University, JAPAN, and ²The University of Tokyo, JAPAN

T.5.126

FLEXIBLE AND FREE-STANDING POLYMERIC MEMBRANES WITH MULTI-DIMENSIONAL PORES FOR A MICROFLUIDIC APPLICATION
H. Cho, H. Park, J. S. Kim, H. Jung, and K.-Y. Suh, Seoul National University, KOREA

T.5.127

SURFACE TREATMENTS OF SOFT MOLDS FOR HIGH ASPECT RATIO MOLDING OF POLY-PEGDA
D. Castro, D. Conchouso, Y. Fan, and I. G. Foulds, King Abdullah University of Science and Technology (KAUST), SAUDI ARABIA

T.5.128

FABRICATION OF PMMA MICROPILLARS BY REACTIVE ION ETCHING TOWARDS SEPARATION OF WHITE AND RED BLOOD CELLS
S. Ito¹, T. Yasui¹, Y. Okamoto¹, N. Kaji¹, M. Tokeshi^1,2, and Y. Baba^1,3, ¹ Nagoya University, JAPAN, ²Hokkaido University, JAPAN, and ³National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

T.5.129

DEVELOPMENT OF FLUORINE INDUCED PLASMA ACTIVATING ROOM-TEMPERATURE BONDING STRATAGE FOR HIGH-PRESSURE MICRO-NANO FLUIDIC DEVICES
K. Jang¹, C. Wang^1,3, Y. Xu², and T. Kitamori^1,3, ¹ The University of Tokyo, JAPAN, ²Research Organization for the 21st Century, JAPAN, and ³Japan Science and Technology Agency (JST), JAPAN

T.5.130

DEVELOPMENT OF A CARBON MICROCHANNEL INTEGRATED WITH A HORIZONTAL CARBON SANDWICH ELECTRODE PAIR FOR ULTRA SENSITIVE ELECTROCHEMICAL/BIO SENSORS
J.-I. Heo¹, Y. Lim¹, B. Lee¹, M. Madou², and H. Shin¹, ¹ UNIST (Ulsan National Institute of Science & Technology), KOREA, and ²University of California, Irvine, USA

T.5.131

LOW COST INTEGRATION OF 3D-ELECTRODES VIA REPLICA MOLDING
B. Mustin, and B. Stoeber, The University of British Columbia, CANADA

T.5.132

FABRICATION OF TUNABLE WRINKLE PATTERNED MICROPARTICLE VIA SILICA-COATING
H. J. Bae¹, A. Lee¹, S. Han¹, L. N. Kim², S. Kwon¹, and W. Park³, ¹ Seoul National University, KOREA, ²Konkuk University, KOREA, and ³Kyung Hee University, KOREA

T.5.133

FLEXIBLE MICRONEEDLE ELECTRODE ARRAY BASED-ON PARYLENE SUBSTRATE
R. Wang¹, Z. Wei², W. Wang¹, and Z. Li¹, ¹ Peking University, CHINA, and ²National Center for Nanoscience and Technology, CHINA

T.5.134

PHOTO-IMMOBILIZATION OF CELLS FOR IN SITU DNA ANALYSIS
N. Sasaki, A. Isu, R. Ishii, and K. Sato, Japan Women's University, JAPAN

T.5.135

HYDROPHILIC POLYMERIC COATINGS FOR ENHANCED, SERIAL-SIPHON BASED FLOW CONTROL ON CENTRIFUGAL LAB-ON-A-DISC PLATFORMS
M. Kitsara², C. Nwankire^1,2, A. O'Reilly², J. Siegrist¹, G. G. Donohoe^1,2, X. Zhang^1,2, R. O'Kennedy^1,2, and J. Ducrée^1,2, ¹ National Centre for Sensor Research, IRELAND, and ²Dublin City University, IRELAND

T.5.136

RAPID PHOTOCHEMICAL SURFACE PATTERNING OF PROTEINS IN THIOL-ENE BASED MICROFLUIDIC DEVICES
J. P. Lafleur¹, R. Kwapiszewski², T. G. Jensen¹, and J. P. Kutter¹, ¹ Technical University of Denmark, DENMARK, and ²Warsaw University of Technology, POLAND

T.5.138

FABRICATION OF PAPER-BASED MICROFLUIDIC DEVICES BY OCTADECYLTRICHLOROSILANE SELF-ASSEMBLING AND UV-PATTERNING
C. Ma, Z. Bai, Q. He, and H. Chen, Zhejiang University, CHINA

T.5.139

ACTIVE MICROMIXER USING A METALLIZED MICROTURBINE DRIVEN BY AN ULTRA-LOW POWER LASER
T. Ikegami¹, R. Ozawa¹, M. P. Stocker², J. T. Fourkas², and S. Maruo¹, ¹ Yokohama National University, JAPAN, and ²University of Maryland, USA

T.5.140

SOLUTE DIFFUSION THROUGH THE FIBROTIC TISSUE FORMED AROUND A PROTECTIVE CAGE SYSTEM FOR IMPLANTABLE SENSORS
H. Ito¹, G. S. Prihandana¹, K. Tanimura¹, Y. Hori², O. Soykan², R. Sudo¹, and N. Miki¹, ¹ Keio University, JAPAN, and ²Medtronic, Inc., JAPAN/USA

T.5.141

ON-CHIP CONTINUOUS ENUCLEATION BY HYDRAULIC FORCE CONTROL USING MAGNETICALLY ACTUATED MICROROBOT
L. Feng¹, M. Hagiware², A. Ichikawa¹, and F. Arai¹, ¹ Nagoya University, JAPAN, and ²University of California, Los Angeles, USA

T.5.142

ALL GLASS-BASED ACTUATOR FOR VALVES AND PUMPS USING ULTRA THIN GLASS MEMBRANE AND PIEZO ACTUATORS
Y. Tanaka, RIKEN, JAPAN

T.5.143

AN ELECTRONIC PIPETTE COMPATIBLE MICROFLUIDIC CHIP FOR CONTINUOUS PROCESSING OF SIZE-DEPENDENT CELL DEPLETION AND IMMUNOHISTOCHEMISTRY
S. Kaneda^1,2, A. Araki^1,2, and T. Fujii^1,2, ¹ University of Tokyo, JAPAN, and ²JST-CREST, JAPAN

T.5.144

LIVER SPECIFIC FUNCTION ENHANCEMENT BY MICROVASCULAR SYSTEM INTEGRATED WITHIN A LAB-ON-CHIP DEVICE
K.-W. Chang, C.-T. Lee, S. Sivashankar, T.-S. Chen, P.-Y. Chang, S. V. Puttaswamy, and C.-H. Liu, National Tsing-Hua University, TAIWAN

T.5.145

ON-DEMAND DRUG RELEASE DEVICE: AN ELECTROPHORETIC APPROACH
Y.-T. Yi, Y.-C. Liao, Y.-W. Lu, and S.-S. Chen, National Taiwan University, TAIWAN

T.6.146

MULTI-STEP MIXING IN EXTENDED NANOSPACE BY CONTINUOUS FLOW CHEMICAL PROCESSING WITH EFFECT OF ION HYDRATION ON LIQUID PROPERTY
K. Kasai, Y. Kazoe, K. Morikawa, K. Mawatari, and T. Kitamori, The University of Tokyo, JAPAN

T.6.147

ENHANCED ELECTROPHORETIC TRANSPORT VIA NOISE-SYNCHRONIZED NANOSCALE ENTROPIC TRAPPING
N. Shi, and V. M. Ugaz, Texas A&M University, USA

T.6.148

IMMOBILIZATION AND ISOLATION OF EXOSOMES USING POLYETHYLENE GLYCOL-LIPID-MODIFIED SURFACE IN A MICROCHANNEL AND EVALUATION BY ATOMIC FORCE MICROSCOPY
T. Akagi, M. Sasaki, M. Kobayashi, and T. Ichiki, The University of Tokyo, JAPAN

T.6.149

SINGLE-MOLECULE IMAGING DEVICE USING LOCALIZED EVANESCENT ILLUMINATION IN POLYMERIC NANOHOLES
T. Ono^1,2,3, R. Iizuka^1,3, T. Akagi^1,3, T. Funatsu^1,3, and T. Ichiki^1,3, ¹ The University of Tokyo, JAPAN, ²Japan Society for the Promotion of Science, JAPAN, and ³Japan Science and Technology Agency, JAPAN

T.6.150

HIGH-THROUGHPUT PROTEIN MICROARRAYS: FEATURE SIZE EFFECTS ON PRINTING ARRAYS WITH IN SITU PROTEIN SYNTHESIS
Y. Tanaka¹, M. Biyani^1,2, T. Akagi^1,2, and T. Ichiki^1,2, ¹ The University of Tokyo, JAPAN, and ²Core Research of Evolutional Science and Technology, JST, JAPAN

T.6.151

SPOT-SELECTIVE DNA RECOVERY FROM DNA MICROARRAY CHIPS FOR ON-CHIP DIRECTED EVOLUTION
S. Ueno^1,2,3, A. Ono¹, R. Kobayashi¹, Y. Tanaka¹, S. Sato¹, M. Biyani^1,3, N. Nemoto^2,3, and T. Ichiki^1,3, ¹ The University of Tokyo, JAPAN, ²Saitama University, JAPAN, and ³Core Research of Evolutional Science and Technology, JST, JAPAN

T.6.152

MANIPULATION OF HUMAN MESENCHYMAL STEM CELLS BY MULTIFUNCTIONAL GRAPHENE-PEDOT MICROELECTRODE ARRAYS
Y.-S. Hsiao, C.-W. Kuo, C.-W. Chu, and P. Chen, Academia Sinica, TAIWAN

T.6.154

VISUALIZING THE GROWTH AND DYNAMICS OF LIQUID ORDERED DOMAINS DURING LIPID BILAYER FOLDING IN A MICROFLUIDIC CHIP
E. L. Kendall, C. Shao, and D. L. DeVoe , University of Maryland, USA

T.6.155

ALIGNING NANOWIRES BY STANDING SURFACE ACOUSTIC WAVES
Y. Chen¹, X. Ding¹, S.-C. S. Lin¹, S. Yang¹, P.-H. Huang¹, N. Nama¹, Y. Zhao¹, A. A. Nawaz¹, F. Guo¹, L. Wang², and T. J. Huang¹, ¹ The Pennsylvania State University, USA, and ²Ascent Bio-Nano Technologies Inc. State College, USA

T.7.156

DETECTION OF THE UNDERWATER MUCUS BY USING LASER RAMAN SPECTROSCOPY
K. Sato^1,2, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²ERATO Takeuchi Biohybrid Innovation Project, JAPAN

T.7.157

A NOVEL DETECTION PLATFORM FOR PARALLEL MONITORING OF DNA HYBRIDIZATION WITH HIGH SENSITIVITY AND SPECIFICITY
Y. Sun¹, I. Perch-Nielsen², Z. Wang³, D. D. Bang¹, and A. Wolff¹, ¹ Technical University of Denmark, DENMARK, ²Delta, DENMARK, and ³Peking University, CHINA

T.7.158

BLOOD COAGULATION TESTING METHOD BASED ON FLOW VELOCITY MEASUREMENT USING A SURFACE PLASMON RESONANCE (SPR)-BASED MICROFLUIDIC DEVICE
K. Hayashi, S. Inoue, Y. Iwasaki, M. Seyama, T. Horiuchi, and E. Tamechika, Nippon Telegraph and Telephone Corporation, JAPAN

T.7.159

RAPID QUANTITATION OF C-REACTIVE PROTEIN AGGLUTINATION WITH ACOUSTIC-ENABLED MICROVORTICES
A. Doria, N. E. Martin, and A. P. Lee, University of California - Irvine, USA

T.7.160

"PEAK-TRACKING CHIP" (PTC) FOR BULK REFRACTIVE INDEX SENSING AND BIOARRAY SENSING
K. Bougot-Robin¹, S. Li¹, Y. Zhang¹, R. Kodzius^1,2,3, I.-M. Hsing¹, H. Benisty⁴, R. H. Austin⁵, and W. Wen^1,3, ¹ Hong-Kong University of Science and Technology, HONG KONG, ²King Abdullah University of Science and Technology, SAUDI ARABIA, ³KAUST-HKUST Micro/Nanofluidic Joint Laboratory, HONG KONG, ⁴Institut Optique Graduate School, FRANCE, and ⁵Princeton University, USA

T.7.161

ANALOG IMAGE SENSOR FOR HIGHLY-SENSITIVE SPECTROSCOPIC IMAGING
Y. Fujii, and A. Hibara, The University of Tokyo, JAPAN

T.7.162

OPTOFLUIDIC DEVICE FOR HIGH RESOLUTION VOLUME REFRACTIVE INDEX MEASUREMENT OF SINGLE CELL
A. Leblanc-Hotte, R. St-Gelais, and Y.-A. Peter, École Polytechnique de Montréal, CANADA

T.7.163

LIGHT-DRIVEN MICROFLUIDICS TOWARDS SOLAR-POWERED POINT-OF-CARE DIAGNOSTICS
L. Jiang, M. Mancuso, and D. Erickson, Cornell University, USA

T.7.164

NANO-OPTOFLUIDIC WAVEGUIDES WITH SUPER-RESOLUTION LIQUID GAP COUPLING FOR BIOMOLECULAR APPLICATIONS
L. K. Chin, Y. Yang, and A. Q. Liu, Nanyang Technological University, SINGAPORE

T.7.165

MONOLITHIC WAVEGUIDE ARRAY PLATFORM FOR PHOTONIC CHARACTERISATION OF BIOLOGICAL SAMPLE
A. Ma, G. Matmon, D. Holmes, and G. Aeppli, University College London, UK

T.7.166

ELECTROCHEMILUMINESCENCE CHIP FOR METHYL-CYTOSINE DETERMINATION IN DNA
R. Kurita, and O. Niwa, National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

T.7.167

LOCAL REDOX CYCLING-BASED ELECTROCHEMICAL CHIP DEVICEFOR HIGH-THROUGHPUT ASSAY TOWARD EVALUATING EMBRYOID BODIES
K. Ino, T. Nishijo, Y. Kanno, H. Shiku, and T. Matsue, Tohoku University, JAPAN

T.7.168

MULTICHANNEL IMPEDIMETRIC BIOSENSOR PLATFORM FOR LABEL-FREE AFFINITY ASSAYS USING ELECTRICALLY CONDUCTIVE FUNCTIONAL POLYMERS
L. Pires, A. Heckel, K. Sachsenheimer, and B. E. Rapp, Karlsruhe Institute of Technology (KIT), GERMANY

T.7.169

STUDY ON ON-CHIP MASS SPECTROMETRY IN A LOW VACUUM OPERATION
K. Sugiyama, H. Harako, Y. Ukita, and Y. Takamura, Japan Advanced Institute of Science and Technology (JAIST), JAPAN

T.7.170

ENHANCEMENT OF NMR SENSITIVITY IN NANOLITER SAMPLES BY DYNAMIC NUCLEAR POLARIZATION AND MICROCOILS FABRICATED ON CAPILLARIES BY SHADOW MASK LITHOGRAPHY
P. Kurek¹, G. van der Heijden², J. van Bentum², A. Kentgens², and H. Gardeniers¹, ¹ University of Twente, THE NETHERLANDS, and ²Radboud University Nijmegen, THE NETHERLANDS

T.8.171

ELECTRONIC MICROFLUIDIC BIOCHIPS WITH IMMUNE-LIKE BIOSENSORS FOR RAPID DETECTION OF C-REACTIVE PROTEIN IN HUMAN SERUM
C.-C. Hong¹, C.-P. Chen², J.-C. Horng¹, S.-Y. Chen¹, C.-H. Tsai¹, W. Chung¹, and Y.-X. Chen¹, ¹ National Tsing Hua University, TAIWAN, and ²Mackay Memorial Hospital, TAIWAN

T.8.173

LAB-ON-A-SYRINGE DIAGNOSIS OF KAPOSI'S SARCOMA IN THE DEVELOPING WORLD
M. Mancuso¹, L. Jiang¹, E. Cesarman², and D. Erickson¹, ¹ Cornell University, USA, and ²Weill Cornell Medical College, USA

T.8.175

CONCENTRATION OF WHITE BLOOD CELLS FROM WHOLE BLOOD BY DUAL CENTRIFUGO-PNEUMATIC SIPHONING WITH DENSITY GRADIENT MEDIUM
D. J. Kinahan, M. T. Glynn, S. M. Kearney, and J. Ducrée, Dublin City University, IRELAND

T.8.177

RAPID TWO-STEP BLOOD SAMPLE PREPARATION WITH ACOUSTIC MICROFLUIDIC CHIPS
A. Doria, N. E. Martin, and A. P. Lee, University of California - Irvine, USA

T.8.178

HYBRID PAPER-POLYMER LAB-ON-A-DISC FOR BIOASSAY INTEGRATION
N. Godino, E. Vereshchagina, R. Gorkin III, and J. Ducrée, Dublin City University, IRELAND

T.8.179

RAPID ASSAY SYSTEM FOR INSULIN AND GLUCOSE IN WHOLE BLOOD BY USING A FULL AUTOMATED POSTAGE-STAMP-SIZE CHIP: POSSIBLE APPLICATION FOR A REALTIME FITNESS INDEX IN PEOPLE WITH METABOLIC SYNDROME
S. Shiohara¹, Y. Ukita¹, H. Ushijima², Y. Fukumura³, T. Takamura⁴, and Y. Takamura¹, ¹ Japan Advanced Institute of Science and Technology, JAPAN, ²Bio-device Technology Ltd., JAPAN, ³Komatsu Electronics Co., Ltd., JAPAN, and ⁴Kanazawa University, JAPAN

T.8.180

MICROFLUIDIC PURIFICATION OF EXTRACELLULAR VESICLES FROM RAW BLOOD SAMPLES
R. T. Davies, J. Kim, Y. Gho, and J. Park, POSTECH, KOREA

T.8.181

HANDHELD ANALYZER WITH DISPOSALBE LAB-ON-CHIPS FOR ELECTRICAL DETECTION OF ANESTHETIC PROPOFOL IN HUMAN SERUM
C.-C. Hong¹, C.-C. Lin², C.-L. Hong², Z.-X. Lin¹, M.-H. Chung¹, and P.-W. Hsieh³, ¹ National Tsing Hua University, TAIWAN, ²Chang Gung Memorial Hospital, TAIWAN, and ³Chang Gung University, TAIWAN

T.8.182

LABDISK INTEGRATED DNA EXTRACTION FROM WHOLE BLOOD USING MAGNETIC PARTICLES
S. Wadle¹, O. Strohmeier², M. Rombach², D. Mark¹, R. Zengerle^1,2, and F. von Stetten^1,2, ¹ University of Freiburg, GERMANY, and ²Institut für Mikro- und Informationstechnik, GERMANY

T.8.183

CAPILLARY SENSOR ARRAY CHIP AS A "SAMPLE-TO-ANSWER" DEVICE FOR SIMPLE, RAPID, AND MULTIPLE COMPONENT ANALYSIS OF SERUM SAMPLE
Y. Kimura, T. G. Henares, S. Funano, T. Endo, and H. Hisamoto, Osaka Prefecture University, JAPAN

T.8.184

A DIGITAL MICROFLUIDIC APPROACH TO OIL-FREE MAGNETIC PARTICLE-BASED IMMUNOASSAYS
A. H. C. Ng¹, K. Choi¹, R. P. Luoma², J. M. Robinson², and A. R. Wheeler¹, ¹ University of Toronto, CANADA, and ²Abbott Diagnostics, USA

T.8.185

CHARACTERIZATION OF IRRIGATION DYNAMICS IN PASSIVE ULTRASONIC AND PRESSURIZED IRRIGATION METHODS IN A ROOT CANAL USING A MICROFLUIDIC DEVICE
W.-I. Wu¹, G. Layton², A. Kishen², and P. R. Selvaganapathy¹, ¹ McMaster University, CANADA, and ²University of Toronto, CANADA

T.8.186

VERIFAST: AN INTEGRATED SYSTEM FOR FLEXIBLE CTC ISOLATION AND ANALYSIS
B. P. Casavant, S. M. Berry, J. Lang, D. J. Guckenberger, and D. J. Beebe, University of Wisconsin – Madison, USA

T.8.187

INTEGRATED DNA PURIFICATION AND AMPLIFICATION USING FTA^® PAPER AND PCR REAGENT ENCAPSULATION
K. J. Shaw, R. Vasiliadou, J. Parton, N. Pamme, and S. J. Haswell, University of Hull, UK

T.8.188

HIGHLY FAST REAL-TIME PCR SYSTEM BASED ON RAPID THERMAL CYCLER AND 2-COLOR SCANNING OPTIC MODULE
W. Chung, K. Namkoong, C. Park, W. Jung, S. Jung, K.-H. Kim, J. S. Shim, K.-Y. Hwang, H. Lim, J.-H. Kim, and N. Huh, Samsung Electronics Co. Ltd., KOREA

T.8.189

AN INTEGRATED SELEX MICROFLUIDIC SYSTEM FOR RAPID SCREENING OF INFLUENZA VIRUS-SPECIFIC APTAMERS
H.-C. Lai, C.-H. Wang, C.-H. Weng, T.-M. Liou, and G.-B. Lee, National Tsing Hua University, TAIWAN

T.8.190

KINETICS OF INSULIN ADSORPTION FROM REAL TIME OF MEASUREMENTS IN A MICROFLUIDIC CHIP
S. Chebil¹, S. Méance¹, I. le Potier^2,3, A. Pallandre^2,3, and A.-M. Haghiri-Gosnet¹, ¹ Laboratoire de Photonique et de Nanostructures, FRANCE, ²Univ Paris Sud, FRANCE, and ³Insitut Galien Paris-Sud, FRANCE

T.8.191

INTEGRATED MICROFLUIDIC FLUIDIZED BED FOR SAMPLE PRECONCENTRATION AND IMMUNOEXTRACTION
S. Tabnaoui, L. Malaquin, S. Descroix, and J.-L. Viovy, Institut Curie, Centre de Recherche, CNRS, FRANCE

T.8.192

MICRO-CAPILLARY SYSTEMS INTEGRATING PHOTO-CONTROLLED MOLECULAR CRANES FOR METAL ION ACCUMULATION, SENSING AND RELEASE IN CONTINUOUS FLOW
L. Florea, D. Diamond, and F. Benito-Lopez, Dublin City University, IRELAND

T.8.193

SELF-INTEGRATION OF ION TRANSPORT TUNABLE NANOPOROUS MICROPLUGS IN A MICROFLUIDIC CHIP FOR ELECTROKINETIC BIO-SAMPLE CONCENTRATION
M. Kim, and T. Kim, Ulsan National Institute of Science and Technology (UNIST), KOREA

T.9.194

NANO DESALINATOR BY ELECTROSTATIC ION SIEVING FOR LOW-POWER WATER PURIFICATION
C.-Y. Lin¹, Y.-S. Huang¹, C.-J. Chang^1,3, W.-C. Chang¹, Y.-L. Chueh¹, and F.-G. Tseng^1,2, ¹ National Tsing Hua University, TAIWAN, ²Academia Sinica, TAIWAN, and ³ITRI South / Microsystem Technology Center, TAIWAN

T.9.195

MICROFLUIDIC GAS/LIQUID TOXICITY SENSING THROUGH THE CHEMOTAXIS OF EUGLENA CELLS CONFINED IN A MICRO-AQUARIUM
K. Ozasa¹, J. Lee², S. Song², M. Hara¹, and M. Maeda¹, ¹ RIKEN Advanced Science Institute, JAPAN, and ²Hanyang University, KOREA

T.9.196

GOLD NANOPARTICLE-BASED FLUORESCENT SENSOR FOR THE ANALYSIS OF DITHIOCARBAMATE PESTICIDES IN WATER
S. Senkbeil, J. P. Lafleur, T. G. Jensen, and J. P. Kutter , Technical University of Denmark, DENMARK

T.9.197

MICROFLUIDICALLY ENABLED HIGH-THROUGHPUT MONITORING OF ENVIRONMENTAL NANOPARTICLES
F. Meng, M. D. King, Y. A. Hassan, and V. M. Ugaz, Texas A&M University, USA

T.9.198

DRUG AUTHENTICATION USING HIGH CAPACITY AND ERROR-CORRECTABLE ENCODED MICROTAGGANTS
S. Han¹, H. J. Bae¹, J. Kim¹, S. Shin¹, S. Kwon¹, and W. Park², ¹ Seoul National University, KOREA, and ²Kyung Hee University, KOREA

T.9.199

ENZYME-BASED BIOFUEL CELL DESIGNED FOR DIRECT POWER GENERATION FROM BIOFLUIDS IN LIVING ORGANISMS
T. Miyake^1,2, S. Yoshino¹, T. Ofuji¹, H. Kaji¹, and M. Nishizawa^1,2, ¹ Tohoku University, JAPAN, and ²JST CREST, JAPAN

T.9.200

MICROFLUIDIC MICROBIAL FUEL CELLS FOR RAPID SCREENING OF ELECTROACTIVE MICROORGANISMS
Y.-Y. Chen¹, J.-Y. Su¹, C.-Y. Huang², and H.-Y. Wang¹, ¹ National Cheng Kung University, TAIWAN, and ²National Tsing Hua University, TAIWAN

T.9.201

DESIGN OPTIMIZATION, FABRICATION, AND FLOW EXPERIMENT OF 2.5D ROCK-BASED ARTIFCIAL POROUS MEDIA MICROMODEL
D. S. Park, S. Bou-Mikael, S. King, K. E. Thompson, C. S. Willson, and D. E. Nikitopoulos, Louisiana State University, USA

W.1.1

AN INTEGRATED MICROFLUIDIC DEVICE FOR HIGH-THROUGHPUT ELECTROPHYSIOLOGICAL ANALYSIS OF C. ELEGANS
C. Hu, V. O'Connor, L. Holden-Dye, and H. Morgan, University of Southampton, UK

W.1.2

HYDRODYNAMIC LEVITATION OF A MICROFLUIDIC PROBE FOR SAMPLE-HEAD DISTANCE CONTROL
R. D. Lovchik, G. V. Kaigala, and E. Delamarche, IBM Research GmbH, SWITZERLAND

W.1.3

NANO LAPLACE VALVE FOR FEMTOLITTER LIQUID GENERATION AND HANDLING REALIZED BY NANOPILLAR-IN-NANOCHANNEL FABRICATION AND SURFACE MODIFICATION
K. Mawatari¹, S. Kubota¹, Y. Xu², and T. Kitamori¹, ¹ The University of Tokyo, JAPAN, and ²Osaka Prefecture University, JAPAN

W.1.4

SAXS-LABDISK: A CENTRIFUGAL MICROFLUIDIC SCREENING PLATFORM FOR PROTEIN STRUCTURE ANALYSIS
F. Schwemmer¹, S. Zehnle², N. Paust², C. Blanchet³, M. Rössle³, F. V. Stetten^1,2, R. Zengerle^1,2, and D. Mark², ¹ University of Freiburg, GERMANY, ²HSG-IMIT - Institut für Mikro- und Informationstechnik, GERMANY, and ³EMBL Hamburg, GERMANY

W.1.5

MICROFLUIDIC PUMP BASED ON ARRAYS OF ROTATING MAGNETIC MICROSPHERES
W. T. E. van den Beld, E. L. de Weerd, L. Abelmann, J. G. Bomer, A. van den Berg, and J. C. T. Eijkel, Twente University, THE NETHERLANDS

W.1.6

GENERATION OF A MICROLIQUID CONCENTRATION SERIES USING WETTABILITY GRADIENT AND ELECTROWETTING
T. Yasuda, J. Nakamura, K. Nakayama, and M. Yamanaka, Kyushu Institute of Technology, JAPAN

W.1.7

FREE ACCESSIBLE MICROCHANNEL USING AIR-LIQUID INTERFACE WITH PATTERNED NANO-GEOMETRIC SURFACE BY HYBRID MASK LITHOGRAPHY
M. Sugita, S. Sakuma, and F. Arai, Nagoya University, JAPAN

W.1.8

FORMATION OF PARALLEL AQU/ORG TWO PHASE FLOW IN EXTENDED NANOCHANNEL BY PARTIAL MODIFICATION WITH MOLECULAR ABLATION USING EVANESCENT WAVE
H. Akaike, Y. Kazoe, K. Kasai, K. Mawatari, and T. Kitamori, The University of Tokyo, JAPAN

W.1.9

INTERNALLY TRIGGERD MULTISTEP FLOW SEQUENCERS USING CLEPSYDRA
Y. Ukita¹, M. Ishizawa², Y. Takamura¹, and Y. Utsumi², ¹ Japan Advanced Institute of Science and Technology (JAIST), JAPAN, and ²University of Hyogo, JAPAN

W.1.10

'ALL-INTO-ONE' CONCENTRATION: CASCADE ELECTROKINETIC PARTICLE FOCUSING FOR RARE SAMPLE DETECTION
M. Motosuke, K. Yamasaki, H. Toki, and S. Honami, Tokyo University of Science, JAPAN

W.1.11

MECHANICS OF PARTICLE TRAPPING AND MAINTENANCE IN MICRO-SCALE FLUID VORTICES
A. J. Mach, X. Yi, E. Sollier, H. Amini, D. E. Go, and D. Di Carlo, University of California, Los Angeles, USA

W.1.12

A STUDY OF LIQUID DYNAMIC RUPTURE IN MICROFLUIDICS
Z. G. Li¹, K. Ando², J. B. Zhang³, A. Q. Liu¹, and C. D. Ohl¹, ¹ Nanyang Technological University, SINGAPORE, ²Keio University, JAPAN, and ³A*STAR, SINGAPORE

W.1.13

SWITCHING OF SECONDARY FLOW BEHAVIOR ON CENTRIFUGAL MICROFLUIDICS
Y. Ukita, and Y. Takamura, Japan Advanced Institute of Science and Technology (JAIST), JAPAN

W.1.14

MEASURING THE 3D MOTION OF PARTICLES IN MICROCHANNEL ACOUSTOPHORESIS USING ASTIGMATISM PARTICLE TRACKING VELOCIMETRY
P. Augustsson¹, R. Barnkob², H. Bruus², C. J. Kähler³, T. Laurell¹, Á. G. Marín³, P. B. Muller², and M. Rossi³, ¹ Lund University, SWEDEN, ²Technical University of Denmark, DENMARK, and ³Universität der Bundeswehr München, GERMANY

W.1.15

ELECTRIC-FIELD INDUCED TIP STREAMING FOR SUB-FEMTOLITER DROPLET FORMATION
H.-H. Tsai, J.-J. Wang, and Y.-C. Su, National Tsing Hua University, TAIWAN

W.1.16

ELECTRIC CONTROL IN DROPLET-BASED MICROFLUIDICS
S. H. Tan, B. Semin, F. Maes, and J.-C. Baret, Max Planck Institute for Dynamics and Self-Organization (MPIDS), GERMANY

W.1.17

THREE-DIMENSIONAL MANIPULATIONS OF NANOLITER WATER-DROPS ON OPEN PLATFORMS USING MAGNETICALLY CONTROLLED HYDROPHOBIC FERRO-DROPS
K. Zhang, Q. Liang, and G. Luo, Tsinghua University, CHINA

W.1.18

SINGLE-MOLECULE ENZYMATIC ANALYSIS IN A DROPLET-BASED MICROFLUIDIC SYSTEM
R. Arayanarakool¹, L. Shui², S. W. M. Kengen³, A. van den Berg¹, and J. C. T. Eijkel¹, ¹ University of Twente, THE NETHERLANDS, ²South China Normal University, CHINA, and ³Wageningen University, THE NETHERLANDS

W.1.19

HIGH-THROUGHPUT PATTERNING OF SINGLE MAGNETIC BEADS USING DIGITAL MICROFLUIDIC TECHNOLOGY
D. Witters, K. Knez, K. Janssen, B. Verbruggen, R. Puers, and J. Lammertyn, KU Leuven, BELGIUM

W.1.20

LIQUID-IN-GAS DROPLET MICROFLUIDICS
K. Jiang, S. R. Raghavan, and D. L. DeVoe, University of Maryland, USA

W.1.21

PRODUCTION OF LIPID-CORE/MULTILAMELLAR-SHELL HYBRID LIPOSOMES UTILIZING NON-EQUILIBRIUM MICROFLUIDIC DROPLETS
M. Mizuno¹, M. Konishi¹, M. Yamada¹, T. Toyota², and M. Seki¹, ¹ Chiba University, JAPAN, and ²The University of Tokyo, JAPAN

W.1.22

HIGH-THROUGHPUT MUTIPLEXED PROTEASE ACTIVITY MEASUREMENT USING A DROPLET BASED MICROFLUIDIC PLATFORM WITH PICOINJECTOR
C.-H. Chen¹, M. A. Miller², A. Sarkar², M. T. Beste², D. A. Lauffenburger², L. G. Griffith², and J. Han², ¹ National University of Singapore, SINGAPORE, and ²MIT, USA

W.1.23

RIGHT TRIANGULAR PRISM-SHAPED POLY(DIMETHYLSILOXANE) (PDMS) MICRODEVICE FOR MULTIPLEX PCR EMPLOYING A SINGLE HEATER
W. Wu, K. T. L. Trinh, and N. Y. Lee, Gachon University, KOREA

W.1.24

ELECTROCHEMICAL DETECTION OF CANCER CELLS ON A CENTRIFUGAL MICROFLUIDIC PLATFORM
C. E. Nwankire, A. Venkatanarayanan, R. J. Forster, and J. Ducrée, Dublin City University, IRELAND

W.1.25

ACOUSTOFLUIDIC OPTICAL SWITCH
P.-H. Huang¹, M. I. Lapsley², D. Ahmed¹, M. Lu¹, L. Wang², and T. J. Huang¹, ¹ The Pennsylvania State University, USA, and ²Ascent Bio-Nano Technologies Inc., State College, USA

W.1.26

A MICROFLUIDIC DEVICE FOR TEMPERATURE-TRIGGERED DNA AMPLIFICATION IN AGAROSE MICROBEADS
L. Desbois, A. Padirac, Y. Rondelez, and T. Fujii, The University of Tokyo, JAPAN

W.1.28

SINGLE ISOLATED VESICLES IN MICROFLUIDIC TRAPS TO STUDY MEMBRANE PROTEIN KINETICS
T. Robinson, P. Kuhn, K. Eyer, and P. S. Dittrich, ETH Zurich, SWITZERLAND

W.1.29

MONODISPERSE DROPLET GENERATION USING ELECTRICAL PULSES
S. Shinwary, C. Y. Ching, and P. R. Selvaganapathy, McMaster University, CANADA

W.1.30

PEN MICROFLUIDICS: FROM DESIGN TO BONDED THERMOPLASTIC CHIPS IN UNDER 30 MINUTES
O. Rahmanian, and D. L. DeVoe, University of Maryland, USA

W.2.31

FABRICATING DNA MICROARRAYS BY COPYING A NEXT GENERATION SEQUENCING CHIP
J. Hoffmann^1,2, S. Hin¹, F. von Stetten^1,2, R. Zengerle^1,2, and G. Roth^1,2, ¹ University of Freiburg, GERMANY, and ²Institut für Mikro- und Informationstechnik, GERMANY

W.2.32

INTEGRATION OF TRANSCRIPTOMIC, PROTEOMIC AND METABOLOMIC PROFILES IN MICROFLUIDIC BIOARTIFICIAL ORGANS APPLIED TO MECHANISTIC INTERPRETATION OF ACETAMINOPHEN INJURY
J.-M. Prot¹, A. Bunescu², B. Elena-Herrmann², C. Aninat³, L. Griscom⁴, C. Legallais¹, A. Corlu³, M. E. Dumas², and E. Leclerc¹, ¹ Université de Technologie de Compiègne, FRANCE, ²Ecole Normale Supérieure de Lyon, FRANCE, ³Université de Rennes 1, FRANCE, and ⁴Ecole Normale Supérieure de Cachan-Bretagne, FRANCE

W.2.33

CONTROLLED DRUG RELEASE ANALYSIS OF MONOSIZED DRUG-LOADED PLGA MICROPARTICLES BY LIGAND-SENSITIZED FLUORESCENCE
H. G. Kim, J. H. Choi, G. M. Kim, K. M. Kim, S. H. Lee, and Y. H. Kim, Kyungpook National University, KOREA

W.2.34

YEAST-BASED LIGAND ASSAY SYSTEM FOR DETECTING G PROTEIN-COUPLED RECEPTOR ACTIVATION IN WATER-IN-OIL DROPLETS
T. Sakurai¹, R. Iizuka¹, Y. Tanigaki², R. Sekine³, D. H. Yoon³, T. Sekiguchi³, J. Ishii⁴, A. Kondo⁴, N. Nemoto^2,5, S. Shoji³, and T. Funatsu^1,5, ¹ The University of Tokyo, JAPAN, ²Saitama University, JAPAN, ³Waseda University, JAPAN, ⁴Kobe University, JAPAN, and ⁵Japan Science and Technology Corporation (JST), JAPAN

W.2.35

TOWARDS A "BODY ON A CHIP" USING SPHERICAL MICROTISSUES IN A MICROFLUIDIC NETWORK
O. Frey¹, S. Mohanty¹, W. Moritz², and A. Hierlemann¹, ¹ ETH Zurich, SWITZERLAND, and ²InSphero AG, SWITZERLAND

W.2.36

DEVELOPMENT OF A MICRO DIALYSIS SYSTEM FOR EVALUATION OF RENAL CLEARANCE
Y. Sakuta, K. Tsunoda, and K. Sato, Gunma University, JAPAN

W.2.37

HIGH THROUGHPUT PURIFICATION DEVICE FOR GENE DELIVERY MULTIFUNCTIONAL ENVELOPE-TYPE NANODEVICE
D. Shigenaka¹, M. Ukawa², N. Kaji¹, Y. Okamoto¹, M. Tokeshi^1,2, H. Akita², H. Harashima², and Y. Baba^1,3, ¹ Nagoya University, JAPAN, ²Hokkaido University, JAPAN, and ³National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

W.2.38

MICROFLUIDIC INVESTIGATION OF CELLULAR MECHANICAL DYSFUNCTION IN CAMPOMELIC DYSPLASIA
I. A. Eydelnant, M. Liao, and A. R. Wheeler, University of Toronto, CANADA

W.2.39

DIELECTROPHORETIC (DEP) CYTOMETER: LABEL-FREE ELECTRONIC SENSING OF PHYSIOLOGICAL CHANGES IN CELLS
M. Nikolic-Jaric, E. Salimi, T. Cabel, K. Braasch, M. Butler, G. E. Bridges, and D. J. Thomson, University of Manitoba, CANADA

W.2.40

CHARACTERIZATION OF NATURAL KILLER CELLS' CYTOTOXIC HETEROGENEITY USING AN ARRAY OF SONO-CAGES
A. E. Christakou¹, M. Ohlin¹, N. Kadri², T. Frisk¹, B. Önfelt^1,2, and M. Wiklund¹, ¹ Royal Institute of Technology, SWEDEN, and ²Karolinska Institute, SWEDEN

W.2.41

A NOVEL MICROFLUIDIC DESIGN TO GENERATE MULTIPLEX GRADIENTS OF BIOMOLECULES BY VISULIZED BIOMOLECULE PATTERNING AND DIRECT CELL ADHESION
T. F. Didar, and M. Tabrizian, McGill University, CANADA

W.2.42

THE SIGNIFICANCE OF NUCLEAR DEFORMATION FOR CANCER CELL TRANSMIGRATION
Y. Fu^1,2,3, A. Vandongen², T. Bourouina³, W. M. Tsang⁴, M. Je⁴, and A. Q. Liu¹, ¹ Nanyang Technological University, SINGAPORE, ²Duke-NUS Graduate Medical School, SINGAPORE, ³ESIEE, University of Paris Est, FRANCE, and ⁴A*Star, SINGAPORE

W.2.43

FOUR-STAGE MECHANISTIC MODEL OF DYNAMIC PLATELET AGGREGATION IN A MICROFLUIDIC CHIP
M. E. Combariza¹, F. J. Tovar-Lopez¹, W. S. Nesbitt², X. Yu¹, and A. Mitchell¹, ¹ RMIT University, AUSTRALIA, and ²Monash University, AUSTRALIA

W.2.44

CONTINUOUS LOCAL EXPOSURE TO CHEMICAL SUBSTANCES OF SINGLE CELL
K. Terao¹, M. Gel², A. Fuke¹, A. Okonogi¹, T. Okitsu¹, T. Tada¹, T. Suzuki¹, M. Washizu¹, and H. Kotera¹, ¹ Kagawa University, JAPAN, and ²The University of Tokyo, JAPAN

W.2.45

IN-SITU MEASUREMENT OF PHOTOSYNTHESIS USING SINGLE SYNECOCYSTIS SP. PCC 6803 IN A MICROCHAMBER WITH GAS BARRIER WALL
H. Maruyama¹, Y. Matsuda¹, T. Niimi¹, N. Unozumi², K. Nanatani², and F. Arai¹, ¹ Nagoya University, JAPAN, and ²Tohoku University, JAPAN

W.2.46

DEVELOPMENT OF A MICROFLUIDIC CONCENTRATION GRADIENT GENERATOR ON A MICROWELL SLIDE FOR HIGH-THROUGHPUT CELL ANALYSIS
E. Weibull¹, S. Matsui², H. Andersson-Svahn¹, and T. Ohashi², ¹ Royal Institute of Technology, SWEDEN, and ²Hokkaido University, JAPAN

W.2.47

QUANTITATIVE PHYSIOLOGY WITH ISOLATED SINGLE CELLS AND MICROPOPULATIONS IN CONTROLLED MICROENVIRONMENTS EMPLOYING A PICOLITER BIOREACTOR
C. Dusny, F. S. O. Fritzsch, K. Rosenthal, O. Frick, and A. Schmid, TU Dortmund University, GERMANY

W.2.48

MICROFLUIDIC PLATELET ANALYSIS PLATFORM BASED ON IMPEDANCE SPECTROSCOPY
M. Evander^1,2, A. J. Ricco², J. Morser^3,4, G. T. A. Kovacs^2,3, L. L. K. Leung^3,4, and L. Giovangrandi², ¹ Lund University, SWEDEN, ²Stanford University, USA, ³Stanford University School of Medicine, USA, and ⁴Veterans Affairs Palo Alto Health Care System, USA

W.2.49

HIGH-RESOLUTION LIVE CELL IMAGING OF THE YEAST LIFE CYCLE
O. Frey, F. Rudolf, and A. Hierlemann, ETH Zurich, SWITZERLAND

W.2.51

SPATIALLY PATTERNED NEURAL AND CARDIAC DIFFERENTIATION OF EMBRYOID BODY (EB) IN A MICROFLUIDIC DEVICE
X. He¹, H. Kimura¹, S. Kaneda¹, J. Kawada¹, H. Akutsu², Y. Sakai¹, and T. Fujii¹, ¹ The University of Tokyo, JAPAN, and ²National Research Institute for Child Health and Development, JAPAN

W.2.52

CONTROL OF SELF-FOLDING CELL-LADEN MICROPLATES BY CYTOSKELETON ALIGNMENT TO FIBRONECTIN PATTERNS
D. Serien¹, K. Kuribayashi-Shigetomi¹, S. Yoshida¹, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²Japan Science and Technology (JST), JAPAN

W.2.53

LARGE-SCALE SCREENING OF OLFACTORY SENSORY NEURONS WITH AN INTEGRATED MICROFLUIDIC PLATFORM
A. K. Au, L. F. Horowitz, D. R. Storm, and A. Folch, University of Washington, USA

W.2.54

HIGH-THROUGHPUT LINEAGE TREE INVESTIGATIONS OF BACTERIA MICROCOLONIES USING ARRAYS OF MONOLAYER GROWTH CHAMBERS
A. Grünberger, S. Helfrich, C. Probst, W. Wiechert, K. Nöh, and D. Kohlheyer, Forschungszentrum Jülich GmbH (Research Center Juelich), GERMANY

W.2.55

FORMATION OF CELL-SIZED VESICLES WITH ASYMMETRIC LIPID BILAYER USING PULSED JET FLOW
K. Kamiya¹, R. Kawano¹, T. Osaki¹, and S. Takeuchi^1,2, ¹ Kanagawa Academy of Science and Technology, JAPAN, and ²The University of Tokyo, JAPAN

W.2.56

LIPID BILAYER CHAMBER ARRAY FOR FLUORESCENT AND ELECTROCHEMICAL MEASUREMENT OF MEMBRANE PROTEINS
T. Tonooka¹, R. Kawano², K. Sato¹, T. Osaki², and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²Kanagawa Academy of Science and Technology, JAPAN

W.2.57

A TRANSDERMAL CONTINUOUS GLUCOSE MONITORING SYSTEM WITH AN IMPLANTABLE FLUORESCENT HYDROGEL FIBER AND A WEARABLE PHOTO-DETECTOR
M. Takahashi^1,3, Y. J. Heo², T. Kawanishi^1,3, T. Okitsu², and S. Takeuchi^1,2, ¹ BEANS Project, JAPAN, ²The University of Tokyo, JAPAN, and ³TERUMO Co., JAPAN

W.2.58

CONTINUOUS FLOW INFRARED POLYMERASE CHAIN REACTION (cfIR-PCR) USING AN INFRARED-MEDIATED HEATING SYSTEM AT CONSTANT POWER
K. Oh, J. A. Lounsbury, B. L. Poe, Z. Keshishian, and J. P. Landers, University of Virginia, USA

W.2.59

CO-RELATION OF CELLULAR AND BEHAVIORAL RESPONSES OF CAENORHABDITIS ELEGANS TO PULSE DC ELECTRIC FIELDS
P. Rezai, S.-C. A. Yeh, S. Salam, Q. Fang, B. P. Gupta, and P. R. Selvaganapathy, McMaster University, CANADA

W.2.60

MULTIPLEXED DRUG SCREENING USING PARTIPETTING
S. E. Chung, J. Kim, D. Oh, Y. Song, and S. Kwon, Seoul National University, KOREA

W.2.61

SILICON NANO TWEEZERS FOR REAL TIME BIOMECHANICAL ASSAY ON DNA DAMAGE BY THERAPEUTIC RADIATION BEAMS
D. Collard^1,4, T. Lacornerie², M. Kumemura^1,4, N. Lafitte^1,4, H. Guillou¹, L. Jalabert¹, E. Lartigau², T. Fujii^1,4, F. Cleri³, and H. Fujita^1,4, ¹ LIMMS/CNRS-IIS, UMI2820, JAPAN, ²University of Lille 2, FRANCE, ³University of Lille 1, FRANCE, and ⁴The University of Tokyo, JAPAN

W.2.62

ON-CHIP BIOLUMINECENCE ASSAY OF ATP AND KINASES USING IMMOBILIZED FIREFLY LUCIFERASE IN THREE-DIMENSIONAL MICROFLUIDIC CHIP
H. Tani, A. Morisaki, A. Ishida, and M. Tokeshi, Hokkaido University, JAPAN

W.3.63

BIOPHOTONIC LAB ON A CHIP WITH INTEGRATED SIZE-EXCLUSION MICROFILTERS FOR CELL PROLIFERATION MONITORING
X. Munoz-Berbel¹, R. Rodriguez-Rodriguez², S. Demming³, A. Al-Halhouli³, S. Buttgenbach³, E. Verpoorte⁴, P. Ortiz¹, and A. Llobera¹, ¹ Institut de Microelectronica de Barcelona (IMB-CNM, CSIC), SPAIN, ²Universidad de Sevilla, SPAIN, ³Technische Universitat Braunschweig, GERMANY, and ⁴University of Groningen, THE NETHERLANDS

W.3.64

INDUCING BACTERIAL BIOFILM FORMATION BY FLUID FORCES USING A MICROFLUIDIC SHEAR ARRAY
W. M. Weaver¹, V. Milisavljevic¹, J. F. Miller¹, and D. Di Carlo^1,2, ¹ University of California, Los Angeles, USA, and ²California NanoSystems Institute, USA

W.3.65

MICRODEVICE FOR CELL MIGRATION ASSAYS USING REVERSE-TRANSFECTION
J. Enomoto^1,2, R. Takagi¹, R. Nagasaki², H. Suzuki¹, S. Fujita², and J. Fukuda^1,2, ¹ University of Tsukuba, JAPAN, and ²National Institute of Advanced Industrial Science and Technology, JAPAN

W.3.66

A MICROFLUIDIC WOUND-HEALING ASSAY TO STUDY ENDOTHELIAL CELL PROLIFERATION AND MIGRATION UNDER OXYGEN GRADIENTS
H.-C. Shih¹, M.-C. Liu¹, T.-W. Weng², Y.-H. Chen¹, W.-H. Liao¹, and Y.-C. Tung¹, ¹ Academia Sinica, TAIWAN, and ²National Taiwan University, TAIWAN

W.3.67

GRAPHENE FOREST DEVICES AS CELL SCAFFOLDS FOR STEM CELLS
Y. Okamoto¹, H. Watanabe¹, K. Kubo¹, H. Kondo¹, N. Kaji¹, M. Tokeshi², M. Hori¹, and Y. Baba^1,3, ¹ Nagoya University, JAPAN, ²Hokkaido University, JAPAN, and ³National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

W.3.68

GENERATION OF DYNAMIC MICROENVIRONMENT IN A HYDROGEL-BASED MICROFLUIDIC DEVICE FOR CELL CULTURE STUDY
A. Al-Abboodi¹, R. Tjeung², P. D. Semper¹, L. Yeo¹, J. Friend¹, and P. Chan¹, ¹ Monash University, AUSTRALIA, ²Swinburne University of Technology, AUSTRALIA, and ³RMIT University, AUSTRALIA

W.3.70

GENERATING CELL CO-CULTURES BY RAPID CELL ADHESION ON OPPOSITE SIDES OF POLYESTER MEMBRANES
C. Hanke^1,2, P. S. Dittrich², and D. R. Reyes¹, ¹ National Institute of Standards and Technology, USA, and ²ETH Zurich, SWITZERLAND

W.3.71

MICROSCALE CULTURE AND ENRICHMENT OF CANCER STEM CELLS FOR DRUG DEVELOPMENT
C.-T. Kuo¹, C.-L. Chiang¹, C.-T. Wu¹, G.-S. Huang¹, R. Y.-J. Huang^2,3, H. Lee¹, and A. M. Wo¹, ¹ National Taiwan University, TAIWAN, ²National University Hospital, SINGAPORE, and ³National University of Singapore, SINGAPORE

W.3.72

BIOHYBRID MUSCLE FIBERS INTEGRATED IN ATHREE-DIMENSIONAL CELLULAR CONSTRUCT
Y. Morimoto¹, K. Kuribayashi-Shigetomi¹, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²Japan Science and Technology (JST), JAPAN

W.3.73

ENGINEERING STABLE MICRO-CAPILLARY STRUCTURES BY CONTROLLED 3D-COLLAGEN MICROCHANNELS
Y. T. Matsunaga^1,2, N. Brandenberg¹, and Y. Okubo¹, ¹ The University of Tokyo, JAPAN, and ²PRESTO, JST, JAPAN

W.3.74

A TECHNIQUE FOR MEASURMENT OF DIELECTRIC PROPERTIES OF CELLS BY SIMULTANEOUS USE OF ELECTROROTATION AND NEGATIVE DIELECTROPHORESIS
S.-I. Han, Y.-D. Joo, and K.-H. Han, Inje University, KOREA

W.3.75

AN OPTO-THERMOCAPILLARY CELL MANIPULATOR
W. Hu, Q. Fan, K. S. Ishii, and A. T. Ohta, University of Hawai'i at Mānoa, USA

W.3.76

AN OPTICAL-INDUCED PLATFORM FOR MULTIPLE GENES TRANSFECTION
H.-T. Kuo¹, Y.-H. Lee¹, C.-H. Wang¹, C.-M. Chang², and G.-B. Lee¹, ¹ National Tsing Hua University, TAIWAN, and ²National Cheng Kung University, TAIWAN

W.3.77

DIRECTED MIGRATION OF CELLS IN CONTACT WITH ANISOTROPIC MICROSTRUCTURES
M. L. Berre¹, Y.-J. Liu¹, J. Hu², P. Mauri¹, R. Voituriez³, Y. Chen², and M. Piel¹, ¹ Institut Curie, FRANCE, ²Ecole Normale Supérieur, FRANCE, and ³Universite Pierre et Marie Curie, FRANCE

W.3.78

MULTIPLEXED CELLS MICROPATTERNING USING CAPILLARY ASSEMBLY
F.-D. Delapierre, G. Mottet, V. Taniga, and L. Malaquin, Institut Curie, FRANCE

W.3.79

LASER-BASED MANIPULATION AND FLUORESCENT DETECTION OF INDIVIDUAL, CENTRIFUGALLY ARRAYED BIOPARTICLES
R. Burger¹, D. Kurzbuch¹, R. Gorkin¹, O. Sheils², J. O'Leary², M. Glynn¹, G. Kijanka¹, and J. Ducrée¹, ¹ Dublin City University, IRELAND, and ²Trinity College Dublin, IRELAND

W.3.80

SIMPLE CIRCULATING TUMOR CELL SEPARATION
J. G. Kralj¹, C. Arya², M. S. Munson¹, T. P. Forbes¹, A. Tona¹, L. Sorbara³, S. Srivastava³, and S. P. Forry¹, ¹ National Institute of Standards and Technology, USA, ²University of Maryland, USA, and ³National Institutes of Health, USA

W.3.81

SEPARATION OF DEFORMABLE HYDROGEL MICROPARTICLES IN DETERMINISTIC LATERAL DISPLACEMENT DEVICES
M. Ghasemi¹, S. H. Holm¹, J. P. Beech¹, M. Björnmalm¹, and J. O. Tegenfeldt^1,2, ¹ Lund University, SWEDEN, and ²University of Gothenburg, SWEDEN

W.3.82

EFFICIENT ISOLATION OF TUMOR CELLS IN WHOLE BLOOD USING APTAMERS IMMOBILIZED IN A DEVICE
Z. H. Fan, W. Sheng, T. Chen, and W. Tan, University of Florida, USA

W.3.83

ISOLATION OF CIRCULATING TUMOR CELLS FROM WHOLE BLOOD USING IMMUNOMAGNETIC NANOBEADS AND LATERAL MAGNETOPHORESIS
S. Kim, M.-J. Park, Y.-D. Joo, I.-H. Choi, and K.-H. Han, Inje University, KOREA

W.3.84

A MICROMIXER FOR CONTINUOUS LABELING OF CIRCULATING TUMOR CELLS WITH MICRO-BEADS AS A HIGHLY SELECTIVE ISOLATION
M. X. Lin¹, K.-A. Hyun¹, H.-S. Moon², T. S. Sim², J.-G. Lee², J. C. Park², and H.-I. Jung¹, ¹ Yonsei University, KOREA, and ²Samsung Advanced Institute of Technology, KOREA

W.3.85

FULLY AUTOMATED IMMUNOMAGNETIC LAB-ON-CHIP FOR RARE CANCER CELLS SORTING, ENUMERATION AND IN-SITU ANALYSIS
J. Autebert, B. Coudert, F.-C. Bidard, J.-Y. Pierga, S. Descroix, L. Malaquin, and J.-L. Viovy, Institut Curie, FRANCE

W.3.87

SORTING OF BLOOD IN SPIRAL MICROCHANNELS
N. Nivedita, and I. Papautsky, University of Cincinnati, USA

W.3.88

SORTING SINGLE CELLS BASED ON DYNAMIC ASSESSMENT OF SIGNALING
S. J. Tan¹, M. Z. L. Kee¹, A. S. Mathuru¹, S. R. Quake^1,2, S. J. Jesuthasan¹, and W. F. Burkholder¹, ¹ A*STAR, SINGAPORE, and ²Stanford University and Howard Hughes Medical Institute, USA

W.3.89

TUNABLE STANDING SURFACE ACOUSTIC WAVES ACTIVATED CELL SORTING
X. Ding¹, C. Y. K. Chan¹, M. I. Lapsley¹, L. Wang², and T. J. Huang¹, ¹ The Pennsylvania State University, USA, and ²Ascent Bio-Nano Technologies Inc. State College, USA

W.3.90

ACOUSTOPHORESIS PRE-ALIGNMENT OF CELLS ENABLES LABEL-FREE ENRICHMENT OF PROSTATE CANCER CELLS IN BLOOD
P. Augustsson¹, C. Magnusson¹, H. Lilja², and T. Laurell¹, ¹ Lund University, SWEDEN, and ²Memorial Sloan-Kettering Cancer Center, USA

W.3.91

A SIZE-DEPENDENT CELL CAPTURE AND RELEASE CHIP USING MULTIPLE VARIABLE MEMBRANE BARRIERS
Y. Kim, and Y.-H. Cho, Korea Advanced Institute of Science and Technology (KAIST), KOREA

W.3.92

A SIMPLE METHOD FOR CELL ISOLATION BY UTILIZING BOTH CELL SIZE AND AFFINITY TO SURFACES
A. Araki^1,2, S. Kaneda^1,2, and T. Fujii², ¹ The University of Tokyo, JAPAN, and ²JST-CREST, JAPAN

W.3.93

DISTINCT RELEASES OF GROWTH FACTORS FROM THREE DIMENSIONAL FIBROUS SCAFFOLDS COMBINED WITH HYDROGEL FOR DIFFERENTIATION OF MESENCHYMAL STEM CELLS
H. J. Lee, S. Park, E. Jang, T. G. Lim, S. W. Han, H. W. Lee, U. S. Chung, and W.-G. Koh, Yonsei University, KOREA

W.3.94

SMOOTH MUSCLE CELL CULTURE IN MICROCHANNEL TOWARD CONSTRUCTION OF MULTILAYERED VASCULAR TISSUE IN MICRO-SCALE
T. Yamashita¹, K. Mawatari^1,2, Y. Tanaka³, and T. Kitamori^1,2, ¹ University of Tokyo, JAPAN, ²CREST, JAPAN, and ³RIKEN, JAPAN

W.3.95

FABRICATION OF MICROCHANNEL NETWORK IN LIVER TISSUE SPHEROIDS
N. Kojima^1,2, S. Takeuchi^1,2, and Y. Sakai^1,2, ¹ University of Tokyo, JAPAN, and ²BEANS Project, JAPAN

W.3.96

MICROMECHANICAL ELASTOMERIC DEVICES FOR INVESTIGATIONS OF MECHANOBIOLOGY IN HUMAN EMBRYONIC STEM CELLS
Y. Sun, L. G. Villa-Diaz, R. H. W. Lam, W. Chen, P. H. Krebsbach, and J. Fu, University of Michigan, USA

W.3.97

THE EFFECT OF EXTRACELLULAR MATRIX ON ACTIVATION OF ATROCYTE IN 3D CO-CULTURE CHIP FOR NERVE INJURY MODEL
Y. H. Kim¹, Y. E. Kim¹, S. Chung², T. S. Kim¹, and J. Y. Kang¹, ¹ Korea Institute of Science and Technology, KOREA, and ²Korea University, KOREA

W.3.98

LINEAR FIBROBLAST ALIGNMENT ON SINUSOIDAL WAVE MICROPATTERNS
J. R. Gamboa, S. Mohandes, P. L. Tran, M. J. Slepian, and J.-Y. Yoon, The University of Arizona, USA

W.3.99

BIOFABRICATION OF LIVING VESSEL STRUCTURES INTEGRATED WITH FLUID PERFUSION
S. Iwanaga^1,2, S. Miura^1,2, H. Onoe^1,2, T. Okitsu^1,2, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²JST, JAPAN

W.3.100

MICROFLUDICS SPINNING OF FLAT FIBER WITH MICRO GROOVES FOR CELL-ALIGNING SCAFFOLDS
E. Kang, Y. Y. Choi, Y. J. Choi, and S.-H. Lee, Korea University, KOREA

W.3.101

ON CHIP SPATIOTEMPORAL ELECTRIC FIELD SHAPING TO LOCALLY ELECTROPORATE CELL MARKERS INTO MOUSE EMBRYONIC TISSUES
E. Mazari¹, X. Zhao¹, J. Collignon², A. Perea-Gomez², and C. Gosse¹, ¹ Laboratoire de Photonique et de Nanostructures, LPN-CNRS, FRANCE, and ²Université Paris 7 – CNRS, FRANCE

W.3.102

DROPLET ELECTROPORATION IN MICROFLUIDICS FOR EFFICIENT TRANSFORMATION WITH OR WITHOUT CELL WALL REMOVAL
B. Qu¹, Y.-J. Eu¹, W.-J. Jeong², and D.-P. Kim³, ¹ Chungnam National University, KOREA, ²Korea Research Institute of Bioscience and Biotechnology, KOREA, and ³Pohang University of Science and Technology, KOREA

W.4.103

"ELISA-CIEF" USING CAPILLARY-BASED MICRODEVICE: HIGHLY-SENSITIVE ELISA BASED ON CAPILLARY-ISOELECTRIC FOCUSING OF ENZYME REACTION PRODUCT
Y. Uenoyama¹, K. Ikegami², D. Citterio², K. Suzuki², S. Funano¹, T. G. Henares¹, T. Endo¹, and H. Hisamoto¹, ¹ Osaka Prefecture University, JAPAN, and ²Keio University, JAPAN

W.4.104

A COMPACT SILICON MICROPILLAR ARRAY CHIP FOR DNA CHROMATOGRAPHY: DETERMINATION OF SAMPLE SIZE AND CONCENTRATION
L. Zhang^1,2, P. Fiorini², B. Majeed², M. Op de Beeck², C. Van Hoof^1,2, and W. De Malsche³, ¹ imec, BELGIUM, ²Katholieke Universiteit Leuven, BELGIUM, and ³Vrije Universiteit Brussel, BELGIUM

W.4.105

DEVELOPMENT OF A MICROFLUIDIC BLOTTING DEVICE BY USING ALGINATE HYDROGEL
M. Ikawa¹, Y. Fukushima¹, K. Sueyoshi¹, F. Kitagawa², and K. Otsuka¹, ¹ Kyoto University, JAPAN, and ²Hirosaki University, JAPAN

W.4.106

A NOVEL DEVICE FOR HIGHLY EFFICIENT EXTRACTION OF NUCLEIC ACIDS FROM 100 MICROLITER WHOLE BLOOD SAMPLES
L. A. Marshall, and J. G. Santiago, Stanford University, USA

W.4.107

ACOUSTIC MICROCENTRIFUGE ARRAYS FOR RAPID PARTICLE SEPARATION FROM MICROVOLUME BLOOD SAMPLES
A. Doria, M. Patel, N. E. Martin, and A. P. Lee, University of California - Irvine, USA

W.4.108

NEW NANOFLUIDIC DEVICE TO ACHIEVE A LENGTH DEPENDENT MOBILITY OF LONG DNA MOLECULES AND A SEPARATION
B. Kim, and K. Park, The University of Tokyo, JAPAN

W.4.109

THE EFFECT OF THE CHANNEL HEIGHT ON THE SEPARATION EFFICIENCY OF AN ELECTRICAL FIELD FLOW FRACTIONATION SYSTEM
T. O. Tasci, C. J. Lambert, H. J. Sant, E. Manangon, D. P. Fernandez, W. P. Johnson, and B. K. Gale, University of Utah, USA

W.4.110

TWO-DIMENSIONAL PROTEIN SEPARATION ENABLED BY MICROVALVE ARRAYS
Z. H. Fan, K. Liu, and I. Shaik, University of Florida, USA

W.4.111

CONTINUOUS PARTICLE SEPARATION USING REPULSIVE FORCE OF ION CONCENTRATION POLARIZATION
H. Jeon, S. H. Ko, and K. H. Kang, Pohang University of Science and Technology, KOREA

W.4.112

WATER-IN-OIL DROPLET-BASED MICROFLUIDIC SYSTEM FOR ENZYMATIC STUDIES, COUPLED TO OFF-CHIP ELECTROSPRAY IONIZATION MASS SPECTROMETRY
T. Obara^1,2, S. Schlautmann², and H. J. G. E. Gardeniers², ¹ Hitachi High-Technologies Corporation, JAPAN, and ²University of Twente, THE NETHERLANDS

W.4.113

PREPARATION OF FREEZE-DRIED POROUS MEDIA IN A MICROCHANNEL: A New Platform for Enzymatic Reactions
K. Nakagawa, A. Tamura, Y. Goto, M. Takeo, and Y. Utsumi, University of Hyogo, JAPAN

W.4.114

RAPID BACTERIOPHAGE DETECTION VIA HOST CELL AMPLICATION IN A DROPLET-BASED OPTOFLUIDIC SYSTEM
J. Q. Yu, W. Huang, L. K. Chin, and A. Q. Liu, Nanyang Technological University, SINGAPORE

W.4.115

PLANAR ALUMINA PURIFICATION OF ¹⁸F-LABELED RADIOTRACER SYNTHESIS ON EWOD CHIP FOR POSITRON EMISSION TOMOGRAPHY (PET)
S. Chen, J. Lei, R. M. van Dam, P. Y. Keng, and C. J. "CJ" Kim, University of California, Los Angeles (UCLA), USA

W.4.116

COMBINATORIAL SYNTHESIS OF PEPTIDOMIMETICS USING DIGITAL MICROFLUIDICS
M. J. Jebrail¹, N. Assem², J. M. Mudrik², M. D. M. Dryden², K. Lin², A. K. Yudin², and A. R. Wheeler², ¹ Sandia National Laboratories, USA, and ²University of Toronto, CANADA

W.4.117

SYNTHESIS OF MONODISPERSE SILICA MICROPARTICLES WITH TUNABLE SHAPE AT FLUID INTERFACES
A. Fang, and C. Gaillard, INRA, FRANCE

W.4.118

"GREEN" OXIDATION REACTIONS USING A PORPHYRIN-IMMOBILISED MICROFLUIDIC DEVICE
E. K. Lumley, C. E. Dyer, N. Pamme, and R. W. Boyle, The University of Hull, UK

W.4.119

A LIQUID/LIQUID OPTICAL WAVEGUIDE WITH MISCIBLE SOLVENTS TO OBSERVE COMPLEXATION REACTION
H. Murata¹, J. Kamiyama¹, S. Asanuma¹, K. Sato¹, K. Tsunoda¹, H. Hotta², and Y. Sugii³, ¹ Gunma University, JAPAN, ²Nara University of Education, JAPAN, and ³The University of Tokyo, JAPAN

W.4.120

MICROFLUIDIC FABRICATION OF POLYMERIZED IONIC LIQUID MICROGELS
Z. Barikbin¹, M. T. Rahman³, D. Jarde⁴, A. Z. M. Badruddoza², P. S. Doyle⁵, and S. A. Khan^1,2, ¹ Singapore-MIT Alliance, SINGAPORE, ²National University of Singapore, SINGAPORE, ³The Queen's University of Belfast, UK, ⁴Technische Universität München, GERMANY, and ⁵Massachusetts Institute of Technology, USA

W.4.121

INTEGRAGION OF ULTRA-SENSITIVE ON-CHIP ELECTRIC CIRCUIT FOR NON-FARADAIC ELECTRIC CURRENT BASED FLOW SENSING
Y. Matsuoka, and T. Yamamoto, Tokyo Institute of Technology, JAPAN

W.4.122

READY STEADY (BUBBLE) FLOW! PREDICTIVE CONTROL OF MIXING, MASS TRANSFER AND RESIDENCE TIMES IN SEGMENTED FLOW
M. Abolhasani, E. Kumacheva, and A. Günther, University of Toronto, CANADA

W.4.123

ON-CHIP PURIFICATION OF [¹⁸F]FDG IN POSITRON EMISSION TOMOGRAPHY RADIOTRACER SYNTHESIS
M. D. Tarn¹, G. Pascali², F. De Leonardis¹, P. Watts¹, P. A. Salvadori², and N. Pamme¹, ¹ The University of Hull, UK, and ²CNR Institute of Clinical Physiology, ITALY

W.5.124

PRESSURE TOLERANT MULTILAYERED POLYMER FILM MICROFLUIDICS BY ONE-STEP BONDING PROCESS FOR HIGH THROUGHPUT EMULSION GENERATION
K.-I. Kim, and D.-P. Kim, Pohang University of Science and Technology, KOREA

W.5.125

VIRTUALLY MONOLITHIC DEVICE FOR DIFFUSIVE MASS TRANSFER ENABLING HIGH VOLUME FLOW
T. Rieper¹, C. Mueller¹, B. Wehrstein², A. N. Maurer², and H. Reinecke¹, ¹ University of Freiburg, GERMANY, and ²Novalung GmbH, GERMANY

W.5.126

FABRICATION OF A LABEL-FREE MICROMECHANICAL CAPACITIVE BIOSENSOR AND INTEGRATION WITH µPCR TOWARDS A LoC FOR DISEASE DIAGNOSIS
D. Moschou¹, N. Vourdas¹, G. Kokkoris¹, G. Tsekenis², V. Tsouti¹, I. Zergioti³, A. Tserepi¹, and S. Chatzandroulis¹, ¹ NCSR "Demokritos", GREECE, ²FBRAA, GREECE, and ³NTUA/Physics, GREECE

W.5.127

FABRICATION OF NANOFLUIDICS AND NANOPORE USING REACTIVE-ION DRY-ETCHING WITH ELECTRON-BEAM BAKED RESISTS
T. Ohshiro¹, C. Hotehama¹, K. Matsubara², K. Konda¹, H. Kowada¹, S. Murayama¹, R. Yamada¹, T. Kawase¹, M. Taniguchi¹, and T. Kawai¹, ¹ Osaka University, JAPAN, and ²Niigata University, JAPAN

W.5.128

A MULTISCALE TRANSFER PRINTING WITH A HIERARCHICAL STAMP FOR SIMPLE GENERATION OF METALLIC NANOPATTERNS
H. Park, H. Cho, D. Y. Lee, J. S. Kim, and K.-Y. Suh, Seoul National University, KOREA

W.5.129

FAST PROTOTYPING OF µTAS BY DIRECT LASER WRITING
V. J. Cadarso¹, K. Pfeiffer², U. Ostrzinski², A. Voigt², G. Gruetzner², and J. Brugger¹, ¹ Ecole Polytechnique Fédérale de Lausanne (EPFL), SWITZERLAND, and ²Micro Resist Technology GmbH, GERMANY

W.5.130

GRAPHENE NANOSIEVE USING BLOCK COPOLYMER LITHOGRAPHY AND ITS APPLICATION TO SEPARATION OF HEMOGLOBIN PROTEIN AND IMMUNOGLOBLIN G
D.-S. Lee¹, S. H. Park², Y.-D. Han³, J. W. Park¹, M. Y. Jung¹, S. O. Kim², H. C. Yoon³, and S. Y. Choi², ¹ Electronics and Telecommunications Research Institute (ETRI), KOREA, ²KAIST, KOREA, and ³Ajou University, KOREA

W.5.131

A FABRICATION TECHNIQUE OF THREE-DIMENSIONAL NANOCHANNEL BRIDGES WITHOUT NANOLITHOGRAPHY
Y. J. Heo^1,2, K. Sato^1,2, and S. Takeuchi^1,2, ¹ The University of Tokyo, JAPAN, and ²Japan Science and Technology Agency, JAPAN

W.5.133

LARGE AREA 3D MICROFABRICATION TECHNIQUE BY MULTIDIRECTIONAL PHOTOLITHOGRAPHY FOR A CHROMOSOME EXTENSION CHIP
Y. Nitta, H. Suzuki, K. Terao, H. Takao, F. Shimokawa, F. Oohira, and T. Suzuki, Kagawa University, JAPAN

W.5.134

A LOW-COST VALVE AND PUMP WITH POLYPROPYLENE (PP) FABRICATED BY UV/OZONE-ASSISTED THERMAL FUSION BONDING
J. S. Shim, W. Jung, C. Park, K.-H. Kim, W. Chung, K. Namkoong, J.-H. Kim, and N. Huh, Samsung Electronics Co., Ltd., KOREA

W.5.135

PHOTO-DYNAMIC CONVERSION OF SOLID SURFACE FROM PROTEIN-PHOBIC TO PROTEIN-PHILIC BY FEMTOSECOND LASER THROUGH IN SITU MICROFABRICATION
K. Okano^1-5, Y. Hosokawa², H. Tsubokawa¹, H. Masuhara⁴, and F.-J. Kao⁵, ¹ Tohoku Fukushi University, JAPAN, ²Nara Institute of Science and Technology, JAPAN, ³Toin University of Yokohama, JAPAN, ⁴National Chiao Tung University, TAIWAN, and ⁵National Yang-Ming University, TAIWAN

W.5.136

SUPERIOR DRY BONDING OF OFF-STOICHIOMETRY THIOL-ENE EPOXY (OSTE(+)) POLYMERS FOR HETEROGENEOUS MATERIAL LABS-ON-CHIP
F. Saharil¹, L. El Fissi², Y. Liu¹, F. Calborg¹, D. Vandormael³, L. A. Francis², W. van der Wijngaart¹, and T. Haraldsson¹, ¹ KTH Royal Institute of Technology, SWEDEN, ²UCL – Université catholique de Louvain, BELGIUM, and ³SIRRIS – Liege Sciences Park, BELGIUM

W.5.137

PDMS MICROCHIP ELECTROPHORESIS WITH HIGH SEPARATION EFFICIENCY BY SIMPLE AND QUICK MODIFICATION OF PHOSPHOLIPID POLYMER
K. Nii¹, K. Sueyoshi², K. Otsuka², and M. Takai¹, ¹ The University of Tokyo, JAPAN, and ²Kyoto University, JAPAN

W.5.138

INKJET PRINTED FET FOR BIOSENSING APPLICATIONS
M. Medina-Sánchez¹, C. Martínez-Domingo¹, E. Ramon¹, S. Miserere¹, A. Alcalde-Aragonés¹, J. Carrabina¹, and A. Merkoçi^1,2, ¹ Universitat Autònoma de Barcelona, SPAIN, and ²ICREA, SPAIN

W.5.139

PIEZOELECTRIC MICROMIXER USING A SWIRLING MOTION
T. Mashimo, R. Shibuya, and K. Terashima, Toyohashi University of Technology, JAPAN

W.5.140

MICROFLUIDIC MAGNETIC RESONANCE CHIP WITH INTEGRATED SOLENOIDAL MICROCOIL FOR DISPOSABLE USE IN A MODULAR PROBE
R. Ch. Meier¹, V. Badilita¹, E. Fischer², M. Meissner¹, D. V. Elverfeldt², J. Hennig², U. Wallrabe¹, and J. G. Korvink¹, ¹ University of Freiburg, GERMANY, and ²University Medical Center Freiburg, GERMANY

W.5.141

SHAPE-MEMORY POLYMER MICROVALVES
H. Takehara^1,2, K. Uto³, M. Ebara³, T. Aoyagi³, and T. Ichiki¹, ¹ The University of Tokyo, JAPAN, ²Japan Society for the Promotion of Science, JAPAN, and ³National Institute for Materials Science (NIMS), JAPAN

W.5.142

SURFACE MICROMACHINING OF POLYDIMETHYLSILOXANE (PDMS) FOR MICROFLUIDIC BIOMEDICAL APPLICATIONS
W. Chen, N.-T. Huang, K. Kurabayashi, and J. Fu, University of Michigan, USA

W.5.143

ON-CHIP ELECTRIC POWER GENERATION SYSTEM FROM SOUND OF PORTABLE MUSIC PLYERS AND SMARTPHONES TOWERD PORTABLE μTAS
T. Naito¹, N. Kaji¹, S. Le Gac², M. Tokeshi³, A. van den Berg², and Y. Baba^1,4, ¹ Nagoya University, JAPAN, ²University of Twente, THE NETHERLANDS, ³Hokkaido University, JAPAN, and ⁴National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

W.5.144

INTEGRATION OF POLYCARBONATE CELL CULTURE MEMBRANES INTO A POLYMER-BASED MICROFLUIDIC PLATFORM FOR RAPID DRUG SCREENING
E. Vereshchagina, D. Mc Glade, M. Glynn, and J. Ducrée, Dublin City University, IRELAND

W.5.145

CODE-CHANGEABLE ENCODED MICROPARTICLES FOR MULTI-STEP BEAD-BASED ASSAY
T. Kwon, Y. Song, D. Lee, M. Kim, T.-J. Park, and S. Kwon, Seoul National University, KOREA

W.6.146

EXOSOME LIKE LIPOSOME GENERATION BY CELL EXTRUSION THROUGH A MICRO CHANNEL
N. Yi, J. Kim, D. Jeong, M. Lee, S. C. Jang, J. H. Kim, Y. S. Gho, and J. Park, POSTECH, KOREA

W.6.147

UTILIZING PDMS STAMPING FOR MASS PRODUCTION OF MICROTUBULE FUNCTIONALIZED DETECTION DEVICES
O. Koc, M. C. Tarhan, Y. Orazov, H. Fujita, and B. Kim, University of Tokyo, JAPAN

W.6.148

ORDERED MOLECULAR ASSEMBLY INSIDE CARBON NANOTUBE FOREST FILMS FOR HIGH-EFFICIENCY ENZYMATIC BIOFUEL CELL
S. Yoshino¹, T. Miyake^1,3, H. Kaji^1,3, T. Yamada^2,3, K. Hata^2,3, and M. Nishizawa^1,3, ¹ Tohoku University, JAPAN, ²AIST, JAPAN, and ³JST-CREST, JAPAN

W.6.149

PHARMACY-ON-A-CHIP: MICROFLUIDIC SYNTHESIS OF PEGYLATED AND FOLATE RECEPTOR-TARGETED LIPOSOMES FOR DRUG DELIVERY
R. R. Hood¹, A. Andar², D. M. Omiatek³, W. N. Vreeland³, P. W. Swaan², and D. L. DeVoe¹, ¹ University of Maryland, College Park, USA, ²University of Maryland, Baltimore, USA, and ³National Institute of Standards and Technology, USA

W.6.152

OPTICAL MAPPING OF TRANSCRIPTIONAL FACTOR BINDING SITES ON SINGLE DNA MOLECULES USING NANOFLUIDIC DEVICES
K. K. Sriram^1,2, J.-W. Yeh¹, Y.-L. Lin¹, Y.-R. Chang¹, and C.-F. Chou¹, ¹ Academia Sinica, TAIWAN, and ²National Tsing Hua University, TAIWAN

W.6.153

A LIPID-BASED PASSIVATION SCHEME FOR NANOFLUIDICS
J. Fritzsche¹, F. Persson^1,2, K. U. Mir³, M. Modesti⁴, F. Westerlund⁵, and J. O. Tegenfeldt^1,6, ¹ University of Gothenburg, SWEDEN, ²Uppsala University, SWEDEN, ³University of Oxford, UK, ⁴Université Aix-Marseille, FRANCE, ⁵Chalmers University of Technology, SWEDEN, and ⁶Lund University, SWEDEN

W.6.154

FORMATION OF A SINGLE METALLIZED DNA NANOWIRE IN A NANOCHANNEL
T. Himuro, H. Ikedo, S. Sato, S. Takenaka, and T. Yasuda, Kyushu Institute of Technology, JAPAN

W.6.155

MECHANICAL EFFECT OF CALIX[N]ARENE CAPPED SILVER NANOPARTICLES ON DNA MEASURED WITH SILICON NANO TWEEZERS
Y. Tauran^1,2, M. Kumera^1,3, N. Lafitte^1,3, R. Ueno³, L. Jalabert^1,3, Y. Takayama³, D. Collard^1,3, H. Fujita^1,3, A. W. Coleman², and B. Kim^1,3, ¹ LIMMS-CNRS/IIS, UMI2820, JAPAN, ²University of Lyon, FRANCE, and ³The University of Tokyo, JAPAN

W.7.156

RAPID AIRBORNE VIRUS DETECTION USING MIST-LABELING BASED ON MICRO REACTION PROCESS
K. Takenaka¹, S. Togashi¹, and R. Miyake², ¹ Hitachi, Ltd., JAPAN, and ²Hiroshima University, JAPAN

W.7.158

ION-ALTERED-FLUORESCENCE IMAGING (IAFI): A NEW, NON-INVASIVE, VISUALIZATION METHOD WHICH SIMULTANEOUSLY IMAGES SCALAR FIELDS AND QUANTIFIES LOCAL ION CONCENTRATION
V. Shkolnikov, and J. G. Santiago, Stanford University, USA

W.7.159

TIME AND POSITION DEPENDENT SURFACE FLOW VELOCITY MEASUREMENT IN MICROFLUIDIC DEVICES
Y. Iwasaki¹, T. Horiuchi¹, T. Miwa², S. Nakamura³, M. Seyama¹, T. Miura¹, S. Inoue¹, K. Hayashi¹, E. Tamechika¹, and S. Hashimoto², ¹ NTT Microsystem Integration Laboratories, JAPAN, ²Waseda University, JAPAN, and ³Shibaura Institute of Technology, JAPAN

W.7.160

DROPLET TRACKING VELOCIMETRY (DTV): AUTOMATED MEASUREMENT OF DROPLET MOTION AND SHAPE USING DIGITAL IMAGE PROCESSING
A. S. Basu, Wayne State University, USA

W.7.161

CONTINUOUS REAL-TIME MONITORING OF MOLECULAR DETECTION BY SILICON NANOTWEEZERS-INTEGRATED MICROFLUIDIC DEVICE
M. C. Tarhan¹, D. Collard¹, L. Jalabert¹, M. Kumemura¹, N. Lafitte¹, Q. Delouvee¹, S. L. Karsten², and H. Fujita¹, ¹ The University of Tokyo, JAPAN, and ²NeuroInDx, Inc., USA

W.7.162

THIOL-ENE WAVEGUIDES AS PROMISING COMPONENTS OF OPTOFLUIDIC MICROSYSTEMS
R. Kwapiszewski¹, T. G. Jensen², K. B. Mogensen², Z. Brzozka¹, and J. P. Kutter², ¹ Warsaw University of Technology, POLAND, and ²Technical University of Denmark, DENMARK

W.7.163

NANO-OPTOFLUIDICS FOR SINGLE MOLECULE DETECTION
Y. Yang¹, J. M. Tsai², D. L. Kwong², and A. Q. Liu¹, ¹ Nanyang Technological University, SINGAPORE, and ²A*STAR, SINGAPORE

W.7.164

MONITORING ACOUSTIC BUBBLE OSCILLATIONS WITH AN OPTOFLUIDIC INTERFEROMETER
M. I. Lapsley, D. Ahmed, C. Chindam, F. Guo, M. Lu, L. Wang, and T. J. Huang, The Pennsylvania State University, USA

W.7.165

HIGH THROUGHPUT FLUORESCENCE BASED FLOW CYTOMETER USING 3D MICROFLUIDICS FOR PARALLEL SHEATH FLOW FOCUSING AND EMBEDED HIGH N.A. MICROLENS
Y.-J. Fan^1,2, Y.-C. Kung¹, Y.-C. Wu¹, K.-W. Huang¹, T.-H. Wu¹, Y. Chen¹, H.-J. Sheen², and P.-Y. Chiou¹, ¹ University of California Los Angeles, USA, and ²National Taiwan University, TAIWAN

W.7.166

SENSITIVE LABELLES IMPEDANCE IMMUNOSENSOR USING GOLD NANOPARTICLES-MODIFIED OF SCREEN-PRINTED CARBON INK ELECTRODE FOR ACT-PROSTATE SPECIFIC ANTIGEN DETECTION
L. T. N. Truong¹, T. T. Nguyen¹, A. L. T. Luu¹, Y. Ukita², and Y. Takamura², ¹ Hanoi University of Science and Technology (HUST), VIETNAM, and ²Japan Advanced Institute of Science and Technology (JAIST), JAPAN

W.7.167

MONITORING BIOFILM GROWTH AND ACTIVITY USING A SCALABLE MULTICHANNEL ELECTROCHEMICAL BIOSENSOR
K. Sachsenheimer, L. Pires, T. Kleintschek, T. Schwartz, and B. E. Rapp, Karlsruhe Institute of Technology (KIT), GERMANY

W.7.168

ELECTROCHEMICAL DETECTION OF SECRETED ALKALINE PHOSPHATASE (SEAP) FROM TRANSFORMED HELA CELLS USING A LAB-ON-A-CHIP DEVICE BASED ON TARGET CONCENTRATION AND LOCAL REDOX-CYCLING
M. Şen, K. Ino, H. Shiku, and T. Matsue, Tohoku University, JAPAN

W.7.169

DROPLET ANALYSIS SYSTEM USING LIQUID CHROMATOGRAPHY AND MASS SPECTROMETRY FOR ENZYME INHIBITION ASSAY
X.-L. Wang, Y. Zhu, and Q. Fang, Zhejiang University, CHINA

W.7.170

DOUBLE DROPLET AS A SENSOR FOR MOLECULAR TRANSPORT THROUGH ORGANIC LIQUID MEMBRANE
M. Fukuyama, and A. Hibara, The University of Tokyo, JAPAN

W.8.171

BEAD TRAPS IN CAPILLARY-DRIVEN MICROFLUIDICS FOR FLUORESCENCE IMMUNOASSAYS
J. Stucki, M. Hitzbleck, and E. Delamarche, IBM Research GmbH, SWITZERLAND

W.8.172

LONG-TERM DRY-STORAGE OF ENZYME-BASED REAGENT SYSTEM FOR ELISA IN POINT-OF-CARE DEVICE
S. Ramachandran, E. Fu, B. Lutz, and P. Yager, University of Washington, USA

W.8.173

INTEGRATED ASSAY WITH SAMPLE PROCESSING: PAPER-BASED DEVICE FOR IgM DETECTION
S. Ramachandran, J. Peltier, J. Osborn, C. Holstein, B. Lutz, E. Fu, and P. Yager, University of Washington, USA

W.8.174

A NEW ASYMMETRIC CAPILLARY FORCE DRIVEN WHOLE BLOOD/PLASMA SEPARATOR USING SPRAY LAYER-BY-LAYER NANO ASSEMBLY
K. K. Lee, and C. H. Ahn, University of Cincinnati, USA

W.8.176

IDENTIFICATION OF SINGLE MOLECULAR DNA METHYLATION POINTS BY MICROFLUIDIC DNA MOLECULE STRETCHING AND QUANTUM DOT DETECTION
Y. Okamoto¹, T. Sano¹, N. Kaji¹, M. Tokeshi², and Y. Baba^1,3, ¹ Nagoya University, JAPAN, ²Hokkaido University, JAPAN, and ³National Institute of Advanced Industrial Science and Technology (AIST), JAPAN

W.8.177

CENTRIFUGAL MICROFLUIDIC SYSTEM FOR RAPID, LOW-COST HIV DIAGNOSIS: CD4+ T-CELL COUNTING USING AN INTEGRATED DVD PLATFORM
H. Ramachandraiah¹, M. Amasia¹, J. Cole², P. Sheard², S. Pickhaver², C. Walker², R. Lione², and A. Russom¹, ¹ KTH Royal Institute of Technology, SWEDEN, and ²Plarion Ltd., UK

W.8.178

INTEGRATED 'LAB-ON-A-TRANSISTOR': WITH DROPLETS-IN-AIR FOR PARALLEL NANOLITER REACTIONS
E. Salm¹, C. Duarte¹, N. Jokilaakso², and R. Bashir¹, ¹ University of Illinois at Urbana-Champaign, USA, and ²Royal Institute of Technology (KTH), SWEDEN

W.8.179

SINGLE-STEP CAPILLARY ELECTROPHORESIS FOR FIELD-AMPLIFIED SAMPLE STACKING
K. Ono, S. Kaneda, and T. Fujii, University of Tokyo, JAPAN

W.8.180

A SIMPLE AND RAPID METHOD FOR INFECTIOUS WATERBORNE DISEASE MONITORING USING DISPOSABLE PDMS MICROFLUIDIC CHIP BY DIELECTROPHORESIS
K.-T. Liao^1,2, W. Varhue², R. L. Guerrant², J. A. Smith², and N. S. Swami², ¹ Academia Sinica, TAIWAN, and ²University of Virginia, USA

W.8.181

OPTICAL MICROSYSTEM FOR FLOW AND STOPPED-FLOW ANALYSES OF ACTIVITY OF ENZYMES DEFICIENT IN RARE GENETIC DISORDERS
R. Kwapiszewski¹, M. Skolimowski², J. P. Kutter², and Z. Brzozka¹, ¹ Warsaw University of Technology, POLAND, and ²Technical University of Denmark, DENMARK

W.8.182

GLASS FIBER SHEET ON A CHIP: FOR RAPID, LOW-COST, AND CONTAMINATION-FREE QUANTITATIVE IMMUNOASSAY
Y. Oyama^1,2, T. Osaki³, K. Kamiya³, R. Kawano³, T. Honjoh², H. Shibata², T. Ide¹, and S. Takeuchi³, ¹ The Graduate School for the Creation of New Photonics Industries, JAPAN, ²Morinaga Institute of Biological Science, Inc., JAPAN, and ³Kanagawa Academy of Science and Technology, JAPAN

W.8.184

MICROFLUIDIC ELECTRIC IMPEDANCE SPECTROSCOPY FOR MALARIA DIAGNOSIS
S. Ha¹, M. Diez-Silva¹, E. Du¹, S. J. Kim², J. Han¹, M. Dao¹, and A. P. Chandrakasan¹, ¹ Massachusetts Institute of Technology, USA, and ²Seoul National University, KOREA

W.8.185

SMALL SAMPLE PROTEIN ANALYSIS BY WESTERN BLOTTING UTILIZING A COUPON-BASED MICROFLUIDIC DEVICE
S. Saedinia¹, K. Nastiuk², J. Krolewski², G. P. Li¹, and M. Bachman¹, ¹ University of California, Irvine, USA, and ²University of Rochester Medical Center, USA

W.8.186

FULLY INTEGRATED ROTARY GENETIC ANALYSIS SYSTEM
J. H. Jung, B. H. Park, S. J. Choi, and T. S. Seo, Korea Advanced Institute of Science and Technology (KAIST), KOREA

W.8.187

VOLUME-REDUCTION SOLID PHASE EXTRACTION ON A PLASTIC MICROFLUIDIC DEVICE FOR FORENSIC SAMPLE ANALYSIS
B. C. Strachan, A. V. Karlsson, and J. P. Landers, University of Virginia, USA

W.8.188

INTEGRATED POLYMERIC LIGHT EMITTER FOR DISPOSABLE PHOTONIC LAB ON CHIP SYSTEMS
E. Carregal-Romero¹, B. Ibarlucea¹, S. Demming², S. Büttgenbach², C. Fernández-Sánchez¹, and A. Llobera¹, ¹ Instituto de Microelectrónica de Barcelona (CSIC), SPAIN, and ²Technische Universitat Braunschweig, GERMANY

W.8.189

AN ACCELERATED, ACTIVELY MIXED, REUSABLE DYNAMIC ARRAY^TM FOR FLUIDIGM BIOMARK^TM AND EP1^TM SYSTEMS
J. Wang, T. Woudenberg, R. Jones, and M. Unger, Fluidigm Corporation, USA

W.8.190

SEAMLESS MULTI-FLUORESCENCE LABELING IN A MICROFLUIDIC DISK VIA DETERMINISTIC VENT VALVES
C.-L. Chen, C.-W. Yang, W.-H. Lian, and A. M. Wo, National Taiwan University, TAIWAN

W.8.191

SLIDABLE AND VALVELESS POLYMERASE CHAIN REACTION–CAPILLARY ELECTROPHORESIS MICRODEVICE FOR PATHOGEN DETECTION
Y. T. Kim, J. Y. Choi, Y. Chen, and T. S. Seo, Korea Advanced Institute of Science and Technology (KAIST), KOREA

W.8.192

HIGHLY SPECIFIC ZEPT-MOLE LEVEL DNA DETECTION BY COMBINATION OF THERMAL LENS MICROSCOPE AND ROLLING CIRCLE AMPLIFICATION
T. Nakao¹, K. Mawatari^1,3, K. Sato², and T. Kitamori^1,3, ¹ University of Tokyo, JAPAN, ²Japan Women's University, JAPAN, and ³Japan Science and Technology Agency, JAPAN

W.9.193

POLYMER-ENHANCED ENERGY HARVESTING FROM STREAMING POTENTIAL
T. Nguyen, Y. Xie, L. J. de Vreede, A. van den Berg, and J. C. T. Eijkel , University of Twente, THE NETHERLANDS

W.9.194

MICRO KINETIC EXCLUSION ASSAY FOR CADMIUM ANALYSIS
A. Aota¹, Y. Date^1,2, S. Terakado¹, K. Sasaki¹, N. Matsumoto¹, T. Matsue², and N. Ohmura¹, ¹ Central Research Institute of Electric Power Industry, JAPAN, and ²Tohoku University, JAPAN

W.9.195

PHOTOCATALYTIC MICROFLUIDIC REACTOR WITH A NOVEL COMPOUND CATALYST FILM USING SOLAR ENERGY
N. Wang, Z. Liu, N. Y. Chan, H. L. W. Chan, and X. Zhang, The Hong Kong Polytechnic University, HONG KONG

W.9.196

MEMBRANELESS PURIFICATION OF HEAVY METAL CONTAMINATED WATER BY ION CONCENTRATION POLARIZATION
S. J. Kim¹, B. Kim², R. Kwak³, K. Y. Zhu³, G. Lim², and J. Han³, ¹ Seoul National University, KOREA, ²POSTECH, KOREA, and ³Massachusetts Institute of Technology, USA

W.9.197

AN EIGHT-CHAMBER LAB-ON-A-CHIP DEVICE FOR MULTIPLE DETECTION OF Campylobacter spp DIRECTLY FROM FECES
J. Høgberg, S. Yi, A. Wolff, and D. D. Bang, Technical University of Denmark, DENMARK

W.9.198

PAPER MICROFLUIDIC DETECTION OF SALMONELLA USING A SMART PHONE
T. S. Park, W. Li, and J.-Y. Yoon, The University of Arizona, USA

W.9.199

DEVELOPMENT OF LIGHT-DRIVEN H₂/O₂ GENERATION CHIP FOR MICRO FUEL CELL DEVICES
Y. Kajita¹, Y. Pihosh^1,2, K. Mawatari^1,2, and T. Kitamori^1,2, ¹ The University of Tokyo, JAPAN, and ²Japan Science and Technology Agency, Core Research for Evolutional Science and Technology, JAPAN

W.9.200

INTERDIGITATED EVAPORATION CHIP FOR EFFICIENT SOLVENT EXCHANGE IN MICROCHANNELS
W.-Y. Tseng, J. S. Cho, A. Chatziioannou, and R. M. van Dam, University of California, Los Angeles, USA

MicroTAS 2012 OKINAWA JAPAN Oct.28-Nov.1

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