The Poster Program highlights research from academia and industry in laboratory technologies spanning several diverse market segments and scientific disciplines. There are two poster sessions, one on Monday, January 31 and the second on Tuesday, February 1.
Click on a day below to jump to that day's poster. Click on a column heading (e.g. "Author") to sort each day's posters by that column.
Click on a code to view the details of that abstract.
| Monday, January, 31, 2011 |
| Code |
Title |
Author |
Organization |
Track |
| MP01 |
‘G Protein-Coupled Receptor Heteromer Identification Technology’ (‘GPCR-HIT’):
Identification and profiling of novel GPCR heteromers and their ligands.
|
Dr. Sanam Mustafa, Ph.D. |
Western Australian Institute for Medical Research |
Emerging Areas of Laboratory Automation |
| MP02 |
Fluorescence and Bioluminescence Genetically Encoded Probes for Imaging Protein Conformational Changes and Interactions in Living
Cells and Animals |
Muhammad Awais |
Liverpool University |
High-Throughput Technologies |
| MP03 |
Automated microfluidic approaches to fraction collection for HPLC and electrophoresis |
Christopher Baker |
Florida State University |
Micro- & Nanotechnologies |
| MP04 |
A droplet microfluidic device for high-throughput screening of reaction conditions |
Mr. Krzysztof Churski, M.S. |
Institute of Physical Chemistry of the Polish Academy of Sciences |
Micro- & Nanotechnologies |
| MP05 |
Paper Based Chromatographic Devices |
Ms. Caroline Davis |
San Diego State University |
Detection & Separation |
| MP06 |
Partial Least Squares (PLS1) Algorithm in Obtaining Meaningful Concentrations of Cholesterol and Polyunsaturated Fatty Acids in Human Serum |
Mr. Gerard Dumancas, B.S. |
Oklahoma State University |
Detection & Separation |
| MP07 |
An automated high-content assay for tumor cell migration through 3-dimensional matrices |
Victoria Echeverria, M.S. |
BellBrook Labs |
High-Throughput Technologies |
| MP08 |
Dielectric sheath flows in microfluidic impedance cytometers |
Dr. Mikael Evander, Ph.D.,M.S. |
Lund University |
Micro- & Nanotechnologies |
| MP09 |
A detailed study of the nano-porous membranes with applications in the enhanced detection of cardiovascular biomarker proteins |
Paige Feikert, B.S. |
Wichita State University |
Micro- & Nanotechnologies |
| MP10 |
Signal Enhancement and Improved Temporal Resolution for Microchip Electrophoresis with Electrochemical Detection |
Laura Filla |
|
Micro- & Nanotechnologies |
| MP11 |
Controlled bending of biocompatible, multifunctional magnetic hydrogel nanocomposites for lab-on-a-chip applications. |
Santaneel Ghosh, Ph.D. |
Southeast Missouri State University |
Micro- & Nanotechnologies |
| MP12 |
Image-based fluidic sorting system for large biological entities demonstrated for Zebrafish larvae sorting into 96-well plates and automated microinjection of Xenopus oocytes |
Mr. Siegfried F. Graf, M.S. |
CSEM SA |
Emerging Areas of Laboratory Automation |
| MP13 |
An Acoustic Trapping System for Monitoring Kinases in Small Cell Populations |
Björn Hammarström, Ph.D. |
Lund University |
Micro- & Nanotechnologies |
| MP14 |
High-throughput 3D spheroid culture and drug testing using a 384 hanging drop array |
Ms. Amy Hsiao, M.S. |
University of Michigan |
High-Throughput Technologies |
| MP15 |
Castable Rigid Polymers For Integrated Microfluidics On Printed Circuit Boards |
Sarkis Babikian, B.S. |
University Of California, Irvine |
Micro- & Nanotechnologies |
| MP16 |
Evaluation of cytostatic effect on the normal and cancer cells in the microfluidic system |
Ms. ELZBIETA JEDRYCH, M.S. |
Warsaw University of Technology, Department of Microbioanalytics |
Micro- & Nanotechnologies |
| MP17 |
Natural product isolation for chemical ecology: rapid screening, analysis, and characterization |
Mrs. Kayla Kaiser, M.S. |
University of California, Riverside |
Detection & Separation |
| MP18 |
HUMAN TEAR FLUID-BASED POINT-OF-CARE DIAGNOSTICS ENABLED BY INTEGRATED MICROFLUIDIC SYSTEMS |
Kelly Karns |
UC Berkeley |
Detection & Separation |
| MP19 |
Instrument-free and High-throughput Screening of Mutagenic/Carcinogenic DNA Sensitizing Drugs using Gold Nanoparticles and Functional DNAs. |
Dr. Joong Kim, Ph.D. |
Korea Research Institute of Bioscience and Biotechnology |
Micro- & Nanotechnologies |
| MP20 |
Improving the Versatility of Microchip-Based Electrochemical Detection: Use of Compact Discs for Electrode Fabrication and Integration of Segmented Flow |
Mr. Douglas Kirkpatrick |
Saint Louis University |
Micro- & Nanotechnologies |
| MP21 |
A microfluidic system for studying cellular markers of metabolic diseases |
Mr. Radoslaw Kwapiszewski, M.S. |
Warsaw University of Technology |
Micro- & Nanotechnologies |
| MP22 |
Biomimetic System for Circulating Tumor Cell (CTC) Isolation |
Cari Launiere |
University of Illinois at Chicago |
Detection & Separation |
| MP23 |
Development of a Microfluidic-Based Screening Device for the Detection of Methylarginines in Plasma |
Thomas Linz, B.S. |
University of Kansas |
Detection & Separation |
| MP24 |
Conjugated Nanoparticles based Enhancement for High-throughput Protein Detection via Surface Plasmon Resonance Imaging |
Ying Liu |
Univeristy of California Riverside |
High-Throughput Technologies |
| MP25 |
High-Throughput Hypoxic Modulation of Islet Calcium Response and Preconditioning |
Dr. Joe Fu-Jiou Lo, Ph.D. |
University of Illinois at Chicago |
Micro- & Nanotechnologies |
| MP26 |
Nanocrystal Clusters for Highly Efficient Bioseparation |
Zhenda Lu, M.S. |
University of California, Riverside |
Detection & Separation |
| MP27 |
Integrated Molecular Diagnostic Systems (iMDs): A Breast Cancer Theranostic Platform
|
Mr. Debkishore Mitra |
Department of Bioengineering, University of California, Berkeley |
Micro- & Nanotechnologies |
| MP28 |
A time-dependent magnetic nanoparticle enhanced actuation strategy for mixing and tagging biomolecules in a point-of-care microfluidic lab-on-a-chip system |
Ahsan Munir, M.S. |
Worcester Polytechnic Institute |
Micro- & Nanotechnologies |
| MP29 |
Electrophysiological Cell Sorting: Label-free Purification of Differentiated Stem Cells via Functional Response to Stimulus in a Microfluidic Platform |
Mr. Frank Myers |
University of California, Berkeley |
Micro- & Nanotechnologies |
| MP30 |
Miniature Electronic Biosensor for the Detection of Glycan Biomarkers |
Nagaraj Vinay Janthakahalli |
The Biodesign Institute at Arizona State University |
Detection & Separation |
| MP31 |
A FASTER AND SAFER STAINING TECHNIQUE FOR ACID FAST BACILLI IN RESOURCE-POOR SETTING |
Mr. Johnbull Sonny Ogboi, M.S. |
Ahmadu Bello University |
Other |
| MP32 |
Soluble and insoluble cues incorporated into polymer nanofiber scaffolds for tissue engineering and regenerative medicine in orthopaedic tissue |
Tim Ruckh, Ph.D.,M.S. |
Colorado State University |
Micro- & Nanotechnologies |
| MP33 |
Liquid Electrodes for Contactless Conductivity Detection in Microchip |
Thiago Segato, Ph.D. |
University of Sao Paulo |
Detection & Separation |
| MP34 |
Use of Epoxy-Embedded, High-Aspect Ratio Pillar Electrodes for Microchip-Based Systems |
Asmira Selimovic, B.S. |
Saint Louis University |
Micro- & Nanotechnologies |
| MP35 |
Hemocompatibility of Titania Nanotube Arrays |
Barbara Symie Smith |
Colorado State University |
Micro- & Nanotechnologies |
| MP36 |
Immune biosensor based on the oxide cerium IsFETs for the determination of mycotoxin level in environmental objects |
Nickolaj F Starodub |
National University of Life and Environmental Sciences of Ukraine |
Detection & Separation |
| MP37 |
Intrinsic bioparticle-induced solution transfer for sample preparation |
Dr. Elodie Sollier, Ph.D. |
UCLA |
Micro- & Nanotechnologies |
| MP38 |
Nanoporous Alumina Membranes Based Microdevices for Ultrasensitive Protein Detection |
Krishna Vattipalli, Ph.D. |
Wichita State University |
Micro- & Nanotechnologies |
| MP39 |
Quantitation and Spatial Control of Peptide Release from Neuronal Cells within Microfluidic Devices |
Mr. Ming Zhong, Ph.D. |
University of Illinois at Urbana-Champaign |
Micro- & Nanotechnologies |
| MP40 |
A microfluidic chip for Multicellular Tumor Spheroid formation and analysis: a prospective system for anticancer drug screening. |
Ms. Karina Ziolkowska, M.S. |
Warsaw University of Technology |
Micro- & Nanotechnologies |
| MP41 |
How to Use a Generic Platform to Track and Control Specific Lab Processes |
Carl Hull, Other |
UNIConnect |
Informatics |
| MP42 |
cAMP Assay Using Spatial Proximity Analyte Reagent Capture Luminescence (SPARCL*) Technology |
Li Liu, Ph.D. |
Beckman-Coulter Inc. |
High-Throughput Technologies |
| MP43 |
Walk-Away Automation of the SOLiD™ Low Input Fragment Library Preparation Protocol utilizing the Tecan® Freedom EVO®75 |
Ms. Karen A Poulter, B.S. |
N/a |
High-Throughput Technologies |
| MP44 |
Automated Data Import and Validation Framework for a High-Throughput Laboratory |
Mr. Zorayr Tigran Khalapyan |
Global Bio Lab |
Informatics |
| MP45 |
A Powerful New High-Throughput Tool for Measuring the Deformability of Single Cells |
Mr. Daniel Gossett, B.S.,M.S. |
UCLA |
High-Throughput Technologies |
| MP46 |
Centrifuge-on-a-Chip: Rapid and Automated Sample Preparation for Cell Suspensions |
Mr. Albert Mach, M.S. |
University of California, Los Angeles |
High-Throughput Technologies |
| MP47 |
Multiplexed biosensing using fiber optic imaging of microsphere whispering gallery mode resonators |
Kevin Armendariz, B.S. |
University of Kansas |
Micro- & Nanotechnologies |
| MP48 |
Novel assay and system for rapid diagnostics of urinary tract infections
using on-chip isotachophoresis and molecular beacons
|
Moran Bercovici, M.S. |
Stanford University |
Detection & Separation |
| MP49 |
Integration of Microchip Electrophoresis with Electrochemical Detection using an Epoxy-Based Molding Method to Embed Multiple Electrode Materials |
Ms. Alicia Johnson, B.S. |
Saint Louis University |
Detection & Separation |
| MP50 |
AUTOMATED DIELECTROPHORETIC SEPARATION OF HETEROGENEOUS CELL POPULATIONS |
Mr. Javier Lopez Prieto, M.S. |
University of California, Irvine |
Detection & Separation |
| MP51 |
A Mircrofluidic Liver Array for Long Term Culture of Fresh and Cryopreserved Primary Hepatocytes |
Ms. Molly Allen, B.S. |
CellASIC Corporation |
Micro- & Nanotechnologies |
| MP52 |
Rapid Liquid Transfer from a 1536-Well Microplate Using Acoustic Droplet Ejection |
Joseph Barco, Ph.D. |
Labcyte, Inc. |
High-Throughput Technologies |
| MP53 |
Automated Washing of Multiplex Bead Based Assays for the MagPix® Reader System |
Dr. Paul Held, Ph.D. |
BioTek Instruments |
Detection & Separation |
| MP54 |
Full Automation of the Composite Assay and Content Uniformity Test by Sotax Tablet Processing Workstation II – HPLC Interface (TPW-HPLC) |
Mr. Brian Kozlowski, M.S. |
Merck Sharpe and Dohme |
High-Throughput Technologies |
| MP55 |
ANALYZING METHYLATED ARGININES USING CAPILLARY ELECTROPHORESIS AND LASER INDUCED FLUORESCENCE DETECTION |
Christa Snyder |
|
Detection & Separation |
| MP56 |
High throughput Drop-to-drop liquid-liquid microextraction method coupled with real time concentration monitoring |
Mrs. Pavithra Wijethunga, B.S. |
The University of Texas at Arlington |
Micro- & Nanotechnologies |
| MP57 |
Gene-Lead and Gene-Typist: Two new fully automated sample to answer systems |
Dr. Carl Hilliker, Ph.D. |
Precision System Science |
Detection & Separation |
| MP58 |
Pin Valve for Microfluidics |
Marie-Elena Brett |
University of Illinois at Chicago |
Micro- & Nanotechnologies |
| MP59 |
Development of a custom high throughput “hit-picking” platform |
Mr. ALEX MLADENOVIC, M.S. |
AMGEN, INC. |
High-Throughput Technologies |
| MP61 |
Fully integrated EWOD based bio-analysis device |
Dr. Frederic Bottausci, Ph.D. |
CEA |
Micro- & Nanotechnologies |
| MP62 |
Automation of a Bioluminescent Live-Cell cAMP Assay for the Pharmacological Evaluation of GPCRs
|
Peter Brescia |
Biotek |
High-Throughput Technologies |
| MP63 |
Utilizing Robotic Sample Preparation and Result Reporting for Automation of the 25-Hydroxyvitamin D2 and D3 Assay |
Eric Bro, B.S. |
Mayo Clinic |
High-Throughput Technologies |
| MP64 |
DNA extraction from frozen serum samples: An automated approach for genetic analysis utilizing QIASymphony and Repli-g whole genome amplification. |
Dr. Andrew I Brooks, Ph.D. |
Rutgers University |
High-Throughput Technologies |
| MP65 |
Flexible nanoliter liquid handling for reliable assay miniaturisation |
Mrs. Dawn Browning |
TTP Labtech Ltd |
High-Throughput Technologies |
| MP67 |
Continuous Improvement through the Development of Equipment Scheduling and Issue Reporting Tools
|
Douglass Fahnoe, B.S. |
Pfizer |
Other |
| MP68 |
Microfluidic Array for High-Throughput Protein Expression |
Dr. Z. Hugh Fan, Ph.D. |
University of Florida |
High-Throughput Technologies |
| MP69 |
Miniaturized Quantitative PCR in 1536-Well Plate Format
Using the Echo Liquid Handler
|
Mrs. Celeste Glazer, M.S. |
Labcyte |
High-Throughput Technologies |
| MP70 |
Automated Solid Phase Extraction for a High Through-Put Vitamin D 1, 25-Dihydroxy Assay. |
Mr. Mark Herrmann, B.S. |
ARUP LABORATORIES |
High-Throughput Technologies |
| MP71 |
Development of an efficient and exclusive temporary immersion bioreactor for plant production in commercial scale |
Mr. Shahriar Hessami, B.S. |
Hessami Plant Tissue Culture Laboratory(HPTCL) |
Detection & Separation |
| MP72 |
Diagnostic Determination of Biotinidase Activity Using AcroPrep™ Advance Filter Plates
|
Mr. Matthew Hymes, M.B.A.,M.S. |
Pall Life Sciences |
Detection & Separation |
| MP73 |
Automated F.A.I.R.E. for Chromatin-based Cancer Diagnosis and Drug Screening |
Mr. Chatura Jayakody, |
U.N.C. at Chapel Hill |
High-Throughput Technologies |
| MP74 |
High Throughput Screening and Validation of High Affinity of Protein Capture Agents |
Dr. Junhoe Cha, Ph.D. |
Institute of Bioengineering and Nanotechnology |
High-Throughput Technologies |
| MP75 |
Automated Optimization of Murine Embryonic Stem Cell Differentiation into Cardiomyocytes |
Michael Kowalski, Ph.D. |
Beckman Coulter |
High-Throughput Technologies |
| MP76 |
Optimizing the automated high-throughput purification of nucleic acids with Thermo Scientific KingFisher Flex |
Arja Lamberg |
Thermo Scientific |
High-Throughput Technologies |
| MP77 |
The Effects of Morphology on the Catalytic Activities of Platinum Nanoparticles Synthesized Using Green Chemistry Methods |
Hunter Rogers |
Auburn University |
Micro- & Nanotechnologies |
| MP78 |
Automated 384-Well Cell-Based Cytochrome P450 Inhibition Assays using Cryopreserved Human Hepatocytes in Suspension |
Brad Larson |
BioTek Instruments, Inc. |
High-Throughput Technologies |
| MP79 |
A Homogeneous Assay to Quantify Endogenous AKT Phosphorylation in Human Umbilical Endothelial Cells |
Brad Larson |
BioTek Instruments, Inc. |
High-Throughput Technologies |
| MP80 |
Microplates and Automation – An Interesting Relationship |
Mark Rothenberg |
Corning Inncorporated |
High-Throughput Technologies |
| MP81 |
High-speed Identification Of Problem Samples In Your Compound Collection |
Mr. Chris Walsh |
RTS Life Science |
High-Throughput Technologies |
| MP82 |
Picoliter Dispense Performance for Dose-Response Assays by Direct Digital Titration |
Kenneth Ward |
Hewlett-Packard Company |
Emerging Areas of Laboratory Automation |
| MP83 |
Complete Solution for Next-Generation Sequencing Sample Preparations of
Roche GS FLX Titanium* Series Kits Using Biomek® FXP and Biomek NXP Laboratory Automation Workstation with REM e Integration
|
Ruth Zhang, Ph.D. |
Beckman Coulter, Inc. |
High-Throughput Technologies |
| MP84 |
Automated Dispense Quality Control and the Active Monitoring of Liquid Handlers |
JUSTIN MURRAY, M.S. |
MERCK & CO. INC. |
High-Throughput Technologies |
| MP85 |
Innovative Automated Small Scale Parallelized Biochromatography for High-Throughput Method Development in Downstream Processing |
Mr. Tim Schroeder |
Atoll GmbH |
High-Throughput Technologies |
| MP86 |
Microscale immunoblotting for small sample protein analysis |
Sara Saedinia |
University of California |
Detection & Separation |
| MP87 |
High-Quality Acoustic Instruments Compound Screening Duet |
Jean Shieh |
Microsonic Systems Inc. |
High-Throughput Technologies |
| MP88 |
Automation of ADP-Glo<sup>TM</sup> Universal Kinase Assay For HTS Screening AND Profiling Applications |
Dr. GEDIMINAS VIDUGIRIS, Ph.D. |
PROMEGA Corp. |
High-Throughput Technologies |
| MP89 |
Microsaic 3500 MiD™ detector coupled to an HPLC
|
Dr. Richard Moseley, Ph.D. |
Microsaic Systems Ltd |
Detection & Separation |
| MP90 |
Speeding Up Assay Development: Perform Highly Efficient Experiments Through Automation |
Mr. Adam Amoss |
Merck & Co., Inc. |
Emerging Areas of Laboratory Automation |
| MP91 |
Development of High-Multiplex Array Formats for Roche NimbleGen Microarrays |
John Painter |
Roche NimbleGen |
High-Throughput Technologies |
| MP92 |
Developing Novel Techniques for Disposable Tip Liquid Handling to Enable High Quality Compound Transfer |
Dr. Moneesh Chatterjee, Ph.D. |
Bristol-Myers Squibb |
High-Throughput Technologies |
| Tuesday, February, 1, 2011 |
| Code |
Title |
Author |
Organization |
Track |
| TP01 |
Stability Management: Journey from Requirements to LIMS Prototype |
VIBHA CHAWLA, M.S. |
iGate patni Life Sciences |
Informatics |
| TP02 |
Compact and inexpensive Capillary Gel-Electrophoresis Fluorescence System for Antibody-Antigen Interactions |
Mr. Varoujan Amirkhanian, B.S. |
BiOptic, Inc. |
Micro- & Nanotechnologies |
| TP03 |
SPECTRAL CORRECTION COMPLEX SCC-BARS |
Dr. Emir Aznakayev, Ph.D. |
National Aviation University |
Emerging Areas of Laboratory Automation |
| TP04 |
MICROFLUIDIC CHIP INTERCONNECT FOR RESEARCH AND DIAGNOSTICS |
Mr. Joseph Paz, B.S. |
UCLA |
Emerging Areas of Laboratory Automation |
| TP05 |
Ultrasonic Fluid Processing Improves Triolein Measurement Accuracy in Mass Spectrometry Assays |
Jean Shieh |
Microsonic Systems Inc. |
Detection & Separation |
| TP06 |
The Single 9-sided Pod - Ultra High Throughput Multi-Function Robotic Screening Platform |
JUSTIN MURRAY, M.S. |
MERCK & CO. INC. |
High-Throughput Technologies |
| TP07 |
Analysis of Differentiation of Embryonic Stem Cells by Automated Flow Cytometry Sample Preparation on the Biomek® NXP |
AMY YODER |
BECKMAN COULTER |
High-Throughput Technologies |
| TP08 |
Novel concept for walk-away automated sample preparation for direct-to-consumer genetics and pharmacogenomic studies |
Dr. Jens Beator, Ph.D. |
STRATEC Molecular GmbH |
Emerging Areas of Laboratory Automation |
| TP09 |
BenchPro 2100_Automated Maxiprep Purification System |
Daniel Bezdek, M.S. |
Life Technologies |
Emerging Areas of Laboratory Automation |
| TP10 |
Novartis Lab2Lab
Enabling Remote Open Access for Biochemical Analysis of the Future |
Mrs. Dawn Browning |
TTP Labtech Ltd |
Informatics |
| TP11 |
The Future of Compound Management |
Mrs. Dawn Browning |
TTP Labtech Ltd |
High-Throughput Technologies |
| TP12 |
An Integrated Solution for Automated Nanoliter Hit-Picking |
Mrs. Dawn Browning |
TTP Labtech Ltd |
High-Throughput Technologies |
| TP13 |
Global Bio Lab: Enabling Technologies for High-Throughput Screening of Infectious Disease Samples |
Lee A. Borenstein, Ph.D. |
|
High-Throughput Technologies |
| TP14 |
Development of automated workstation for optimization of protein refolding conditions |
Mr. ALEX MLADENOVIC, M.S. |
AMGEN, INC. |
High-Throughput Technologies |
| TP15 |
Analysis of volume precision and accuracy of a new device and method for nanoliter liquid handling in micro well plates |
Tobias Brode |
Fraunhofer IPA |
High-Throughput Technologies |
| TP16 |
A Platform for the Analysis of Time-resolved Data from FLIPR, Label-free, and Ion-flux Technologies, in High-Throughput Style: Automated Analysis, Systematic Quality Control and Multiplexed Hit List Generation |
Dr. Annette Brodte, Ph.D. |
Genedata |
Emerging Areas of Laboratory Automation |
| TP17 |
High-throughput extraction of compromised whole blood samples for genetic analysis: Implementation of the chemagic STAR in a genetics repository |
Dr. Andrew I Brooks, Ph.D. |
Rutgers University |
High-Throughput Technologies |
| TP18 |
Expanding the Application of a Tablet Processing Workstation to Support the Sample Preparation of Liquid Formulations |
Mr. JOHN WARZEKA, M.S. |
PFIZER |
High-Throughput Technologies |
| TP19 |
An Efficient System for End to End Automation of Discovery Processes |
Walter Cedeno, Ph.D. |
Johnson & Johnson |
Informatics |
| TP20 |
Combinatorial discovery and characterization of upconverting nanocrystal probes for biological imaging |
Dr. Emory Chan, Ph.D. |
Lawrence Berkeley National Laboratory |
Micro- & Nanotechnologies |
| TP21 |
Application of microarrayer for yeast cell array in drug screening |
Dr. Daniel Chen, Ph.D. |
University of California, Irvine |
High-Throughput Technologies |
| TP22 |
Comparison of workflows for mouse serum peptidome analysis in an automated mesofluidic platform |
Gabriela Chirica, Ph.D. |
Sandia National Laboratory |
Emerging Areas of Laboratory Automation |
| TP23 |
Array Tape™ Platform provides HTP Screening with Reduced Plastic, Reagent and Energy Consumption |
Dr. Kjersten Cook, Ph.D. |
Douglas Scientific |
High-Throughput Technologies |
| TP24 |
Homogeneous Multiplexed Assay for Hematopoietic Stem Cell Toxicity |
Cromwell F Evan |
Molecular Devices |
High-Throughput Technologies |
| TP25 |
Volume Detection through Pressure Measurement |
Cheryl Dlhos, B.S.,M.S. |
Amgen Inc |
Emerging Areas of Laboratory Automation |
| TP26 |
Characterization of the H-Cube Flow Chemistry Reactor for Discovery Scale Hydrogenation |
Dr. John Eschelbach, Ph.D. |
|
High-Throughput Technologies |
| TP27 |
Microtechnologies For Mimicking Tumor Microenvironments In Vitro |
Bhushan Toley |
UMass Amherst |
Micro- & Nanotechnologies |
| TP28 |
High-Throughput Technologies
Evaluation & Comparison of Kinetic Detectors
|
Mr. Olaf Galuba, M.S. |
Novartis Pharma AG |
High-Throughput Technologies |
| TP29 |
High Throughput Tag-Lite® Cell based Functional and Surface Binding Assays on the SpectraMax® Paradigm Plate Reader Platform |
Cromwell F Evan |
Molecular Devices |
High-Throughput Technologies |
| TP30 |
Web-based E-Wizard screen builder and deskop instrument facilitate automated chemical screen design. |
Cory Gerdts, Ph.D. |
Emerald BioSystems |
High-Throughput Technologies |
| TP31 |
Volume Verification in Steel Probe for Enhanced Process Control |
Dr. Klaus Rehfeldt, Ph.D. |
STRATEC Biomedical Systems AG |
Emerging Areas of Laboratory Automation |
| TP32 |
Smart Fabrication of the Cell Array Chips using Optically Coded Functional Microbeads |
Dr. Man Bock Gu, Ph.D. |
Korea University |
High-Throughput Technologies |
| TP33 |
High Throughput Determination of Enzyme Kinetic Parameters with High Speed Microplate Photometry |
Ms. Reija-Riitta Harinen, M.S. |
Thermo Fisher Scientific |
High-Throughput Technologies |
| TP34 |
Simplified Nanodroplet Formation and Injection for Capillary Electrophoretic Separations |
Dr. Christopher Harrison, Ph.D. |
San Diego State University |
Micro- & Nanotechnologies |
| TP35 |
Development of an Inventory scan using a BL601 Barcode Reader in a Cytomat 6002 with Biomek 3.3 |
Mr. Jan Wagner |
Private |
High-Throughput Technologies |
| TP36 |
Quantitative Studies of Long-Term Culture and Development of Embryoid Bodies Regulated by Reactive Oxygen Species (ROS) |
Mr. SoonGweon Hong |
UC Berkeley |
Micro- & Nanotechnologies |
| TP37 |
Optimization of mixing processes in microplates - A Methodology and Study
of Microplate Mixing Techniques Including BioShake 3000 |
Olaf Hoyer, Other |
Quantifoil Instruments GmbH |
High-Throughput Technologies |
| TP38 |
Multiplexed Biosensing Using Whispering Gallery Mode Imaging |
Mr. Heath Huckabay, B.S. |
The University of Kansas |
Micro- & Nanotechnologies |
| TP39 |
New Software Technology that Enables Scientists to Design and Build their own Assays |
Carl Hull, Other |
UNIConnect |
Informatics |
| TP40 |
Automated Protein Crystallization of membrane proteins with ProCrys Meso |
Schools Jim, Other |
Zinsser Analytic |
Emerging Areas of Laboratory Automation |
| TP41 |
Study on Tunable Resonator using a Cantilevered Carbon Nanotube Encapsulating a Copper Nanocluster |
Mr. SUN-YOUNG JUNG, B.S. |
|
Micro- & Nanotechnologies |
| TP42 |
Measuring Residual Volumes Remaining in a Microplate After Sample Aspiration |
Mr. Kevin Khovananth, B.S. |
Artel Inc |
Detection & Separation |
| TP43 |
Do Plate Readers Agree? Understanding Performance Differences between Different Plate Reader Makes/Models |
Tanya Knaide |
Artel |
Emerging Areas of Laboratory Automation |
| TP44 |
A job scheduling algorithm development for a small size clinical test platform using a virtual prototype machine |
Dr. Ja Choon C Koo, Ph.D. |
SUNGKYUNKWAN UNIVERSITY |
High-Throughput Technologies |
| TP45 |
Utilizing Automated Assay Optimization for BioRAPTR to Maximize Antibody Production by a Hybridoma Cell Line |
Michael Kowalski, Ph.D. |
Beckman Coulter |
High-Throughput Technologies |
| TP46 |
Influence of modified microplate surfaces on the adipogenesis of human mesenchymal stem cells (hMSC) |
Dr. Rainer Heller, Ph.D. |
Greiner BioOne GmbH |
High-Throughput Technologies |
| TP47 |
Utility of Automated Drug Transport Assays in 96-Well Format, using Permeable Support Systems |
Brad Larson |
BioTek Instruments, Inc. |
High-Throughput Technologies |
| TP48 |
Automated Triplexed Hepatocyte-Based Viability and CYP1A and CYP3A Induction Assays in 96 and 384-well Microplates |
Brad Larson |
BioTek Instruments, Inc. |
High-Throughput Technologies |
| TP49 |
Multiplexed Point-of-Care Diagnostics with Fluid Delivery Control and Electrochemical Detection |
Mr. WALSON LAWI, B.S. |
GENEFLUIDICS, INC. |
Micro- & Nanotechnologies |
| TP50 |
Accurate and Precise Low volume Transfer of Antibody and Enzyme Solutions stored in Glycerol using Acoustic Droplet Ejection |
Mr. Howard Lee, B.S. |
Labcyte |
High-Throughput Technologies |
| TP51 |
mES Cell-derived Cardiomyocytes Characterization using the xCELLigence RTCA System |
Li Liu, Ph.D. |
Beckman-Coulter Inc. |
High-Throughput Technologies |
| TP52 |
cytogenetical studies of oil crops |
Dr. leela maheshwari, Ph.D. |
ACS |
High-Throughput Technologies |
| TP53 |
Automation of cell line development workflow and data analysis for increased efficiency |
Brian Majors, Ph.D. |
|
High-Throughput Technologies |
| TP54 |
Integration of Heterogeneous Automated Systems in a High Throughput Laboratory Using Web Services by the example of a LIMS and an Accessioning System |
Mr. Frank Masur |
UCLA Global Bio Lab |
Informatics |
| TP55 |
The Labcyte Access™ Laboratory Workstation: A novel system that quickly and easily integrates the Echo Liquid Handler® into any laboratory workflow. |
Randy Dyer |
Labcyte, Inc. |
Emerging Areas of Laboratory Automation |
| TP56 |
Ultrafast SPE Integrated with TOF-MS Streamlines Workflow and Increases the Throughput of ADME Assay Analysis |
Vaughn P Miller, Other |
Agilent Technologies |
High-Throughput Technologies |
| TP57 |
The Impact of Low-Volume Liquid-Handling Technologies on Sample Management and Screening Workflows |
Keith Miller, B.S. |
Pfizer |
Emerging Areas of Laboratory Automation |
| TP58 |
Robust and reproducible automated tissue homogenization |
Dr. Carsten Poggel, Ph.D. |
Miltenyi Biotec |
Emerging Areas of Laboratory Automation |
| TP60 |
Cell Signaling Assay – Hardware integration on the Beckman Coulter Biomek |
Kelechi Eluwa, M.S. |
Beckman Coulter |
Emerging Areas of Laboratory Automation |
| TP61 |
Do you really know what your robot is doing? – The importance of paying attention to liquid handling details |
Dr. John Thomas Bradshaw, Ph.D. |
Artel |
High-Throughput Technologies |
| TP62 |
Changes in Phosphorylation of Receptor Tyrosine Kinases using a Homogenous Multiplex Immunoassay that is Adaptable for HTS |
Mr. Richard Fuerstenberg, B.S. |
R&D Systems, Inc. |
High-Throughput Technologies |
| TP63 |
Automation of SOLID® Standard Fragment Library Preparation with Size Selection by utilizing Agencourt® AMPure® XP beads for cleanup and a Tecan® Freedom EVO® 75 for the mechanization |
Ms. Karen A Poulter, B.S. |
N/a |
High-Throughput Technologies |
| TP64 |
Productivity enhancement and Acceleration of Chemical Process Development through utilization of Laboratory Automation |
Victor Rosso |
Bristol-Myers Squibb |
Emerging Areas of Laboratory Automation |
| TP65 |
Induction Based Fluidics |
Mr. Drew Sauter |
nanoLiter LLC |
High-Throughput Technologies |
| TP66 |
Automated Parallel Chromatographic Separations in Process Development |
Mr. Tim Schroeder |
Atoll GmbH |
High-Throughput Technologies |
| TP67 |
Automated Isolation of Genomic DNA from Large Volumes of Whole Blood |
Dr. Cristopher Cowan, Ph.D. |
Promega Corporation |
High-Throughput Technologies |
| TP68 |
A NOVEL TECHNIQUE FOR DETECTING THE THERAPEUTIC TARGET, KRAS MUTANT, FROM PERIPHERAL BLOOD USING THE AUTOMATIC GENECHIP ANALYZER DEVICE WITH WEIGHTED ENZYMATIC CHIP ARRAY |
Dr. Hsiung Suz Kai, Ph.D. |
Fooyin University and Hospital |
High-Throughput Technologies |
| TP69 |
<b> Using graphical programming tools with flexible design hardware to speed time to market </b> |
Mr. Markus Tarin, M.S. |
MoviMED |
Emerging Areas of Laboratory Automation |
| TP70 |
Leveraging SharePoint and InfoPath Technologies to Perform Harmonized Study Tracking Across a Complex Global Organization |
Max Tella, Other |
Pfizer Inc |
Informatics |
| TP71 |
A new automation platform ideally suited for small to mid size automated workstations in the life science laboratory |
Marc Valer, B.S. |
Agilent Technologies |
High-Throughput Technologies |
| TP72 |
Lab Services PlateButler 3.0 Robotic Control Software |
Jolanda Van Putten |
Lab Services BV |
High-Throughput Technologies |
| TP73 |
High-content analysis of signaling networks using protein fragment complementation assays (PCA) |
Dr. Ann Siehoff, Ph.D. |
Lonza Cologne GmbH |
Other |
| TP74 |
A Comparison of International Laboratory Regulatory Requirements |
Dr. Sandy Weinberg, Ph.D. |
Clayton State University |
Emerging Areas of Laboratory Automation |
| TP75 |
An Ultrafast Workflow for ICH Linearity Studies using Automated Standard Preparation and UHPLC |
Mr. Altar Yilmazer |
Mettler Toledo |
Emerging Areas of Laboratory Automation |
| TP76 |
Experiences and details of a high throughput, multi-user, multiple instrument hardware vendor screening solution for library QC and target purification |
Dr. Mark Bayliss |
Virscidian Inc |
High-Throughput Technologies |
| TP77 |
Comparison of Monochromator and Filter Based Fluorometers in the Measurement of Narrow Stoke’s Shift Labels; Fluorescent Proteins as Practical Examples |
Dr. Jorma Lampinen, Ph.D. |
Thermo Scientific |
Detection & Separation |
| TP78 |
A Fluorescence Microplate-Based Assay Workflow for High-Throughput Screening of Compounds Modulating Autophagy in Living Cells. |
Dr. Paul Held, Ph.D. |
BioTek Instruments |
Detection & Separation |
| TP79 |
Streamlined Purification of Plasmid DNA from Prokaryotic Cultures |
Mr. Matthew Hymes, M.B.A.,M.S. |
Pall Life Sciences |
High-Throughput Technologies |
| TP80 |
A Microfluidic Device for the Capture, Enumeration, and Isolation of Circulating Tumor Cells |
Jason Luo |
University of California |
Detection & Separation |
| TP81 |
Advancing Drug Discovery with the MaxCyte® STX™ Scalable Transient Transfection System: Expression of Intracellular, Membrane-Bound and Secreted Proteins in Physiologically Relevant Cell Lines, Primary Cells and Stem Cells |
James Brady |
MaxCyte, Inc. |
High-Throughput Technologies |
| TP82 |
Rapid Optimization of Affinity-Tag Purification Protocols using PhyTip Columns and HighThroughput Microchip-CE Analysis |
Mr. ronnel cabuslay, B.S. |
Caliper Life Sciences |
High-Throughput Technologies |
| TP83 |
Automated Plate-Based Differential Scanning Fluorimetry (DFS) for High-Throughput Thermal Stability Screening |
Mr. Huu Tran, B.S. |
Sandia National Laboratories, Joint BioEnergy Institute |
High-Throughput Technologies |
| TP84 |
High-throughput imaging of cellular models using an Acumen eX3 |
Mrs. Dawn Browning |
TTP Labtech Ltd |
High-Throughput Technologies |
| TP85 |
In situ screening and more with G-Rob and the CrystalQuick™ X plate:
a direct way from the crystal to the crystal structure with no crystal handling.
|
Dr. Jean-Luc Ferrer, Ph.D. |
IBS |
High-Throughput Technologies |
| TP86 |
Ensuring the Quality of Registered Compounds in a Drug Discovery Environment – A Multidisciplinary Approach |
Ms. Tara Sinclair, B.S. |
Advanced Chemistry Development, Inc., (ACD/Labs) |
High-Throughput Technologies |
| TP87 |
Real-time and label-free monitoring of bioenergetics and cell impedance/adhesion for long and short term cell-based functional assays in vitro |
Dr. Carsten Haber, Ph.D. |
Bionas |
Other |
| TP88 |
siRNA transfection efficiency of HeLa cells cultivated on various cell culture surfaces |
Antje Fuhrmann, Ph.D. |
Greiner Bio-One GmbH |
Other |
| TP89 |
A Self-Monitoring Quality Management System Incorporating Spectral and Chromatographic Data |
Ms. Tara Sinclair, B.S. |
Advanced Chemistry Development, Inc., (ACD/Labs) |
Informatics |
| TP90 |
Automation and Miniaturization of Glutathione: GSH/GSSG-Glo<sup>TM</sup> Assay using the IDEX H&S Innovadyne Nanodrop II Dispenser
|
Dr. GEDIMINAS VIDUGIRIS, Ph.D. |
PROMEGA Corp. |
High-Throughput Technologies |
| TP91 |
Accelerated Process Development: Automated Purification Technologies to Enhance the Implementation of Quality by Design Strategies |
Dr. Jessika Feliciano, Ph.D. |
Merck |
High-Throughput Technologies |
| TP92 |
Full Automation of Pharmacokinetic and Anti-Drug Antibody Assays in Support of Clinical Trials |
Jhunjhunwala Parul |
Regeneron Pharmaceuticals |
Emerging Areas of Laboratory Automation |
