Jason K. King, Brian K. Canfield, Lloyd M. Davis and William H

Slides:

Advertisements

Similar presentations

Single Cell Biosensor Allan Fierro David Sehrt Doug Trujillo Evan Vlcek Michael Bretz.

Advertisements

Device Design and Fabrication Using lithography techniques, a Y-channel master was fabricated with SU8 photoresist. Master on Silicon With this master,

A New Design Tool for Nanoplasmonic Solar Cells using 3D Full Wave Optical Simulation with 1D Device Transport Models Liming Ji* and Vasundara V. Varadan.

Molecular Computation with Automated Microfluidic Sensors (MCAMS) Laura Landweber * Princeton University L. L. Sohn† M. Singh A. Sahai R. Weiss Stanford.

3D Force Microscope (3DFM): Laser Tracking and Force Application CISMM: Computer Integrated Systems for Microscopy and Manipulation Collaborators: Dr.

Effect of Resist Thickness

ABRF meeting 09 Light Microscopy Research Group. Why are there no standards? Imaging was largely an ultrastructure tool Digital imaging only common in.

Géraldine Guerri Post-doc CSL

Optical Tweezers F scatt F grad 1. Velocity autocorrelation function from the Langevin model kinetic property property of equilibrium fluctuations For.

Precision Tilt and Radius of Curvature Sensor Using Double-Pass AOM Kyuman Cho Department of Physics Sogang University.

1 Localized surface plasmon resonance of optically coupled metal particles Takumi Sannomiya*, Christian Hafner**, Janos Vörös* * Laboratory of Biosensors.

Lecture 8: Measurement of Nanoscale forces II. What did we cover in the last lecture? The spring constant of an AFM cantilever is determined by its material.

June 13, 2015Sean Glass 2003 Two and three- dimensional nanoscale structures for molecular electronics Controlled self assembly of charged-stabilized gold.

Micro PIV  An optical diagnostic technique for microfluidics (e.g. MEMS, biological tissues, inkjet printer head) Requirements: Measure instantaneously.

Printed by Supported by an NSF EPSCoR Grant EPS REFERENCES 1.Carls, J.C. et al, Time- resolved Raman spectroscopy from reacting optically levitated.

1 Surface Enhanced Fluorescence Ellane J. Park Turro Group Meeting July 15, 2008.

Nucleation of gold nanoparticles on graphene from Au 144 molecular precursors Andrei Venter 1, Mahdi Hesari 2, M. Shafiq Ahmed 1, Reg Bauld 1, Mark S.

Applications of SPCE to Pharmaceutical Research Kathleen Hamilton, Tom Laue, and James Harper Presentation at the 2007 BITC Meeting University of New Hampshire.

Confocal Raman Tweezers for a Nanotoxicology Application Raman measurements from optically trapped dielectric and magnetic microparticles, under various.

Using Optical Tweezers as a Tool in Undergraduate Labs. Paul Ingram, Ido Braslavsky and David F. J. Tees Dept of Physics and Astronomy, Ohio University,

Announcements HW: Due Tuesday Oct 27 th. Start looking at an article to do your write-up on. Best article is from Nature, Science, Cell. (though can choose.

Optics in micromanufacturing Prof. Yong-Gu Lee Phone: Course web site:

Volumetric 3-Component Velocimetry (V3V)

Optical Tweezers Sarah Nichols March 17, Outline Motivations Operation Layout Successes and Difficulties Future Directions.

Particle Image Velocimetry (PIV) Introduction

Journal Meeting Jung-Yun Ko DNA Sequencing & ABI DNA Sequencer.

BGU Physics Department: Going with the (Laminar) Flow

Colloid Transport Project Project Advisors: Timothy R. Ginn, Professor, Department of Civil and Environmental Engineering, University of California Davis,

指導老師:許藝菊學生:邱建龍介電電泳（DEP）基於微流體粒子分離器Dielectrophoresis (DEP) Based Microfluidic Particle Separator.

Theoretical Study of the Optical Manipulation of Semiconductor Nanoparticles under an Excitonic Resonance Condition + Reference + T.Iida and H.Ishihara,

High Throughput Microscopy

Measurements in Fluid Mechanics 058:180:001 (ME:5180:0001) Time & Location: 2:30P - 3:20P MWF 218 MLH Office Hours: 4:00P – 5:00P MWF 223B-5 HL Instructor:

Objectives Division of Work Background Mirror Fabrication Cavity Fabrication Biomaterials Sample Preparation Test Procedure Results Timeline Future Work.

BIOPARTICLE SEPARATION AND MANIPULATION USING DIELECTROPHORESIS Advisor: Yi-Chu Hsu Student: Le Van Cong ( 黎文功 ) Date: 11/04/2011.

Powerpoint Templates Page 1 Depth Effects of DEP Chip with Microcavities Array on Impedance Measurement for Live and Dead Cells Cheng-Hsin Chuang - STUST.

Miysaka Lab. Keisuke Yamada Alexandros Pertsinidis, Yunxiang Zhang & Steven Chu.

Department of Aerospace Engineering and Mechanics, Hydrodynamic surface interactions of Escherichia coli at high concentration Harsh Agarwal, Jian Sheng.

Pursuing the initial stages of crystal growth using dynamic light scattering (DLS) and fluorescence correlation spectroscopy (FCS) Takashi Sugiyama Miyasaka.

Fluorescence Correlation Spectroscopy

MICROSCOPE DESIGN. beam expander and objective Why do we need a beam expander? What facts about the laser do we need to know? How much expansion do we.

Measurements in Fluid Mechanics 058:180 (ME:5180) Time & Location: 2:30P - 3:20P MWF 3315 SC Office Hours: 4:00P – 5:00P MWF 223B-5 HL Instructor: Lichuan.

OPTOFLUIDIC DEVICES FOR SINGLE CELL MANIPULATION Ana Rita Ribeiro, Ariel Guerreiro, Pedro Jorge New Challenges in the European Area - Young Scientist's.

IFS prototype – PM3 LAM, 13/06/2003 Prototype testing at CRAL Tests at room temperature in the visible.

Chair of Optoelectronics DGAO Wroclaw 1 Fabrication of integrated structures for coupling VCSEL to fibre Denis Wohlfeld, K.-H. Brenner Chair of.

Optimization of T-Cell Trapping in a Microfluidic Device Group #19

1 Advisor : Cheng-Hsin Chuang Advisee : Jing-wei Ju Department of Mechanical Engineering & Institute of Nanotechnology, Southern Taiwan University, Tainan,

C A microfluidic device was created in order to mix the contents of two reservoirs through a 200um-wide, 30mm-long diffusion channel. Flow Characterization.

Tracking and Probing Single, Diffusing Molecules in Droplets Mark Arsenault, Peker Milas, Ben Gamari, Richard Buckman, Lori Goldner Biophysics Group MiniSymposium.

Date of download: 5/30/2016 Copyright © 2016 SPIE. All rights reserved. Optical configuration. The function of a BFP imaging lens, added externally to.

Date of download: 6/2/2016 Copyright © 2016 SPIE. All rights reserved. Experimental setup for angular and spectrally resolved scattering microscopy. The.

James A Germann, Brian K Canfield, Jason K King, Alexander Terekhov, Lloyd M Davis.

Optofluidic Microparticle Splitters Using Multimodeinterference-based Power Splitters Reporter: Nai-Chia Cheng ( 鄭乃嘉 ) Advisor: Ding-Wei Huang 2012/5/30.

Date of download: 6/22/2016 Copyright © 2016 SPIE. All rights reserved. Prismless confocal total internal reflection (CTIR) microscope. 532-nm light is.

Date of download: 6/25/2016 Copyright © 2016 SPIE. All rights reserved. Schematic optical layout of the instrument. Color box legend: Upright optical tweezers.

Development of Micro-Pore Optics at NAOC MPO research group X-ray Imaging Laboratory, NAOC Presented by Chen Zhang.

Date of download: 7/9/2016 Copyright © 2016 SPIE. All rights reserved. Schematic diagram of magnetic fields and their sensing on a tooth of an electric.

Overview of Issue

Manuel Marchiò, Raffaele Flaminio, Shunshi Kuroki

Volume 74, Issue 2, Pages (February 1998)

Supported by NIH Grant EB

Spectral Flow Cytometry

High-Density 3D Single Molecular Analysis Based on Compressed Sensing

Volume 90, Issue 8, Pages (April 2006)

Waves may reflect diffusely based on…

Volume 105, Issue 5, Pages (September 2013)

LIGHT MICROSCOPY variations

Complex Nanophotonics

Volume 90, Issue 8, Pages (April 2006)

10.2 How we see the image.

Quantitative Modeling and Optimization of Magnetic Tweezers

Presentation transcript:

Microfluidic device for 3-D electrokinetic manipulation of single fluorescent molecules Jason K. King, Brian K. Canfield, Lloyd M. Davis and William H. Hofmeister DC.00005 10/20/2011

Motivation

Nanochannel and ABEL trap 100 nm 400 nm Nanochannel 20 nm sphere 8.90E04 5 nm ABEL 20 nm sphere 5 nm 1.72E04

Theory – 3D trap V1 V4 V3 V1 = 3 V, V2 = V3 = V4 = 1 V Finite-volume time domain (FVTD) numerical simulations in ESI CFD-ACE+ Tetrahedral arrangement of electrodes on glass Uniform over laser focal volume Oriented by adjusting electrode potentials V1 V4 V3 V1 = 3 V, V2 = V3 = V4 = 1 V Electrode separation 200 µm V2 Davis et al, Proc. SPIE 6862 (2008)

Electrode-pair fabrication 1) Surface prep 2) Spin coat photoresist 3) Expose/Develop 5) Deposit Cr/Pt 6) Strip photoresist 4) Hard bake

Device assembly

Device assembly

Device assembly

Device assembly

Device assembly

Optical setup NI diffused light PCI - 7833R sample microscope objective lens iris mirror 660 notch 670 LP CCD cylindrical lens

Joystick Control X Y Z

XY Measurements 0.5V: 50 µm·s-1 1.0V: 80 µm·s-1 2.0V: 115 µm·s-1

Cycle XY

Cylindrical lens imaging X image focal plane Y Without Cylindrical Lens -5.0 +0.5 +1.5 +3.0 +5.0 -0.5 -1.5 -3.0 With Cylindrical Lens

Z Measurements 2.0V: 5 µm·s-1

Conclusion/Future Work Demonstrated control in three-axis Quantified motion Three-dimensional trapping of a single fluorescent particle in solution Automated tracking Increase data acquisition rate Further calibrate z-axis measurements Trapping algorithm Integrate z-motion into existing methods Optimize control for high speed operation

Thank you

Collision Simulations (Nanochannel) Rhodamine B: 360 µm s-1 20 nm bead: 21.8 µm s-1 7.06E06 10 nm 4.34E04 10 nm 1.47E06 5 nm 8.90E04 5 nm So why three dimensions? 2.40E05 2 nm 3.87E06 2 nm Time

Collision Simulations (ABEL trap) Rhodamine B: 360 µm s-1 20 nm bead: 21.8 µm s-1 1.47E05 10 nm 10 nm 1.09E04 3.52E05 5 nm 5 nm 1.72E04 So why three dimensions? 2 nm 2.12E04 1.65E05 2 nm Time