Your search keyword '"Warren R. Zipfel"' showing total 3 results

1. Achieving Uniform Mixing in a Microfluidic Device: Hydrodynamic Focusing Prior to Mixing

Author

Lois Pollack, Hye Yoon Park, Jonas Korlach, Lisa W. Kwok, Elizabeth Rhoades, Warren R. Zipfel, Watt W. Webb, and Xiangyun Qiu

Subjects

Molecular diffusion, Chemistry, business.industry, Spectrum Analysis, Microfluidics, Fluorescence spectrometry, Fluorescence correlation spectroscopy, Mechanics, Models, Theoretical, Kinetic energy, Analytical Chemistry, Physics::Fluid Dynamics, Microsecond, Optics, Microscopy, Hydrodynamic focusing, business

Abstract

We describe a microfluidic mixer that is well-suited for kinetic studies of macromolecular conformational change under a broad range of experimental conditions. The mixer exploits hydrodynamic focusing to create a thin jet containing the macromolecules of interest. Kinetic reactions are triggered by molecular diffusion into the jet from adjacent flow layers. The ultimate time resolution of these devices can be restricted by premature contact between co-flowing solutions during the focusing process. Here, we describe the design and characterization of a mixer in which hydrodynamic focusing is decoupled from the diffusion of reactants, so that the focusing region is free from undesirable contact between the reactants. Uniform mixing on the microsecond time scale is demonstrated using a device fabricated by imprinting optical-grade plastic. Device characterization is carried out using fluorescence correlation spectroscopy (FCS) and two-photon microscopy to measure flow speeds and to quantify diffusive mixing by monitoring the collisional fluorescence quenching, respectively. Criteria for achieving microsecond time resolution are described and modeled.

Published

2006

2. Focal volume confinement by submicrometer-sized fluidic channels

Author

Jonas Korlach, Mathieu Foquet, Warren R. Zipfel, Watt W. Webb, and Harold G. Craighead

Subjects

Photons, business.industry, Chemistry, Capillary action, Microchemistry, Microfluidics, Fluorescence spectrometry, Fluorescence correlation spectroscopy, Microfluidic Analytical Techniques, Models, Theoretical, Analytical Chemistry, Electrokinetic phenomena, Kinetics, Optics, Spectrometry, Fluorescence, Volume (thermodynamics), Diffusion (business), Particle Size, business, Excitation

Abstract

Microfluidic channels with two lateral dimensions smaller than 1 microm were fabricated in fused silica for high-sensitivity single-molecule detection and fluorescence correlation spectroscopy. The effective observation volumes created by these channels are approximately 100 times smaller than observation volumes using conventional confocal optics and thus enable single-fluorophore detection at higher concentrations. Increased signal-to-noise ratios are also attained because the molecules are restricted to diffuse through the central regions of the excitation volume. Depending on the channel geometries, the effective dimensionality of diffusion is reduced, which is taken into account by simple solutions to diffusion models with boundaries. Driven by electrokinetic forces, analytes could be flowed rapidly through the observation volume, drastically increasing the rate of detection events and reducing data acquisition times. The statistical accuracy of single-molecule characterization is improved because all molecules are counted and contribute to the analysis. Velocities as high as 0.1 m/s were reached, corresponding to average molecular residence times in the observation volume as short as 10 micros. Applications of these nanofabricated devices for high-throughput, single-molecule detection in drug screening and genomic analysis are discussed.

Published

2004

3. DNA fragment sizing by single molecule detection in submicrometer-sized closed fluidic channels

Author

Harold G. Craighead, Mathieu Foquet, Jonas Korlach, Warren R. Zipfel, and Watt W. Webb

Subjects

Fabrication, Field (physics), business.industry, Chemistry, Microfluidics, Nanotechnology, Fluorescence correlation spectroscopy, DNA, Fluorescence, Analytical Chemistry, Molecular Weight, Spectrometry, Fluorescence, Flow velocity, Electric field, Optoelectronics, Molecule, business

Abstract

The fabrication of fluidic channels with dimensions smaller than 1 microm is described and characterized in respect to their use for detection of individual DNA molecules. The sacrificial layer technique is used to fabricate these devices as it provides CMOS-compatible materials exhibiting low fluorescence background. It also allows creating microfluidics circuitry of submicrometer dimensions with great control. The small dimensions facilitate single molecule detection and minimize events of simultaneous passage of more than one molecule through the measurement volume. The behavior of DNA molecules inside these channels under an applied electrical field was first studied by fluorescence correlation spectroscopy using M13 double-stranded DNA. A linear relationship between the flow speed and applied electric field across the channel was observed. Speeds as high as 5 mm/s were reached, corresponding to only a few milliseconds of analysis time per molecule. The channels were then used to characterize a mixture of nine DNA fragments. Both the distribution and relative proportions of the individual fragments, as well as the overall concentration of the DNA sample, can be deduced from a single experiment. The amount of sample required for the analysis was approximately 10,000 molecules, or 76 fg. Other potential applications of these submicrometer structures for DNA analysis are discussed.

Published

2002