Your search keyword '"Palmer, James"' showing total 5 results

1. Laser-Induced Mixing in Microfluidic Channels

Author

Hellman, Amy N, Rau, Kaustubh R, Yoon, Helen H, Bae, Stephanie, Palmer, James F, Phillips, K Scott, Allbritton, Nancy L, and Venugopalan, Vasan

Subjects

Fluid Mechanics and Thermal Engineering, Engineering, Catalysis, Fluorescent Dyes, Horseradish Peroxidase, Hydrogen Peroxide, Kinetics, Lasers, Microfluidics, Microscopy, Fluorescence, Oxazines, Analytical Chemistry, Other Chemical Sciences, Medical biochemistry and metabolomics, Analytical chemistry, Chemical engineering

Abstract

We demonstrate a novel strategy for mixing solutions and initiating chemical reactions in microfluidic systems. This method utilizes highly focused nanosecond laser pulses from a Q-switched Nd:YAG laser at lambda = 532 nm to generate cavitation bubbles within 100- and 200-microm-wide microfluidic channels containing the parallel laminar flow of two fluids. The bubble expansion and subsequent collapse within the channel disrupts the laminar flow of the parallel fluid streams and produces a localized region of mixed fluid. We use time-resolved imaging and fluorescence detection methods to visualize the mixing process and to estimate both the volume of mixed fluid and the time scale for the re-establishment of laminar flow. The results show that mixing is initiated by liquid jets that form upon cavitation bubble collapse and occurs approximately 20 micros following the delivery of the laser pulse. The images also reveal that mixing occurs on the millisecond time scale and that laminar flow is re-established on a 50-ms time scale. This process results in a locally mixed fluid volume in the range of 0.5-1.5 nL that is convected downstream with the main flow in the microchannel. We demonstrate the use of this mixing technique by initiating the horseradish peroxidase-catalyzed reaction between hydrogen peroxide and nonfluorescent N-acetyl-3,7-dihydroxyphenoxazine (Amplex Red) to yield fluorescent resorufin. This approach to generate the mixing of adjacent fluids may prove advantageous in many microfluidic applications as it requires neither tailored channel geometries nor the fabrication of specialized on-chip instrumentation.

Published

2007

2. Electrokinetic stacking injection of neutral analytes under continuous conductivity conditions

Author

Palmer, James, Burgi, Dean S., and Landers, James P.

Subjects

Electrokinetics -- Analysis, Electrolytes -- Conductivity, Micelles -- Analysis, Chemistry

Abstract

In capillary electrokinetic chromatography, neutral analytes can be injected by electroosmotic flow directly from a sample matrix into a separation buffer containing an electrokinetic vector with an opposite mobility. Analytes are injected at the velocity of electroosmotic flow but are retained at the interface of the sample matrix co-ion and separation buffer micelle zones as analyte/micelle complexes. A simple electrokinetic chromatography system containing sodium dodecyl sulfate as the micellar agent with borate as the buffering electrolyte included in the separation buffer and in the sample matrix to provide continuous conductivity was investigated. Concentrations of the micelle, methanol, and borate in the separation buffer were explored to increase maximum injection length of neutral analytes. Reducing the analyte velocity in the separation buffer without substantially decreasing the velocity of the analyte during injection from the sample vial allowed greatly extended sample plug injection lengths. It is presently possible to inject sample solvent volumes equivalent to ~7 effective capillary lengths (180 cm) with a 50-[micro]m-i.d. capillary (24.5 cm effective capillary length), total volume of sample injection ~3.5 [micro] L. Equations describing the injection process and maximum injection lengths for this mode of stacking in electrokinetic capillary chromatography are introduced. The result of this work leads to a postulated generalization of electrokinetic stacking injection maximums for electrophoretic processes, and the concept of orthogonal analyte stacking/ injection systems is discussed.

Published

2002

3. A universal concept for stacking neutral analytes in micellar capillary electrophoresis

Author

Palmer, James, Munro, Nicole J., and Landers, James P.

Subjects

Electrophoresis -- Research, Micelles -- Research, Chemistry

Abstract

Unlike recent studies that have depended on manipulation of separation buffer parameters to facilitate stacking of neutral analytes in micellar capillary electrophoresis (MCE) mode, we have developed a method of stacking based simply on manipulation of the sample matrix. Many solutions for sample stacking in MCE are based on strict control of pH, micelle type, electroosmotic flow (EOF) rate, and separation-mode polarity. However, a universal solution to sample stacking in MCE should allow for free manipulation of separation buffer parameters without substantially affecting separation of analytes. Analogous to sample stacking in capillary zone electrophoresis by invoking field amplification of charged analytes in a low-conductivity sample matrix, the proposed method utilizes a high-conductivity sample matrix to transfer field amplification from the sample zone to the separation buffer. This causes the micellar carrier in the separation buffer to stack before it enters the sample zone. Neutral analytes moving out of the sample zone with EOF are efficiently concentrated at the micelle front. Micelle stacking is induced by simply adding salt to the sample matrix to increase the conductivity 2-3-fold higher than the separation buffer. This solution allows free optimization of separation buffer parameters such as micelle concentration, organic modifiers, and pH, providing a method that may complement virtually any existing MCE protocol without restricting the separation method.

Published

1999

4. Stacking Neutral Analytes in Capillary Electrokinetic Chromatography with High-Salt Sample Matrixes

Author

Palmer, James and Landers, James P.

Subjects

Chromatographic analysis -- Research, Chemistry, Analytic -- Research, Chemistry

Abstract

We recently described a method to stack neutral analytes in electrokinetic chromatography dependent upon using high-salt sample matrixes (Palmer et al. Anal. Chem. 1999, 71, 1679-1687) The use of a high-mobility coion in the sample matrix at a higher concentration than the like-charged electrokinetic vector (e.g., charged micelle) in the separation buffer as we previously suggested induces a single-boundary, discontinuous buffer system which subsequently stacks neutral analytes. Under these conditions, it is possible to electrokinetically inject neutral analytes directly from a high-salt sample matrix via electroosmotic flow, with stacking initiated simultaneously with injection. The correspondence by Quirino et al. (Anal. Chem., previous paper in this issue) suggests the effects of the high-salt sample matrix on stacking of micelles is obviated by a destacking of the micelle zone as it exits the sample zone. They reevaluate the high-salt stacking mode in terms of the (gamma) function. Based on the present data, it is our interpretation that the stacking efficiency is not accurately represented by the (gamma) function and that neither micelle zone nor neutral analyte destacking occurs under conditions we previously described. Low stacking efficiency when low-conductivity sample matrixes are used indicates that the high-salt stacking effect cannot be explained simply as a function of the k value of an analyte/micelle system.

Published

2000

5. Electrokinetic Injection for Stacking Neutral Analytes in Capillary and Microchip Electrophoresis

Author

Palmer, James, Burgi, Dean S., Munro, Nicole J., and Landers, James P.

Subjects

Electrokinetics -- Research, Chromatography -- Research, Capillaries -- Research, Chemistry

Abstract

An on-column mechanism for electrokinetically injecting long sample plugs with simultaneous stacking of neutral analytes in capillary electrokinetic chromatography is presented. On-column stacking methods allow for the direct injection of long sample plugs into the capillary, with narrowing of the analyte peak width to allow for an increase in the detected signal. Low-pressure injections (~50 mbar) are commonly used to introduce sample plugs containing neutral analytes. We demonstrate that injection can be accomplished by applying an electric field from the sample vial directly into the capillary, with neutral analytes injected by electroosmotic flow at up to 1 order of magnitude faster than the corresponding pressure injections. Since stacking occurs simultaneously with electrokinetic injection, stacking is initiated at the capillary inlet, resulting in an increased length of capillary remaining for separation. Reproducibility obtained for peak height and peak area with electroosmotic flow injection is comparable to that obtained with the pressure injection mode, while reproducibility of analysis time is markedly improved. Electrokinetic stacking of neutral analytes utilizing electroosmotic flow is demonstrated with discontinuous (high conductivity, high mobility) as well as continuous (equal conductivity, equal mobility) sample electrolytes. Injecting neutral analytes by electroosmotic flow affords a 10-fold or greater decrease in analysis times when capillaries of 50-[micro]m i.d. or smaller are used. This stacking method should be exportable to dynamic pH junction stacking and electrokinetic chromatography with capillary arrays. Equations describing this electrokinetic injection mode are introduced and stacking of a neutral analyte on a microchip by electrokinetic injection using a simple cross-T channel configuration is demonstrated.

Published

2001