Carl I. D. Newman scite author profile

In order to understand the role of stacked micelles in sample preconcentration, it is necessary to understand the factors that contribute to the micelle stacking phenomenon. Various MEKC background electrolyte (BGE) solutions were prepared in the presence of Sudan III in order to monitor the micelle stacking phenomenon in the anionic sodium dodecyl sulfate and sodium cholate micelle systems. The data show that micelle stacking is a dynamic process that is strongly dependent upon the relative conductivities of the sample matrix and BGE, the relative column length of the sample plug, and the mobilities of the ions involved in the stacking process regardless of electric field conditions (i.e., field-amplified stacking, sweeping, or high-salt stacking). Conditions under which micelle stacking can be expected to occur are presented, and the extent of micelle stacking is quantified. The micelle stacking phenomenon is correlated to the separation performance of a series of neutral alkaloids. It is shown that neutral analytes migrate rapidly through the evolving stacked micelle region in the initial moments of the separation. As a consequence of this transient interaction, analytes with small retention factors spend less time in the stacked micelle region and experience lower stacked micelle concentrations than analytes with large retention factors that spend more time in the growing stacked micelle region. It is also demonstrated that the extent of analyte enrichment generally increases with injection length, by facilitating greater interaction time with stacked micelles; however, enrichment will eventually plateau with increasing injection length as a function of an analyte's affinity for the micelle. Finally, it is shown that, in contrast to conventional wisdom, a range of long injection plugs exist where separation efficiency can be dramatically improved due to analyte interaction with an actively growing stacked micelle region.

show abstract

Microchip micellar electrokinetic chromatography separation of alkaloids with UV‐absorbance spectral detection

Newman

Giordano²,

Copper

et al. 2008

Electrophoresis

View full text Add to dashboard Cite

A microchip device is demonstrated for the electrophoretic separation and UV-absorbance spectral detection of four toxic alkaloids: colchicine, aconitine, strychnine, and nicotine. A fused-silica (quartz) microchip containing a simple cross geometry is utilized to perform the separations, and a miniature, fiber-optic CCD spectrometer is coupled to the microchip for detection. Sensitive UV-absorbance detection is achieved via the application of online preconcentration techniques in combination with the quartz microchip substrate which contains an etched bubble-cell for increased pathlength. The miniature CCD spectrometer is configured to detect light between 190 and 645 nm and LabView programming written in-house enables absorbance spectra as well as separations to be monitored from 210 to 400 nm. Consequently, the configuration of this microchip device facilitates qualitative and quantitative separations via simultaneous spatial and spectral resolution of solutes. UV-absorbance limits of quantification for colchicine, 20 microM (8 mg/L); strychnine, 50 microM (17 mg/L); aconitine, 50 microM (32 mg/L); and nicotine, 100 microM (16 mg/L) are demonstrated on the microchip. With the exception of aconitine, these concentrations are > or =20-times more sensitive than lethal dose monitoring requirements. Finally, this device is demonstrated to successfully detect each toxin in water, skim milk, and apple juice samples spiked at sublethal dose concentrations after a simple, SPE procedure.

show abstract

Stochastic simulation of reactive separations in capillary electrophoresis

Newman

McGuffin

2005

Electrophoresis

View full text Add to dashboard Cite

A stochastic (Monte Carlo) simulation is used to investigate thermodynamic and kinetic contributions from the reversible A <--> B reaction in capillary electrophoresis (CE). The effects of equilibrium constant, rate constant, and electrophoretic mobility on the molecular zone profiles and the corresponding statistical moments are evaluated. As the reaction approaches steady state, the velocity of the zone is governed by the equilibrium constant and the electrophoretic mobilities of the reacting molecules. When the equilibrium constant is less than unity, the mean zone velocity is more similar to that of the reactant A. Conversely, when the equilibrium constant is greater than unity, the velocity is more similar to that of the product B. The extent of zone-broadening and asymmetry at steady state is dependent upon the equilibrium constant, the characteristic reaction lifetime, and the electrophoretic mobility difference between reacting molecules. If all other parameters are held constant, the plate height is greatest and skew is least when the equilibrium constant is unity. The plate height increases linearly with the characteristic reaction lifetime and electrophoretic mobility difference, whereas the skew is independent of these parameters. These conclusions have important implications for the elucidation of thermodynamic and kinetic information from experimental data.

show abstract

Advances in CE for kinetic studies

Newman

Collins

2007

Electrophoresis

View full text Add to dashboard Cite

CE is a promising technique for the investigation of molecular interactions because it affords evaluation of multiple interaction modes, does not require immobilization of molecules, and has no dead time. In order to perform these investigations, numerous methods have been developed for determining binding constants and other thermodynamic parameters. These methods have been reviewed extensively in recent years. However, methods for determining the rates of reaction are less prolific. Nonetheless, numerous theoretical and experimental advances have been made in recent years to address this discrepancy. Some of these methods employ computer simulations to determine first-order or second-order rate constants numerically, whereas other methods calculate rate constants directly as solutions to analytical equations. It is the object of this review to provide descriptions of these methods in terms of their underlying assumptions, experimental methodology, calculation of rate constants, and inherent limitations.

show abstract

Capillary electrophoresis for thermodynamic and kinetic studies of peptidyl‐proline isomerization by the theoretical plate height model

Newman

McGuffin

2006

Electrophoresis

View full text Add to dashboard Cite

The theoretical plate height model, extended to include reactive CE, is used to calculate equilibrium constants and rate constants for the reversible, first-order isomerization of proline dipeptides. This model is consistent with chromatographic theory and enables calculation of equilibrium constants from velocity and calculation of rate constants from plate height. Thermodynamic and kinetic parameters for isomerization of Ala-Pro and Phe-Pro are calculated by using the plate height model, and are shown to be in good agreement with literature values. Additionally, the efficacy of the plate height model is compared to ChromWin, an existing simulation method for calculating rate constants from zone profiles. It is shown that ChromWin and the plate height model are complementary methods. ChromWin is best used for calculating rate constants for reactions that are far from steady state, where the zone profiles exhibit plateau formation. On the other hand, the plate height model is best used for calculating rate constants for reactions that are at or near steady state, where the zone profiles exhibit a single zone containing both reacting species.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Carl I. D. Newman

Micelle Stacking in Micellar Electrokinetic Chromatography

Microchip micellar electrokinetic chromatography separation of alkaloids with UV‐absorbance spectral detection

Stochastic simulation of reactive separations in capillary electrophoresis

Advances in CE for kinetic studies

Capillary electrophoresis for thermodynamic and kinetic studies of peptidyl‐proline isomerization by the theoretical plate height model

Contact Info

Product

Resources

About