Michelle Camenzuli

Enhanced separation performance using a new column technology: parallel segmented outlet flow.

A new column technology - termed parallel segmented outlet flow was employed here to illustrate gains in separation performance that are achievable by the active management of flow as it exits from the outlet of the chromatography column. Parallel segmented outlet flow requires a column be fitted with an outlet fitting that separates flow from the central region of the column from that of wall region. Each region of flow is able to be processed independently, such that post column detection emulates end column localised detection. As a result of this flow segmentation and the subsequent more efficient means of detection, column efficiency was observed to increase by more than 20%, with gains in sensitivity by as much as 22%, and a decrease in peak volume by up to 85%.

A new measure of orthogonality for multi-dimensional chromatography

Multi-dimensional chromatographic techniques, such as (comprehensive) two-dimensional liquid chromatography and (comprehensive) two-dimensional gas chromatography, are increasingly popular for the analysis of complex samples, such as protein digests or mineral oils. The reason behind the popularity of these techniques is the superior performance, in terms of peak-production rate (peak capacity per unit time), that multi-dimensional separations offer compared to their one-dimensional counterparts. However, to fully utilize the potential of multi-dimensional chromatography it is essential that the separation mechanisms used in each dimension be independent of each other. In other words, the two separation mechanisms need to be orthogonal. A number of algorithms have been proposed in the literature for measuring chromatographic orthogonality. However, these methods have their limitations, such as reliance on the division of the separation space into bins, need for specialist software or requirement of advanced programming skills. In addition, some of the existing methods for measuring orthogonality include regions of the separation space that do not feature peaks. In this paper we introduce a number of equations which provides information on the spread of the peaks within the separation space in addition to measuring orthogonality, without the need for complex computations or division of the separation space into bins.

Parallel segmented flow chromatography columns: Conventional analytical scale column formats presenting as a ‘virtual’ narrow bore column☆

Narrow bore columns find advantage in HPLC applications when volumetric flow is important, For example, for detection processes that are volume limited. Yet there are significant drawbacks to narrow bore columns. Due to their small column volume relative to analytical scale columns, narrow bore columns are more affected by system dead volume. In addition the wall effect and the variation in packing density from the centre to the wall are more significant in these columns relative to larger scale analytical columns. In this study we operate a 4.6mm i.d. parallel segmented flow column in such a manner that it emulates 2.1mm i.d. and 3.0mm i.d. columns. By using a parallel segmented flow column in this way, it was possible to combine the benefits of narrow bore and analytical scale columns.

Gradient elution chromatography with segmented parallel flow column technology: A study on 4.6 mm analytical scale columns☆

A new column format known as parallel segmented flow has recently been introduced, whereby improvements in column performance are observed. These improvements are achieved via the separation of eluent from the column core from that of the column wall region. The segmentation of flow is accomplished immediately as the eluent exits the column through the use of a multi-channel end fitting. The ratio of flow exiting through the column central port relative to the peripheral ports, known as the segmentation ratio, can be tuned to optimise chromatographic performance. Investigations into the use of parallel segmented flow chromatography columns have demonstrated increased sensitivity and theoretical plates in analytical scale isocratic separations, but so far no studies have detailed the performance of these columns in gradient elution. The current study addresses the performance of parallel segmented flow columns in gradient elution, detailing the reproducibility of the gradient at various segmentation ratios and compares the performance to conventional columns. The study found that there was no observable difference in the gradient shape, or reproducibility of the gradient profiles generated at any segmentation ratio, tested on three different types of stationary phases. A separation of an 11-component test mixture verified that the primary advantage of parallel segmented flow columns was that the peak volume was reduced in proportion to the segmentation ratio.

Postcolumn derivatization of amino acids using reaction flow chromatography columns with fluorescence detection: a fast new approach to selective derivatization techniques

ABSTRACT Reaction flow (RF) chromatography with fluorescamine reagent and fluorescence detection (FLD) was used for the analysis of amino acids. The performance of RF chromatography was tested against several optimized conventional postcolumn derivatization (PCD) methods. RF columns achieved greater sensitivity compared to conventional PCD methods, without the need for reaction loops, which resulted in more efficient separations. The RF-PCD method also achieved limits of detection (LOD) from the low picomole to subnanomole range. The calibration data of the RF-PCD technique yielded R2 ≥ 0.99 and % relative standard deviation in peak areas ranging from 0.34% to 5%. Through reaction flow chromatography, multiplexed detection was also achieved allowing the monitoring and analysis of derivatized and nonderivatized flow streams simultaneously. GRAPHICAL ABSTRACT

ACTIVE FLOW MANAGEMENT IN CHROMATOGRAPHIC SEPARATIONS: A PRELIMINARY INVESTIGATION INTO ENHANCED PREPARATIVE SCALE SEPARATION USING A PARALLEL SEGMENTED OUTLET FLOW DISTRIBUTOR

The detrimental effect of heterogeneity on the efficiency of particle packed columns has been a long standing issue in chromatographic separations. This heterogeneity arises from the difference in packing density between the wall and central regions of the chromatographic bed and imparts radial variance in mobile phase velocity through the column. In conjunction with the uneven distribution of the sample band through frits and distributors at the head of the column, the resultant effect is a decrease in efficiency due to the formation of a parabolic-“like” sample band. We introduce the concept of “Active Flow Management” to counteract the effects of column heterogeneity via the separation of the flow eluting from the center of the column from that of the flow eluting near the peripheral wall region. The flow streams from the two aforementioned regions are separated by the use of a specialized column outlet fitting. By varying the ratio of flow eluting from the center to the peripheral region it was possible to increase the efficiency of a 100 × 21 mm column by up to 57% compared to a column operated in the conventional manner.

Different Stationary Phase Selectivities and Morphologies for Intact Protein Separations

The central dogma of biology proposed that one gene encodes for one protein. We now know that this does not reflect reality. The human body has approximately 20,000 protein-encoding genes; each of these genes can encode more than one protein. Proteins expressed from a single gene can vary in terms of their post-translational modifications, which often regulate their function within the body. Understanding the proteins within our bodies is a key step in understanding the cause, and perhaps the solution, to disease. This is one of the application areas of proteomics, which is defined as the study of all proteins expressed within an organism at a given point in time. The human proteome is incredibly complex. The complexity of biological samples requires a combination of technologies to achieve high resolution and high sensitivity analysis. Despite the significant advances in mass spectrometry, separation techniques are still essential in this field. Liquid chromatography is an indispensable tool by which low-abundant proteins in complex samples can be enriched and separated. However, advances in chromatography are not as readily adapted in proteomics compared to advances in mass spectrometry. Biologists in this field still favour reversed-phase chromatography with fully porous particles. The purpose of this review is to highlight alternative selectivities and stationary phase morphologies that show potential for application in top-down proteomics; the study of intact proteins.

Antioxidant screening of beverages using the online HPLC-DPPH* assay incorporating active flow technology chromatography columns

The analysis and isolation of antioxidants from complex samples requires a separation step to fractionate the sample, followed by a means to measure the presence of the antioxidants. This can be conveniently achieved using liquid chromatography coupled with an on-line antioxidant assay. One such on-line antioxidant assay involves the diphenylpicrylhydrazyl radical (DPPH•), which provides a positive test for phenolic antioxidants through a decolorization of the DPPH• reagent. In this study we review typical applications involving the DPPH• assay. Then we demonstrate how this assay can be improved using recent developments of chromatography technology. The study uses coffee, a complex sample containing numerous antioxidants, to show the efficiency of the new technology. Using this new technology the need to employ large-volume mixing coils is no longer a requirement.

Post Column Derivatization Using Reaction Flow High Performance Liquid Chromatography Columns

A protocol for the use of reaction flow high performance liquid chromatography columns for methods employing post column derivatization (PCD) is presented. A major difficulty in adapting PCD to modern HPLC systems and columns is the need for large volume reaction coils that enable reagent mixing and then the derivatization reaction to take place. This large post column dead volume leads to band broadening, which results in a loss of observed separation efficiency and indeed detection in sensitivity. In reaction flow post column derivatization (RF-PCD) the derivatization reagent(s) are pumped against the flow of mobile phase into either one or two of the outer ports of the reaction flow column where it is mixed with column effluent inside a frit housed within the column end fitting. This technique allows for more efficient mixing of the column effluent and derivatization reagent(s) meaning that the volume of the reaction loops can be minimized or even eliminated altogether. It has been found that RF-PCD methods perform better than conventional PCD methods in terms of observed separation efficiency and signal to noise ratio. A further advantage of RF-PCD techniques is the ability to monitor effluent coming from the central port in its underivatized state. RF-PCD has currently been trialed on a relatively small range of post column reactions, however, there is currently no reason to suggest that RF-PCD could not be adapted to any existing one or two component (as long as both reagents are added at the same time) post column derivatization reaction.