Separations HILIC

We use the second-dimension separation from Fig. 6.6 with a 25 pL injection volume and 2.5 min sampling time the separation is an RPLC method that uses a monolithic column. Thus, 10 pL/min is the maximum flow rate in the first-dimension. Fig. 6.7 shows the development of the first-dimension column that utilizes a hydrophilic interaction (or HILIC) column for the separation of proteins at decreasing flow rates. The same proteins were separated in Fig. 6.6 (RPLC) and 6.7 (HILIC) and have a reversed elution order, which is known from the basics of HILIC (Alpert, 1990). It is believed that HILIC and RPLC separations are a good pair for 2DLC analysis of proteins as they appear to have dissimilar retention mechanisms, much like those of NPLC and RPLC it has been suggested that HILIC is similar in retention to NPLC (Alpert, 1990). Because the HILIC column used in Fig. 6.7 gave good resolution at 0.1 mL/min and no smaller diameter column was available, the flow was split 10-fold to match the second-dimension requirement... 

When comparing the orthogonality values listed in Table 12.2, one may assume that the HILIC-RP combination is the most efficient 2DLC setup for the separation of... 

In recent years, also the number of articles concerning HILIC stationary phases has enormously increased, especially as regards the hydrophilic interactions that resolve some important problems separation and resolution of less retained compound in reversed phase chromatography. With this novel stationary phase, where the silica surface is covered with cross-linked diol groups to increase polar selectivity in hydrophilic conditions, is possible obviate to the use of normal phase with high water content. This allows facilitating the interfacing with sensible and selective detection instruments, such as mass spectrometer with ESI source. The HILIC stationary phase was often chosen to interface the mass spectrometry detector, because it would be... 

HILIC is a variant of normal-phase chromatography that employs polar stationary phases and RPLC-type mobile phases. Because HILIC separations occur by a normal-phase mechanism, the organic component of the mobile phase... 

It appears that the use of HILIC for the separation of basic compounds is increasing and it can provide a useful alternative selectivity to RP, with polar compounds being retained more than nonpolar compounds. The compatibility of HILIC eluents with MS detection seems to be a particular advantageous feature of the technique. Improved understanding of the separation mechanism may lead to its increased use. 

An example of a separation carried out in reversed-phase and in HILIC is shown in Figure 16. The analytes are rather polar, morphine and morphine 3- -glucuronide. On the reversed-phase column, the glu-curonide elutes first, since it is more polar than the parent compound. On the HILIC column, it elutes last. In addition, a gradient is used in the HILIC separation to elute both compounds in the same time frame. This demonstrates clearly the difference in retention between HILIC and reversed-phase chromatography. 

Another important feature of HILIC is the improved sensitivity with electrospray mass spectrometry. At least one order of magnitude, but often more, can be gained compared with reversed-phase separations. This is significant for the analysis of parent drugs and metabolites in plasma or urine samples. Together with the ability to retain very polar metabolites, this feature makes HILIC now a very attractive technique in pharmacokinetics. In addition, HILIC can be combined conveniently... 

FIGURE 16 Comparison of a HILIC separation (top) and a reversed-phase separation (bottom). Peak I morphine, peak 2 morphine 3- glucuronide.Top column Atlantis HILIC Silica, 4.6x50mm, 3.0 lm gradient from 90% to 50% acetonitrile with lOmM ammonium formate buffer, pH 3.0 flow rate 2.0mL/min. Bottom Atlantis dC g, 4.6x50mm, 3.0pm mobile phase 2% acetonitrile with lOmM ammonium formate buffer, pH 3.0 flow rate l.4mL/min. 

Additional modes of HPTC include normal phase, where the stationary phase is relatively polar and the mobile phase is relatively nonpolar. Silica, diol, cyano, or amino bonded phases are typically used as the stationary phase and hexane (weak solvent) in combination with ethyl acetate, propanol, or butanol (strong solvent) as the mobile phase. The retention and separation of solutes are achieved through adsorp-tion/desorption. Normal phase systems usually show better selectivity for positional isomers and can provide orthogonal selectivity compared with classical RPLC. Hydrophilic interaction chromatography (HILIC), first reported by Alpert in 1990, is potentially another viable approach for developing separations that are orthogonal to RPLC. In the HILIC mode, an aqueous-organic mobile phase is used with a polar stationary phase to provide normal phase retention behavior. Typical stationary phases include silica, diol, or amino phases. Diluted acid or a buffer usually is needed in the mobile phase to control the pH and ensure the reproducibility of retention times. The use of HILIC is currently limited to the separation of very polar small molecules. Examples of applications... 

In addition to classical reverse phase separation of peptides on octadecyl derivatized silica monoliths, sugars and peptides as well as proteins and nucleosides have been analyzed on a 20-cm-long silica-based poly(acrylic acid) column (ID. 200 pm), employing HILIC and weak cation-exchange chromatography, respectively [194]. Furthermore, HILIC fractionation of polysaccharides delivered remarkable and promising results [84,194]. 

Inorganic ions (e.g., LP, Na+, and K+) were separated by a silica rod column under hydrophilic interaction mode (HILIC) [198]. The studies of Pack and Risley showed amazing high efficiencies at high mobile phase flow rates by applying HlLlC conditions toward separation of inorganic ions. 

Finally, when RPC methods are used in preparative studies with peptides, the opportunity routinely exists for subsequent analysis of the recovered fractions by a variety of analytical methods including high-speed RP-HPLC, HP-IEX, HP-HILIC, or HP-IMAC, zonal or micellar electrokinetic high-performance capillary electrophoresis (HP-CZE and MECK-CZE), capillary electrochromatography (CEC), or capillary isotachophoresis. The combination of the RPC information, drawn from the In k versus i > plots, with the data derived from on-line spectroscopic detection thus readily provides a comprehensive opportunity to assess the purity of an isolated peptide, many of the physicochemical features of the interaction, as well as a means to optimize the resolution in the RPC separation. 

Liquid Chromatography The process by which the components of a liquid sample are physically separated based on their partitioning between a stationary phase and a moving (mobile) phase. Major modes include reverse phase, in which the stationary phase is non-polar, and normal phase, in which the stationary phase is polar. HILIC (Hydrophobic interaction chromatography) is a popular variant on the latter (Goodwin et al., 2007). 

One weakness of the dominant reverse phase separations mechanism has been the poor retention of highly polar analytes, and hydrophilic interaction liquid chromatography (HILIC) has emerged as an alternative. In HILIC, a polar stationary phase such as silica gel is used to retain highly polar analytes. Mobile phases components similar to those described above for reverse phase separations are used, but the proportions of aqueous vs. organic are changed. Analytes are retained under conditions of relatively low water content, and eluted using increased water content. 

A selective, sensitive, and rapid hydrophilic interaction liquid chromatography with electrospray ionization tandem mass spectrometry was developed for the determination of donepezil in human plasma [32], Donepezil was twice extracted from human plasma using methyl-ferf-butyl ether at basic pH. The analytes were separated on an Atlantis HILIC Silica column with the mobile phase of acetonitrile ammonium formate (50 mM, pH 4.0) (85 15, v/v) and detected by tandem mass spectrometry in the selective reaction monitoring mode. The calibration curve was linear (r = 0.9994) over the concentration range of 0.10-50.0 ng/ ml and the lower limit of quantification was 0.1 ng/ml using 200 /d plasma sample. The CV and relative error for intra- and inter-assay at four quality control levels were 2.7% to 10.5% and —10.0% to 0.0%, respectively. There was no matrix effect for donepezil and cisapride. The present method was successfully applied to the pharmacokinetic study of donepezil after oral dose of donepezil hydrochloride (10 mg tablet) to male healthy volunteers. 

Normal phase (NP) separations are comparatively rarely used in environmental analysis. Again, the reasons lie in the range of analytes amenable to this mode of separation, and in the limited compatibility of typical normal phase HPLC (NP-HPLC) mobile phases with mass spectrometric detection (this also applies to IC). Not only for this reason has interest recently grown in hydrophilic-lipophilic interaction chromatography (HILIC), which represents a viable alternative to the separation of very polar compounds with mobile phases that have a much better compatibility with MS detection, for example, acetonitrile/water with a low water content, typically below 10%, 32 Nonetheless, NP chromato-graphy retains its important role in sample preparation, particularly for the cleanup of complex environmental samples. In the off-line approach, fractions are collected and the relevant one is injected into the reversed phase HPLC (RP-HPLC) system, often after solvent exchange. 

In parallel with recent developments in GC, multidimensional HPLC (LC x LC) is now also finding application in environmental analysis.33 The combination of two sufficiently different separation dimensions (e.g., NP-HPLC x RP-HPLC or IC x RP-HPLC), however, remains difficult because of the solvent compatibility issues discussed above. Here, too, HILIC may bring about a significant improvement, since its mobile phase requirements are much closer to RP-HPLC than those of other liquid chromatographic techniques.34 In contrast to GC x GC, LC x LC cannot be implemented with a (thermal) modulator that collects the analytes after the first separation dimension and reinjects them into the second column it is most practically realized with a double-loop interface that alternately collects and transfers the analytes from the first to the second dimension (Figure 13.7). Even though the second dimension chromatogram is also very fast, detection is not normally a problem since the peak widths in the second dimension are usually still of the order of 1-2 s. 

Antidepressant separation was usually performed by reversed-phase chromatography with typical C8 or C18 alkyl chain columns, although phenyl [30, 59] or cyano [48,64, 84] stationary phases were also employed. As an exception, hydrophilic interaction liquid chromatography (HILIC), a variation of normal phase chromatography, was employed in two analytical methods for duloxetine [38] and... 

High-performance liquid chromatography (HPLC) is a well-established separation technique it is able to solve numerous analytical problems and there is the possibility of acting on the mobile phases with appropriate additives to improve the quality of the peak. Of course, any additive must be compatible with the MS detector nonvolatile buffer or eluent additives cannot be used strong acids such as trifhioroacetic acid (TFA) may cause significant signal suppression in positive ionization. Different stationary phases are used as an alternative to the classical C18 Phenyl, HILIC, fluorinated, etc. 

Further examples of separation techniques that exploit the asymmetric distribution of amino acid residues at the surface of folded proteins include metal ion affinity chromatography (HP-IMAC), ligand exchange chromatography (HP-LEC), immunoaffinity chromatography (HP-IAC), hydrophilic chromatography (HP-HILIC), and the various modes of biospecific (HP-BAC), and biomimetic (HP-BMC) chromatography. For example, the... 

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