Higher degree of glycation of hemoglobin S compared to hemoglobin A measured by mass spectrometry: Potential impact on HbA1c testing.

Background: Glycated hemoglobin (GHb), reported as HbA1c, is used as marker of long-term glycemia for diabetic patients. HbA1c results from boronate affinity methods are generally considered to be unaffected by most hemoglobin variants; this assumes comparable glycation of variant and non-variant (HbAA) hemoglobins. In this report, glycation of HbA beta chain (βA) and HbS beta chain (βS) for the most common Hb variant trait (HbAS) are examined.

Two-step ion-exchange chromatographic purification combined with reversed-phase chromatography to isolate C-peptide for mass spectrometric analysis.

A liquid chromatography with mass spectrometry on-line platform that includes the orthogonal techniques of ion exchange and reversed phase chromatography is applied for C-peptide analysis. Additional improvement is achieved by the subsequent application of cation- and anion-exchange purification steps that allow for isolating components that have their isoelectric points in a narrow pH range before final reversed-phase mass spectrometry analysis. The utility of this approach for isolating fractions in the desired "pI window" for profiling complex mixtures is discussed.

Isotope dilution assay in peptide quantification: the challenge of microheterogeneity of internal standard.

Isotope dilution analysis allows quantitation of elements and different compounds in complex mixtures. The quantitation is based on a known amount of reference material (internal standard, IS) added to a sample that makes the result critically dependent on the value assigned to the standard. In the case of peptides, IS concentration is determined by nitrogen and amino acid analysis while purity is normally assessed by methods such as chromatography or electrophoresis that might not be able to detect many possible amino acid modifications, either naturally occurring or chemically induced.

Human C-peptide Quantitation by LC-MS Isotope-Dilution Assay in Serum or Urine Samples.

In this communication we report a simple and efficient approach to C-peptide quantitation using isotope dilution mass-spectrometry analysis. The method facilitates quantitation of C-peptide levels at least one order of magnitude lower compared to concentration levels achieved with an IDA method reported previously. The improvement was due to more intensive sample preparation procedure that, in turn, makes it possible to increase the sample load without a corresponding increase in matrix effects.

Use of cation exchange chromatography for human C-peptide isotope dilution - mass spectrometric assay.

An application of ion exchange chromatography for C-peptide analysis is described here. At the stage of C-peptide isolation, a strong cation exchanger (SP HP or MonoS) was used to purify the analyte from ballast proteins and peptides. The conditions of ion-exchange chromatographic separations were optimized using theoretical modeling of the net surface electric charge of the peptide as a function of pH.

Protein fractionation according to molecular size in constant pH media with immobilized charges in colinear porosity gradient.

A new method of protein electrophoresis is described here. Electrophoretic separation is performed in gel media with uniform concentration of immobilized charges, combined with porosity gradient directed against protein movement. Successful separation becomes possible due to the effect of strong sample zone compression; the latter effect is connected with complex conductivity profile dynamics in a gel system containing immobilized charges.

On the possibility of applying noncovalent dyes for protein labeling in isoelectric focusing.

Noncovalent fluorescent dyes are widely used for protein quantification and postcolumn detection in electrophoretic separations and recently some attempts to separate the precolumn labeled proteins using isoelectric focusing (IEF) have been made. In the present study, the possibility of applying the technique of protein labeling with noncovalent dyes for IEF is investigated. We found that fluorescent signal emitted by NanoOrange dye increases essentially in presence of carrier ampholyte (CA) components, which makes problematic a reliable protein detection in CA environment.

Conductivity properties of carrier ampholyte pH gradients in isoelectric focusing.

The conductivity properties of natural pH gradient created by carrier ampholytes were studied during the process of isoelectric focusing (IEF). IEF was performed in capillaries (10-30 mm long) or in microchips with the same channel length. A 10-30x reduction of the conductivity of the separation medium was observed during the establishment of pH gradient.

Buffer composition changes in background electrolyte during electrophoretic run in capillary zone electrophoresis.

The electrophoretic behaviors of different analytes in capillary zone electrophoresis were studied by the Whole Column Imaging Detection (WCID). For capillary zone electrophoresis (CZE) in conventional buffer systems, non-constant sample plug movement characterized by progressive decrease of peak migration velocity was observed. The appropriate velocity decrease was correlated with a degree of ionization of the analyzed ion, thus the effect observed could be explained by fast buffer composition change resulting in the development of a non-linear pH gradient.

CE in a nonuniform capillary modulated by a cylindrical insert, and zone-narrowing effects during sample injection.

The electrophoretic behavior of an analyte in a capillary consisting of two parts of different cross section has been investigated. Modulation of the cross-sectional area of the separation channel has been achieved by inserting a cylindrical fiber different distances into the capillary. It was shown that the zone injected into the capillary part with smaller cross section could be moved using electromigration into the wider part of the capillary with zone compression.

Heterogeneity of protein labeling with a fluorogenic reagent, 3-(2-furoyl)quinoline-2-carboxaldehyde.

Fluorogenic reagents are used for protein labeling when high-sensitivity fluorescence detection is required. Similar to traditional labeling with activated fluorescent dyes, such as fluorescein isothiocyanate, a fluorogenic reaction is expected to change the physical-chemical properties of proteins. Knowledge of these changes may be essential for efficient separation and identification of labeled proteins.