Impurity identification and quantification for arginine vasopressin by liquid chromatography/high-resolution mass spectrometry.

RATIONALE: For pharmaceutical quality control, impurities may have unexpected pharmacological or toxicological effects on quality, safety, and efficacy of drugs. Arginine vasopressin (AVP) is an important cyclic peptide drug that is mainly used for the treatment of diabetes insipidus and esophageal varices bleeding. With the advancement made in analytical techniques, liquid chromatography/high-resolution mass spectrometry (LC/HRMS) has emerged as a critical technique for the identification and quantification of structurally related peptide impurities in AVP. METHODS: An LC/HRMS/MS-based method using a quadrupole ion trap-Orbitrap mass spectrometer operated in the positive ion electrospray ionization mode was developed for the determination and quantification of structurally related peptide impurities in AVP. RESULTS: Under optimized experimental conditions, three deamidation products, ([Glu4 ]AVP, [Asp5 ]AVP, and AVP acid), two amino acid deletion impurities (des-Pro7 -AVP and des-Gly9 -AVP), one amino acid insertion impurity (endo-Gly10a -AVP), one end chain reaction product (N-acetyl-AVP), and one AVP isomer were detected. Subsequent quantification using an external standard method estimated the total mass fraction of all structurally related peptide impurities in the AVP study material to be 30.3 mg/g with an expanded uncertainty of 3.0 mg/g (k = 2). CONCLUSIONS: This study complements the AVP impurity profile and improves the separation and discovery of other potential impurities in vasopressin analogues.

Rapid characterization of structure-dependency gas-phase ion/ion reaction via accumulative tandem MS.

To enable the rapid detection of biomolecule reactivity and reaction sites, we developed a method based on gas-phase ion/ion reaction and accumulative tandem mass spectrometry (MS). Structure-dependency reactions in gas-phase were performed between biomolecule ions and their reaction partner ions with opposite polarities in a quadrupole ion trap. Gas-phase peptide bioconjugation with pyridoxal-5-phosphate (PLP) was chosen as a proof-of-principle example. It is found that the Coulomb attraction force holds reaction partners close together, which increasing the reaction probability. Post reaction, reaction sites were identified by the consequent accumulative tandem MS method, in which informative product ions in low abundance were enriched by more than 100 times in another quadrupole ion trap. With enough product ions, tandem MS was performed, and reaction sites could be identified unambiguously. Since those reactions are normally biomolecular structure dependent, density functional theory (DFT) calculations were also carried out to understand the reaction mechanism. The method allows for rapid characterization of structure dependent reactivity of a biomolecule, and opens a new avenue for drug development and biomolecule structure analyses.

Ion manipulation and enrichment mass spectrometer for cleavage of disulfide bond via ion/ion reaction.

A novel mass spectrometer with the capability of ion manipulation and enrichment was developed to perform gas-phase ion/ion reactions followed by product ions accumulation. The development of this apparatus opens opportunities for more complex sequences of ion manipulations, thus offers the potential on extensive application involving ion/ion reaction. Here, cleavage of disulfide bond in peptide was demonstrated based upon this ion manipulation and enrichment mass spectrometer. Two typical peptides including S-glutathionylated ARACAKA with an intermolecular disulfide bond, and oxytocin with an intramolecular disulfide bond were chosen as typical samples to demonstrate the ability of the apparatus. After ion/ion reaction between selected peptide cations and periodate ions (IO4 - ), two kinds of product ions (eg, [M + O + H]+ and [M + H + Na + IO4 ]+ ) were enriched with a number of accumulation events. Afterwards, the enriched ions were subjected to activation, and the disulfide bond cleavage was clearly observed from the tandem mass spectra. These results illustrate the potential of this apparatus for ion manipulation performing ion/ion reaction, and low abundance product ion enrichment.

Boosting the Signal Intensity of Nanoelectrospray Ionization by Using a Polarity-Reversing High-Voltage Strategy.

Continuous efforts have been made to further improve the performance of nano-ESI. In this work, we made use of a polarity-reversing high-voltage strategy for the generation of nano-ESI (PR-nESI). Typically, a negative high voltage of -3.0 kV was first applied to the electrode and maintained for 6 s. Then the polarity was reversed, and a positive high voltage of +1.75 kV was applied for the generation of electrospray. Compared with conventional nano-ESI, PR-nESI significantly enhanced the signal intensity of protonated protein ions. The signal-to-noise ratio (S/N) of protonated protein ions was increased by 1-2 orders of magnitude. The increase of S/N was even more remarkable at lower concentrations. Furthermore, PR-nESI also had a desalting effect. Metal ion adducts of proteins were effectively removed. No metal ion adducts were identified from the spectra, even if the concentration of salt was increased to the millimolar level. The performance of PR-nESI was confirmed in the detection of different molecules including proteins, peptides, amino acids, and other small-molecule compounds. The intact folded structure of proteins was preserved during PR-nESI. No unfolding was observed in the spectra. PR-nESI was further applied to the analysis of noncovalent protein-ligand complexes and protein digest. At last, investigations into the mechanism of PR-nESI were carried out. The enhancement of signal intensity and desalting effect were related to the electromigration of the solutes in solution. With all the advantages above, PR-nESI would be a promising method in the future analytical and bioanalytical applications.