Nonresonance excitation is a universal ion excitation and ejection method in which increased ion kinetic energy is achieved by the combination of an axial dc dipole and the rf trapping fields. The method does not require the applied excitation frequency to match with the secular frequency of the precursor ions to effect collision-induced dissociation (CID) for tandem mass spectrometry applications. Therefore, it is free of the effects of secular frequency changes caused by space-charge and simplifies the optimization of tandem mass spectrometry parameters when combined with gas chromatography-tandem mass spectrometry (GC-MS/MS). Computer simulations show that in contrast to the resonance excitation process, the nonresonance excitation process is able to accelerate thermal ions to kinetic energies in excess of 40 eV in a few microseconds. Based on simulations, we expect that the rapid deposition of energy by this method may allow the study, in ion traps, of high energy decomposition channels of precursor ions with multiple decomposition channels. Furthermore, the method is able to simultaneously excite multiple precursor ions, for example, excite both analyte and its coeluting isotopically labeled internal standard for GC-MS/MS analysis. A GC-MS/MS analysis of 100 pg of n-butylbenzene is demonstrated with a signal-to-noise ratio of 3624, which is over an order of magnitude higher than the signal-to-noise ratio of 345 obtained by full scan gas chromatography-mass spectrometry. In addition, the nonresonance excitation method can be used as a low pass mass filter in the chemical ionization (CI) mode to eject undesired fragment ions that result from direct electron ionization. This new CI method, selected ejection chemical ionization, can produce a CI spectrum without contamination of sample fragment ions from electron ionization.
A new combination of a dual EI/CI ion source with a quadrupole ion trap mass spectrometer has been realized in order to efficiently produce negative ions in the reaction cell. Analysis of volatile compounds was performed under negative ion chemical ionization (NICI) during a reaction period where selected reactant negative ions, previously produced in the external ion source, were allowed to interact with molecules, introduced by hyphenated techniques such as gas chromatography. The O2*-, CH3O-, and Cl- reactant ions were used in this study to ensure specific ion/molecule interactions such as proton transfer, nucleophilic displacement, or charge exchange processes, respectively leading to even-electron species, i.e., deprotonated [M - H]- molecules, diagnostic [M - R]- ions, or odd-electron M*- molecular species. The reaction orientation depends on the thermochemistry of reactions within kinetic controls. First analytical results are presented here for the trace-level detection of several contaminants under NICI/Cl- conditions. Phosphorus-containing compounds (malathion, ethyl parathion, and methyl parathion as representative for pesticides) and nitro-containing compounds (2,4,6-trinitrotoluene for explosive material) have been chosen in order to explore the analytical ability of this promising instrumental coupling.
A robust process to manufacture AMG 232 was developed to deliver drug substance of high purity. Highlights of the commercial process development efforts include the following: (i) use of a novel bench-stable Vilsmeier reagent, methoxymethylene-N,N-dimethyliminium methyl sulfate, for selective in situ activation of a primary alcohol intermediate; (ii) use of a new crystalline and stable isopropyl calcium sulfinate reagent ensuring robust preparation of a sulfone intermediate; (iii) development of a safe ozonolysis process conducted in an aqueous solvent mixture in either batch or continuous manufacturing mode; and (iv) control of the drug substance purity by crystallization of a salt rejecting impurities effectively. The new process was demonstrated to afford the drug substance (99.9 LC area %) in 49.8% overall yield from starting material DLAC (1).
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