![]() Expensive to purchase and operate, these instruments are not used widely despite their capability for very high mass resolution and mass accuracy. Until quite recently, it has only been possible to meet this condition to any practical degree in Fourier transform ion cyclotron resonance (FT ICR) mass spectrometers. Overall, ECD spectra are easier to interpret than CID spectra.ĮCD requires that the precursor ions be forced to mingle with a dense population of low-energy electrons. 21, 22 Finally, ECD occurs at more backbone sites and, thus, provides more extensive coverage of a peptide’s sequence than does CID. 15 Labile post-translational modifications, for example, phosphorylation, 16, 17 o-glycosylation, 18, 19 and ubiquination, 20 remain intact during ECD MS/MS experiments thereby allowing the site and the nature of the modifications to be more reliably determined. -type and z-type) fragment ions, 14 and these cleavages show almost no selectivity for particular amino acids–two exceptions being proline and disulphide bonds. ![]() 6 This process generates almost exclusively c-type and z 6 - 13 In ECD, the exothermic capture of a free, low-energy (~1 eV) electron by a multiply protonated (cationic) peptidic precursor induces one of the peptide’s N– C α backbone-bonds to break before the electronic excitation energy is distributed among all of the molecule’s degrees of freedom. 5, 6 In the end, interpreting CID mass spectra can be much more tedious than acquiring them.Įlectron-capture dissociation (ECD) has been shown to be an effective alternative to CID. Since thermal activation favors fragmentation pathways that require the least energy, labile post-translational modifications and, along with them, information crucial for understanding physiological processes are readily lost in CID analyses. As a result, gaps are left in the sequence-data, and the heights of the fragments’ signals in the mass spectra vary from almost background level to that of the most intense signal in the spectrum. 3, 4 Unfortunately, this type of fragmentation does not occur between all the residues in peptides of a given amino acid sequence. In CID, the internal energy of a cationic peptide-precursor is raised through gas-phase collisions between the latter and inert atoms or molecules this thermal activation will in many instances induce a charge-directed cleavage of a peptide bond to produce a b-type or y-type fragment ion. 1, 2 In proteomic applications of tandem mass spectrometry (MS/MS), proteins and peptides can be induced to fragment to varying degrees by a number of physicochemical processes of all of them, however, collision-induced dissociation (CID) has so far proven to be the most operationally practical and analytically robust. Mass spectrometry is performed on a molecular sample in multiple, tandem stages to probe incisively into the complexities of molecular structure and to markedly increase specificity and sensitivity in analyses of complex mixtures of molecules. The cell’s design and compact construction should allow it to be incorporated at relatively little cost into virtually any type of tandem mass spectrometer, for example, triple quadrupole, hybrid quadrupole ion trap, hybrid quadrupole time-of-flight, or even FT-ICR. The mass spectra produced with the modified instrument appear in all respects (other than resolution and mass accuracy, which were limited by the mass spectrometer used) to be at least as good for purposes of peptide identification as those recorded with Fourier transform ion cyclotron resonance (FT ICR) instruments however, the effort and time to produce the mass spectra were much less than required to produce their FT ICR counterparts. These spectra were readily obtained without recourse to a buffering gas or synchronizing electron injection with a specific phase of an RF field. The RFF electrostatic/magnetostatic ECD cell was installed in a Finnigan TSQ700 ESI triple quadrupole (QqQ) spectrometer, and its performance was evaluated by recording product-ion spectra of doubly protonated substance P, doubly protonated gramicidin S, doubly protonated neurotensin, and triply protonated neurotensin. The device is based on interleaving a series of electrostatic lenses with the periodic structure of magnetostatic lenses commonly found in a traveling wave tube. A radio frequency-free (RFF), analyzer-independent cell has been devised for electron-capture dissociation (ECD) of ions.
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