FAB and chemical ionization in the production of [M+ H]+ and [M− H]− species from 2-aryl-2-methyl-1,3-dithianes

The unimolecular fragmentations of [M + H]⁺ and [M – H]^? ions from four 2-aryl-2-methyl-1,3-dithianes are described and clarified with the aid of deuterated derivatives. Comparison of the MIKE spectra of [M + H]⁺ species obtained under chemical ionization and fast atom bombardment (FAB) conditions reveals differences which are attributed to the different energetics involved in the two ionization processes. It is suggested that FAB is a ‘softer’ ionization technique but, at the same time, it provides, for the possibility of solvation, reaction sites not available in gas-phase protonation. [M – H]^? species and anionic fragments thereof were generally not obtained under FAB(?) conditions. [M – H]^? ions are readily produced in gas-phase reactions with OH^? via proton abstraction from C(4) or C(5), and from the 2-methyl substituent; and they fragment according to several reaction pathways.     

Comparison of the stable products formed by fast atom bombardment and γ-irradiation of glycerol

The major end-products formed by fast atom bombardment (FAB) and γ-irradiation of glycerol have been identified using capillary gas chromatography/mass spectrometry. The product distributions differ dramatically. Products resulting from the recombination of either carbon-centered or oxygen-centered radicals are evident for both sources of irradiation. However, the major FAB-generated products are formed by the recombination of carbon-centered [G – H]^· radicals with other carbon-centered radicals while the major γ-radiolysis products result from the recombination of oxygen-centered [G–H]^· radicals with lower-weight carbon-centered species. γ-Radiolysis of an N₂O-saturated aqueous solution of glycerol, experimental conditions that strongly favor the formation of carbon-centered [G – H]^· radicals at the expense of the oxygen-centered species, yielded some products that were identical to those produced by FAB of neat glycerol. Finally, the free radicals produced by γ-radiolysis of glycerol were investigated by electron spin resonance spectroscopy and spin trapping with 5,5-dimethyl-1-pyrrolne-TV-oxide. The presence of only the carbon-centered free radical was established by this technique. The implications of these results are discussed.     

Negative-ion fast atom bombardment mass spectrometry of N-phosphoamino acids

The fragmentation patterns of N-phosphoamino acids in negative-ion fast atom bombardment mass spectrometry (FABMS) showed different characteristics to those in positive-ion FABMS. Six typical N-diisopropyloxyphorphorylamino acids all had intense [M ? 1]^? peaks, and they underwent similar fragmentation pathways. In general, the elimination of one alkene molecule followed by the loss of one molecule of alcohol occurred. They also favoured an N → O rearrangement reaction, followed by fragmentation to (RO)₂ PO₂^? and (RO) (HO)PO₂^?.     

Fast Atom Bombardment Mass Spectrometry of Organophosphorus Compounds

Abstract

Fast atom bombardment mass spectrometry has been applied to a range of ionic, zwitterionic, and thermally labile organophosphorus compounds and has been shown to be a potentially valuable aid to identification and characterisation. Results are presented for the positive ion spectra of quasiphosphonium salts, aminophosphonic, aminophosphonous, and aminophosphinic acids, phosphonopeptides, and a number of heat sensitive derivatives. The quasiphosphonium intermediates derived from alkyl esters of phosphorus (III) acids and halogeno compounds generally show base peaks corresponding to the phosphonium ion which fragments to give the protonated form of the Arbuzov product. Strong characteristic peaks are also obtained from various phosphonic and phosphinic derivatives. α- and ω-aminoalkanephosphonic acids and their guanidino analogues give base peaks corresponding to [M+H]⁺ ions and show simple fragmentations arising mainly from the loss of HPO₃ and H₃PO₃ Phosphonous derivatives give peaks corresponding to [M+H]⁺ and [2M+H]⁺ with the base peak apparently resulting from the elimination of HPO₃ from the dimeric structure. Elimination of H₃PO₂ is also indicated. Examples of phosphonopeptides are also shown to give base peaks at [M+H]⁺ and to exhibit characteristic fragmentations that are of potential value as aids to identification. Fast atom bombardment mass spectra have also been recorded for a number of pesticidal phosphorodithioates, their principal metabolites, and some related esters. Although [M+H]⁺ peaks are clearly present in all cases, the intensity is variable and fragmentations are generally more complex than those obtained for the compounds referred to above. O,O-Diethyl phosphorodithioates, for example, frequently give rise to (EtO)₂PS⁺, which fragments further by stepwise elimination of ethylene as is also observed in electron impact mass spectrometry. We are grateful to SERC for support of this work and for FAB mass spectrometry facilities at the Physico-Chemical Measurements Unit, Harwell.     

Neurosteroid analogues: synthesis of 6-aza-allopregnanolone

An efficient synthesis of 6-azapregnane derivatives and their biological activity is described. The nitrogen was introduced into the B ring using Beckmann rearrangement of the (E)-oxime of 6-oxo-B-nor-5α-pregnane derivatives. The required 3α-hydroxyl was produced either by solvolysis of the corresponding 3β-mesyloxy group or by the Meerwein-Ponndorf-Verley reduction of the 3-oxo group; this reduction could be carried out selectively with an unprotected 3,20-dioxo derivative. The binding of the 6-aza-steroids to the γ-aminobutyric acid receptor (GABA_A) was measured using [³⁵S]-tert-butyl-bicyclo[2.2.2]phosphorothionate (TBPS) and [³H]flunitrazepam. The only analogue to be slightly active was that lacking any oxygen function in position 3.     

Ion-molecule reactions observed for nitroaromatic compounds in negative ion fast atom bombardment mass spectrometry

Analyses of a series of nitroaromatic compounds using fast atom bombardment (FAB) mass spectrometry are discussed. An interesting ion-molecule reaction leading to [M + O ? H]^? ions is observed in the negative ion FAB spectra. Evidence from linked-scan and collision-induced dissociation spectra proved that [M + O ? H]^? ions are produced by the following reaction: M + NO₂^? → [M + NO₂]^? → [M + O ? H]^?. These experiments also showed that M^?˙ ions are produced in part by the exchange of an electron between M and NO₂^? species. All samples showed M^?˙, [M ? H]^? or both ions in their negative ion FAB spectra. Not all analytes studied showed either [M + H]⁺ and/or M⁺˙ in the positive ion FAB spectra. No M⁺˙ ions were observed for ions having ionization energies above ～9 eV.     

A 15N labelling,FD and FAB study of ammonia loss from protonated arginine molecules

The positive ion field desorption (FD) spectrum of arginine taken at the best anode temperature only contains a peak due to [M+H]⁺ ions. At higher emitter temperatures a considerable amount of fragmentation is induced and the [M+H NH₃]⁺ ions become most abundant. Specific ¹⁵N labelling reveals that the eliminated ammonia molecule, exclusively, contains one of the terminal nitrogen atoms of the guanidyl group. This also applies to the ammonia loss from metastably decomposing [M+H]⁺ ions. The positive ion fast atom bombardment (FAB) spectrum shows more fragmentation than the FD spectrum. In contrast with the FD results, the [M+H]⁺ ions generated upon FAB with ion lifetimes <10⁻⁶ s eliminate both ammonia containing one of the terminal nitrogen atoms of the guanidyl group and ammonia containing the α-amino group in the ratio of 1.35, as found by ¹⁵N labelling. The metastably decomposing [M+H]⁺ ions, however, eliminate only the former ammonia molecule. In the negative ion FD and FAB spectra no other peak than that corresponding to the [M H]⁻ ion is observed. Some attention has been paid to the thermal degradation of arginine on the basis of a few Curie-point pyrolysis experiments.     

Molecular species analysis of arachidonate containing glycerophosphocholines by tandem mass spectrometry

Carboxylate anions arising from collision-induced dissociation (CID) of the [M - 15]^- ion produced by fast atom bombardment (FAB) of glycerophosphocholine (GPCho) were previously shown to be produced in an abundance ratio of 1:3 for the carboxylic acids esterified at sn - 1 and sn - 2, respectively. This observation has been confirmed in a series of 13 synthetic GPCho molecular species. A good correlation was found between the isomeric purity of GPCho molecular species as determined by negative-ion FAB/CID analysis and the isomeric purity of the sn - 2 fatty acid using a phospholipase A₂ assay. Negative-ion FAB mass spectra of several 1-0-alkyl-2-acyl-GPCho molecular species were found to be similar to those of diacyl GPCho. However, the cm spectra from the major high-mass ions are different from those of the diacyl species in that the [M - 15]^- ion yields only one carboxylate anion and the [M - 86]^- undergoes a neutral loss of the sn - 2 carboxylic acid as a major decomposition product. These results suggest several rules useful for structural characterization of GPCho molecular species by negative-ion tandem mass spectrometry (MS/MS): (1) For diacyl species, the mass of the two carboxyl anions plus the mass of the GPeho backbone (minus a methyl group) must correspond to the mass of the [M - 15] anion; (2) for diacyl species there is a carboxylate anion ratio approximately 1:3 for the substituents at sn - 1 and sn - 2; and (3) for alkylether species, only one fatty acyl group is present, and the difference between the [M - 15] ion and the GPCho backbone (minus methyl) plus the fatty acyl group at sn - 2 corresponds to an alkylether substituent. (4) Assignment of ether-linked molecular species can be made from the [M - 86]^- ion, which has a strong neutral loss of the sn - 2 fatty acid. Analysis of GPCho isolated from human neutrophils by total lipid extraction and normal-phase HPLC was carried out by negative-ion FABand MS/MS. The major arachidonate-eontaining molecular species, which comprise only 5% of total GPCho, were identified by using precursor ion scans for the arachidonate anion, m/ z 303. Decomposition of identified. precursor ions permitted the assignment of those molecular species of GPCho that contain arachidonate at sn - 2 and identification of the substituent at the sn - 1 position. These results were compared to previously identified molecular species from human neutrophils. Several minor arachidonate-containing molecular species were tentatively identified.     

Negative- and positive-ion chemical ionization mass spectra of aromatic amines: Surface-assisted reactions involving oxygen

The O₂–N₂ and O₂–Ar negative-ion chemical ionization mass spectra of aromatic amines show a series of unusual ions dominated by an addition appearing at [M + 14]^?˙. Other ions are observed at [M – 12]^?˙, [M + 5]^?˙, [M + 12]^?˙, [M + 28]^?˙ and [M + 30]^?˙. Ion formation was studied using a quadrupole instrument equipped with a conventional chemical ionization source and a Fourier transform ion cyclotron resonance (FTICR) mass spectrometer. These studies, which included the examination of ion chromatograms, measurement of positive-ion chemical ionization mass spectra, variation of ion source temperature and pressure and experiments with ¹⁸O₂, indicate that the [M + 14]^?˙ ion is formed by the electron-capture ionization of analytes altered by surfaceassisted reactions involving oxygen. This conversion is also observed under low-pressure conditions following source pretreatment with O₂. Experiments with [¹⁵N]aniline, [2,3,4,5,6-²H₅] aniline and [¹³C₆]aniline show that the [M + 14]^?˙ ion corresponds to [M + O ? 2H]^?˙, resulting from conversion of the amino group to a nitroso group. Additional ions in the spectra of aromatic amines also result from surface-assisted oxidation reactions, including oxidation of the amino group to a nitro group, oxidation and cleavage of the aromatic ring and, at higher analyte concentrations, intermolecular oxidation reactions.     

Collision-Induced Dissociation Analysis of Negative Atmospheric Ion Adducts in Atmospheric Pressure Corona Discharge Ionization Mass Spectrometry

Collision-induced dissociation (CID) experiments were performed on atmospheric ion adducts [M + R]^– formed between various types of organic compounds M and atmospheric negative ions R^- [such as O₂ ^–, HCO₃ ^–, COO^–(COOH), NO₂ ^–, NO₃ ^–, and NO₃ ^–(HNO₃)] in negative-ion mode atmospheric pressure corona discharge ionization (APCDI) mass spectrometry. All of the [M + R]^– adducts were fragmented to form deprotonated analytes [M – H]^– and/or atmospheric ions R^–, whose intensities in the CID spectra were dependent on the proton affinities of the [M – H]^– and R^– fragments. Precursor ions [M + R]^– for which R^- have higher proton affinities than [M – H]^– formed [M – H]^– as the dominant product. Furthermore, the CID of the adducts with HCO₃ ^– and NO₃ ^-(HNO₃) led to other product ions such as [M + HO]^– and NO₃ ^–, respectively. The fragmentation behavior of [M + R]^– for each R^– observed was independent of analyte type (e.g., whether the analyte was aliphatic or aromatic, or possessed certain functional groups).      

Fast atom bombardment mass spectra of telluronium salts

The fast atom bombardment (FAB) mass spectra of telluronium salts were studied. The spectra exhibit the intact cation (C⁺) and cluster ions ([M + C]⁺). The principal fragment ions in the FAB mass spectra of telluronium salts are [RTe]⁺, [R₂Te]⁺˙, [R₂Te − H]⁺, [RTeR′]⁺˙, and [RTeR′ + H]⁺. When the anion was [BPh₄]⁻, interesting cluster ions such as [M + C − BPh₃]⁺ appeared.     

Characteristic fragmentations of peptide derivatives containing proline in negative-ion fast atom bombardment mass spectrometry

Fragmentations of N-benzyloxycarbonyl-protected tripeptide ethyl esters containing proline were compared with those of the corresponding peptide derivatives not containing proline in negative-ion fast atom bombardment mass spectrometry. The fragment ion [M – 109]^? due to loss of the benzyloxy group followed by dehydrogenation from the peptide molecule was the base peak in the negative-ion mass spectra for the peptides not containing proline, whilst it was a very weak fragment ion or not observed at all in those for the peptides containing proline. These results suggest that the fragmentations of the peptide derivatives in negative-ion fast atom bombardment mass spectrometry depend on the conformational difference of the peptide derivatives owing to the existence of proline in the derivative.     

Electron-impact studies—LV: Skeletal rearrangement and hydrogen scrambling processes in the positive and negative-ion mass spectra of phenyl derivatives of elements of group IV and V

The mass spectra of many triphenyl/tetraphenyl derivatives of the Group IV and V elements exhibit the processes [M⁺˙ ? C₁₂H₁₀] and/or [M⁺˙ ? C₆H₅· ? C₁₂H₁₀]. These fragmentations are not preceded by hydrogen scrambling between all the phenyl rings. Hydrogen scrambling does occur in certain fragment ions prior to fragmentation in both the positive and negative-ion spectra. The process [M⁺˙ ? C₁₂H₁₀] occurs in the negative-ion mass spectrum of tetraphenylsilane.     

Fast atom bombardment mass spectral study of tetracycline antibiotics

In the fast atom bombardment mass spectra of tetracyclines, ammonia elimination fragment ions, [M + H – NH₃]⁺ and [M + H – NH₃ – H₂O]⁺, appeared with considerable abundances. A plausible mechanism for the loss of ammonia from [M + H]⁺ was discussed based on results by measurements on various types of tetracyclines and benzamides as the model compounds and B/E linked scanning. The results indicated that the loss of ammonia occurred in the carboxyamide moiety in the A ring and was accelerated by an ortho-hydroxy group. The same fragmentations were observed in the electrospray mass spectra of tetracyclines with a skimmer-capillary voltage differential of 150 V.     

Behaviour of methyl red under fast atom bombardment conditions

The influence of the pH, the nature of the matrix and the presence of a surfactant on the positive- and negative-ion abundances in the molecular mass region in the fast atom bombardment (FAB) mass spectra of methyl red was investigated. A small but significant pH effect was observed which was attributed to the non- or at the most low surface-active character of the intact methyl red molecule. As expected, the more basic the solution, the less protonated molecules with respect to M⁺˙ are observed and in the negative-ion mode less [M + H]^? and more [M – H]^? ions with respect to M^?˙ were found. In contrast to neutral solutions, both acidic and basic solutions give a long-lasting stable response of all methyl red ions. For dyes with a moderately negative redox potential such as methyl red, beam-induced redox reactions seem to play a role in the ionization process, the neutral medium offering the best conditions for reduction processes. The ion intensities in the molecular mass region depend on the nature of the matrix. Protonation of the molecule has been found to be more effective in glycerol than in 3-nitrobenzyl alcohol; the former also appears to offer the best conditions for reduction processes. Anionic and cationic surfactants effectively suppress the contribution of ions from glycerol in both positive- and negative-ion spectra and generally promote the formation of analyte ions at the surface. The most important effect of the surfactant in a neutral medium seems to be the promotion of a regular transport of ions and molecules to the surface, which permits the creation of stable ion currents, instead of an unstable ion beam if the surfactant is absent. Moreover, when the surfactant is present an increase of the sample ion abundances is observed. Redox reactions involving molecules and molecular ions and also molecules and preformed ions in the solution, brought to the surface by micelles, have been proposed to give some contribution for the small but significant enhanced abundance of [M + nH]⁺ (n > 1) ions with respect to [M + H]⁺ ions, in the presence of a surfactant. The results have been rationalized in terms of the surface phenomena while the important role of surfactants for obtaining better FAB mass spectra is emphasized.     

Fast atom bombardment mass spectrometric study of benzyloxycarbonyl-protected tetrapeptides containing proline

Fragmentations of N-benzyloxycarbonyl-protected tetrapeptide ethyl esters containing L -alanine and L -proline, in which changes in the numbers and positions of prolyl residues were observed, were studied by negative-ion fast atom bombardment mass spectrometry. A significant difference was found among the abundances of the molecule ions and the fragment ions formed by the cleavage of the benzyloxycarbonyl group, depending on the numbers and positions of prolyl residues in the derivatives. The results indicate that the conformational differences in the tetrapeptide derivatives due to the existence of proline affect fragmentations of molecules in the solution phase in negative-ion fast atom bombardment mass spectrometry.     

Fast atom bombardment (FAB) mass spectrometry of piperidine N-oxide derivatives and free radical quenching under FAB conditions

Mechanisms are proposed for the formation of M⁺, [M + 2H]⁺ and [M + 3H]⁺ ions in the fast atom bombardment (FAB) mass spectra of 4-(2,2,6,6-tetramethyl-1-oxyl)-piperidol and its carboxylates. Free radical quenching induced by the fast atom beam has been observed. The effects of temperature on the radical quenching and of acid on the FAB mass spectra are discussed. The experiment showed that the volatile liquid samples with vapour pressures higher than that for glycerol produced M⁺ even-electron molecular ions, and the FAB mass spectra were similar to the corresponding electron ionization mass spectra. For the solid samples, it was found that the free radicals were quenched during the FAB process so that the mononitroxide and dinitroxide compounds produced [M + 2H]⁺ and [M + 3H]⁺ ions, respectively. Further experiments showed that the intensities and stabilities of [M + 2H]⁺ and [M + 3H]⁺ ions could be improved by addition of acids.     

Fast-atom bombardment mass spectrometry and low energy collision-induced tandem mass spectrometry of tauroconjugated bile acid anions

Fragmentation of negative ions produced by fast-atom bombardment (FAB) from 14 tauroconjugated bile acids and some of their deuterated analogs has been studied by mass spectrometry and by collision-induced dissociation (CED) tandem mass spectrometry at low energy. Low energy collision-induced dissociation of the deprotonated molecules [M - H]^? of these tauroconjugated bile acids leads to both charge-driven and charge-remote fragmentations (CRF). The former yields neutral loss from the side chain with charge migration during the fragmentation process. These fragments dominate the CID spectra, but are absent from the FAB spectra. Their relative abundances are dependent on the number and the positions of the hydroxyl groups in the steroid nucleus and thus permit distinction among some positional isomers. The CRF fragments correspond to cleavages in the side chain up to fragmentations across the steroid rings with charge retention on the sulfonate group. These CRF fragments, which also are useful for structural identification, are less intense in CID than in FAB spectra. It appears that these charge-remote fragments are favored by unsaturation in the steroid rings, either as keto groups or as endocyclic double bonds. Tandem mass spectrometry combined with the use of deuterated analogs demonstrates that the structures of the survivor pseudomolecular ions and of the CRF fragments are not rearranged.     

Collisionally activated mass spectra of [M?H] ions of polyhydroxy and hydroxy ether compounds

Collision-induced decomposition/mass-analyzed ion kinetic energy or collisionally activated mass spectra of [M ? H]^? ions of polyhydroxy compounds and other alcohols and ethers are reported. The [M ? H]^? ion of each compound is produced under OH^? negative ion chemical ionization mass spectrometric conditions. Characteristic fragmentations are observed that include production of [M ? H ? 2]^?, [M ? H ? 18]^? and [M ? H ? 32]^? ions. Certain other fragment ions in the collisionally activated mass spectra make it possible to distinguish among structural isomers. In polyhydroxy compounds, fragmentation increases as the number of hydroxyl groups increase, and carbon-carbon bond cleavage becomes favored.     

Fragmentations of peptide derivatives depending on the positions of proline in negative-ion fast atom bombardment mass spectrometry

Fragmentations of N-benzyloxycarbonyl-protected tripeptide ethyl esters, in which changes in the numbers and positions of prolyl residues were observed, were examined by negative-ion fast atom bombardment mass spectrometry. A significant difference was found among the intensities of the fragment ions formed by cleavage of the benzyloxycarbonyl group, depending on the numbers and positions of prolyl residues in the derivatives. These results suggest that the fragmentations of the peptide derivatives in negative-ion fast atom bombardment mass spectrometry depend on the conformational differences in the peptide derivatives due to the existence of proline, and permit the prediction of the positions of proline in the peptides.