Fragmentation of gas-phase ions is essential to tandem mass spectrometry and occurs between different stages of mass analysis. There are many methods used to fragment the ions and these can result in different types of fragmentation and thus different information about the structure and composition of the molecule.
In-source fragmentation Often, the
ionization process is sufficiently violent to leave the resulting ions with sufficient
internal energy to fragment within the mass spectrometer. If the product ions persist in their non-equilibrium state for a moderate amount of time before auto-dissociation this process is called
metastable fragmentation. Nozzle-skimmer fragmentation refers to the purposeful induction of in-source fragmentation by increasing the nozzle-skimmer potential on usually
electrospray based instruments. Although in-source fragmentation allows for fragmentation analysis, it is not technically tandem mass spectrometry unless metastable ions are mass analyzed or selected before auto-dissociation and a second stage of analysis is performed on the resulting fragments. In-source fragmentation can be used in lieu of tandem mass spectrometry through the utilization of enhanced in-source fragmentation annotation (EISA) technology which generates fragmentation that directly matches tandem mass spectrometry data. Fragments observed by EISA have higher signal intensity than traditional fragments which suffer losses in the collision cells of tandem mass spectrometers. EISA enables fragmentation data acquisition on MS1 mass analyzers such as time-of-flight and single quadrupole instruments. In-source fragmentation is often used in addition to tandem mass spectrometry (with post-source fragmentation) to allow for two steps of fragmentation in a pseudo MS3-type of experiment.
Collision-induced dissociation Post-source fragmentation is most often what is being used in a tandem mass spectrometry experiment. Energy can also be added to the ions, which are usually already vibrationally excited, through post-source collisions with neutral atoms or molecules, the absorption of radiation, or the transfer or capture of an electron by a multiply charged ion.
Collision-induced dissociation (CID), also called collisionally activated dissociation (CAD), involves the collision of an ion with a neutral atom or molecule in the gas phase and subsequent dissociation of the ion. For example, consider :{AB+} + M -> {A} + {B+} + M where the ion AB+ collides with the neutral species M and subsequently breaks apart. The details of this process are described by
collision theory. Due to different instrumental configuration, two main different types of CID are possible:
(i) beam-type (in which precursor ions are fragmented on-the-flight) and
(ii) ion trap-type (in which precursor ions are first trapped, and then fragmented). A third and more recent type of CID fragmentation is
higher-energy collisional dissociation (HCD). HCD is a CID technique specific to
orbitrap mass spectrometers in which fragmentation takes place external to the ion trap, it happens in the HCD cell (in some instruments named "ion routing multipole"). HCD is a trap-type fragmentation that has been shown to have beam-type characteristics. Freely available large scale high resolution tandem mass spectrometry databases exist (e.g. METLIN with 960,000 molecular standards each with experimental CID MS/MS data), and are typically used to facilitate small molecule identification.
Electron capture and transfer methods The energy released when an electron is transferred to or captured by a multiply charged ion can induce fragmentation.
Electron-capture dissociation If an
electron is added to a multiply charged positive ion, the
Coulomb energy is liberated. Adding a free electron is called
electron-capture dissociation (ECD), and is represented by :[\ce M + n\ce H]^{n+} + \ce{e^- ->} \left[ [\ce M + (n-1)\ce H]^{(n-1)+} \right]^* \ce{-> fragments} for a multiply protonated molecule M.
Electron-transfer dissociation Adding an electron through an ion-ion reaction is called
electron-transfer dissociation (ETD). Similar to electron-capture dissociation, ETD induces fragmentation of cations (e.g.
peptides or
proteins) by transferring
electrons to them. It was invented by
Donald F. Hunt,
Joshua Coon, John E. P. Syka and Jarrod Marto at the
University of Virginia. ETD does not use free electrons but employs radical anions (e.g.
anthracene or
azobenzene) for this purpose: :[\ce M + n\ce H]^{n+} + \ce{A^- ->} \left[ [\ce M + (n-1)\ce H]^{(n-1)+} \right]^* + \ce{A -> fragments} where A is the anion. ETD cleaves randomly along the peptide backbone (c and z ions) while side chains and modifications such as phosphorylation are left intact. The technique only works well for higher charge state ions (z>2), however relative to
collision-induced dissociation (CID), ETD is advantageous for the fragmentation of longer peptides or even entire proteins. This makes the technique important for
top-down proteomics. Much like ECD, ETD is effective for peptides with
modifications such as phosphorylation. Electron-transfer and higher-energy collision dissociation (EThcD) is a combination ETD and HCD where the peptide precursor is initially subjected to an ion/ion reaction with
fluoranthene anions in a
linear ion trap, which generates c- and z-ions. In the second step HCD all-ion fragmentation is applied to all ETD derived ions to generate b- and y- ions prior to final analysis in the orbitrap analyzer.
Negative electron-transfer dissociation Fragmentation can also occur with a deprotonated species, in which an electron is transferred from the species to a cationic reagent in a negative electron transfer dissociation (NETD): :[\ce M-n\ce H]^{n-} + \ce{A+ ->} \left[ [\ce M-n\ce H]^{(n+1)-} \right]^* + \ce{A -> fragments} Following this transfer event, the electron-deficient anion undergoes internal rearrangement and
fragments. NETD is the ion/ion analogue of
electron-detachment dissociation (EDD). NETD is compatible with fragmenting
peptide and
proteins along the backbone at the Cα-C bond. The resulting fragments are usually a•- and x-type product ions.
Electron-detachment dissociation Electron-detachment dissociation (EDD) is a method for fragmenting anionic species in mass spectrometry. It serves as a negative counter mode to electron capture dissociation. Negatively charged ions are activated by irradiation with
electrons of moderate kinetic energy. The result is ejection of electrons from the parent
ionic molecule, which causes dissociation via recombination.
Charge-transfer dissociation Reaction between positively charged peptides and cationic reagents, also known as charge transfer dissociation (CTD), has recently been demonstrated as an alternative high-energy fragmentation pathway for low-charge state (1+ or 2+) peptides. The proposed mechanism of CTD using helium cations as the reagent is: :\ce{{[{M}+H]^1+} + He+ ->} \left[ \ce{[{M}+H]^2+} \right]^* + \ce{He^0 -> fragments} Initial reports are that CTD causes backbone Cα-C bond cleavage of peptides and provides a•- and x-type product ions.
Photodissociation The energy required for dissociation can be added by
photon absorption, resulting in ion
photodissociation and represented by :{AB+} + \mathit{h\nu} -> {A} + B+ where h\nu represents the photon absorbed by the ion. Ultraviolet lasers can be used, but can lead to excessive fragmentation of biomolecules.
Infrared multiphoton dissociation Infrared photons will heat the ions and cause dissociation if enough of them are absorbed. This process is called
infrared multiphoton dissociation (IRMPD) and is often accomplished with a
carbon dioxide laser and an ion trapping mass spectrometer such as a
FTMS.
Blackbody infrared radiative dissociation Blackbody radiation can be used for photodissociation in a technique known as blackbody infrared radiative dissociation (BIRD). In the BIRD method, the entire mass spectrometer vacuum chamber is heated to create
infrared light. BIRD uses this radiation to excite increasingly more energetic
vibrations of the ions, until a bond breaks, creating fragments. This is similar to
infrared multiphoton dissociation which also uses infrared light, but from a different source. Today, SID is used to fragment a wide range of ions. Years ago, it was only common to use SID on lower mass, singly charged species because ionization methods and mass analyzer technologies weren't advanced enough to properly form, transmit, or characterize ions of high m/z. Over time, self-assembled monolayer surfaces (SAMs) composed of CF3(CF2)10CH2CH2S on gold have been the most prominently used collision surfaces for SID in a tandem spectrometer. SAMs have acted as the most desirable collision targets due to their characteristically large effective masses for the collision of incoming ions. Additionally, these surfaces are composed of rigid
fluorocarbon chains, which don't significantly dampen the energy of the projectile ions. The fluorocarbon chains are also beneficial because of their ability to resist facile electron transfer from the metal surface to the incoming ions. SID's ability to produce subcomplexes that remain stable and provide valuable information on connectivity is unmatched by any other dissociation technique. Since the complexes produced from SID are stable and retain distribution of charge on the fragment, this produces a unique, spectra which the complex centers around a narrower m/z distribution. The SID products and the energy at which they form are reflective of the strengths and topology of the complex. The unique dissociation patterns help discover the Quaternary structure of the complex. The symmetric charge distribution and dissociation dependence are unique to SID and make the spectra produced distinctive from any other dissociation technique. Fourier-transform ion cyclotron resonance are able to provide ultrahigh resolution and high mass accuracy to instruments that take mass measurements. These features make FT-ICR mass spectrometers a useful tool for a wide variety of applications such as several dissociation experiments such as collision-induced dissociation (CID, electron transfer dissociation (ETD), and others. In addition, surface-induced dissociation has been implemented with this instrument for the study of fundamental peptide fragmentation. Specifically, SID has been applied to the study of energetics and the kinetics of gas-phase fragmentation within an ICR instrument. This approach has been used to understand the gas-phase fragmentation of protonated peptides, odd-electron peptide ions, non-covalent ligand-peptide complexes, and ligated metal clusters. ==Quantitative proteomics==