Distance-of-flight mass spectrometry (DOFMS) is demonstrated for the first time with a commercially available ion detector—the IonCCD camera. Because DOFMS is a velocity-based MS technique that provides spatially dispersive, simultaneous mass spectrometry, a position-sensitive ion detector is needed for mass-spectral collection. The IonCCD camera is a 5.1-cm long, 1-D array that is capable of simultaneous, multichannel ion detection along a focal plane, which makes it an attractive option for DOFMS. In the current study, the IonCCD camera is evaluated for DOFMS with an inductively coupled plasma (ICP) ionization source over a relatively short field-free mass-separation distance of 25.3–30.4 cm. The combination of ICP-DOFMS and the IonCCD detector results in a mass-spectral resolving power (FWHM) of approximately 900 and isotope-ratio precision equivalent to or slightly better than current ICP-TOFMS systems. The measured isotope-ratio precision in % relative standard deviation (%RSD) was ≥0.008%RSD for nonconsecutive isotopes at 10-ppm concentration (near the ion-signal saturation point) and ≥0.02%RSD for all isotopes at 1-ppm. Results of DOFMS with the IonCCD camera are also compared with those of two previously characterized detection setups.
In mass spectrometry imaging, spatial resolution is pushed to its limits with the use of ion microscope mass spectrometric
imaging systems. An ion microscope magnifies and then projects the original spatial distribution of ions from a sample surface
onto a position-sensitive detector, while retaining time-of-flight mass separation capabilities. Here, a new type of position-sensitive
detector based on a chevron microchannel plate stack in combination with a 512 × 512 complementary metal-oxide-semiconductor
based pixel detector is coupled to an ion microscope. Spatial resolving power better than 6 μm is demonstrated by secondary
ion mass spectrometry and 8–10μm spatial resolving power is achieved with laser desorption ionization. A detailed evaluation
of key performance criteria such as spatial resolution, acquisition speed, and data handling is presented. 相似文献
An ambient desorption/ionization (ADI) source, known as the flowing atmospheric pressure afterglow (FAPA), has been coupled
to a Mattauch-Herzog mass spectrograph (MHMS) equipped with a focal plane camera (FPC) array detector. The FAPA ionization
source enables direct mass spectral analysis of solids, liquids, and gases through either positive or negative ionization
modes. In either case, spectra are generally simple with dominant peaks being the molecular ions or protonated molecular ions.
Use of the FAPA source with the MHMS allows the FPC detector to be characterized for the determination of molecular species,
whereas previously only atomic mass spectrometry (MS) has been demonstrated. Furthermore, the FPC is shown to be sensitive
to negative ions without the need to change any detector parameters. The analysis of solid, liquid, and gaseous samples through
positive and negative ionization is demonstrated with detection limits (1–25 fmol/s, ∼0. 3–10 pg of analyte per mL of helium)
surpassing those obtained with the FAPA source coupled to a time-of-flight mass analyzer. 相似文献
Distance-of-flight mass spectrometry (DOFMS) separates ions of different mass-to-charge (m/z) by the distance they travel in a given time after acceleration. Like time-of-flight mass spectrometry (TOFMS), separation and mass assignment are based on ion velocity. However, DOFMS is not a variant of TOFMS; different methods of ion focusing and detection are used. In DOFMS, ions are driven orthogonally, at the detection time, onto an array of detectors parallel to the flight path. Through the independent detection of each m/z, DOFMS can provide both wider dynamic range and increased throughput for m/z of interest compared with conventional TOFMS. The iso-mass focusing and detection of ions is achieved by constant-momentum acceleration (CMA) and a linear-field ion mirror. Improved energy focus (including turn-around) is achieved in DOFMS, but the initial spatial dispersion of ions remains unchanged upon detection. Therefore, the point-source nature of surface ionization techniques could put them at an advantage for DOFMS. To date, three types of position-sensitive detectors have been used for DOFMS: a microchannel plate with a phosphorescent screen, a focal plane camera, and an IonCCD array; advances in detector technology will likely improve DOFMS figures-of-merit. In addition, the combination of CMA with TOF detection has provided improved resolution and duty factor over a narrow m/z range (compared with conventional, single-pass TOFMS). The unique characteristics of DOFMS can enable the intact collection of large biomolecules, clusters, and organisms. DOFMS might also play a key role in achieving the long-sought goal of simultaneous MS/MS.
Distance-of-flight mass spectrometry (DOFMS) is a velocity-based, spatially dispersive MS technique in which ions are detected simultaneously along the plane of a spatially selective detector. In DOFMS, ions fly though the instrument and mass separate over a set period of time. The single flight time at which all ions are measured defines the specific m/z values that are detectable; the range of m/z values is dictated by the length of the spatially selective detector. However, because each packet of ions is detected at a single flight time, multiple groups of ions can fly through the instrument concurrently and be detected at a single detector. In this way, DOFMS experiments can be interleaved to perform several mass separation experiments within a single DOF repetition period. Interleaved operation allows the orthogonal acceleration region to be operated at a repetition rate higher than the reciprocal of the flight time, which improves the duty factor of the technique. In this paper, we consider the fundamental parameters of interleaved DOFMS and report first results.
A recently described ion charge coupled device detector IonCCD (Sinha and Wadsworth, Rev. Sci. Instrum. 76(2), 2005; Hadjar, J. Am. Soc. Mass Spectrom. 22(4), 612–624, 2011) is implemented in a miniature mass spectrometer of sector-field instrument type and Mattauch-Herzog (MH)-geometry (Rev.
Sci. Instrum. 62(11), 2618–2620, 1991; Burgoyne, Hieftje and Hites J. Am. Soc. Mass Spectrom. 8(4), 307–318, 1997; Nishiguchi, Eur. J. Mass Spectrom. 14(1), 7–15, 2008) for simultaneous ion detection. In this article, we present first experimental evidence for the signature of energy loss
the detected ion experiences in the detector material. The two energy loss processes involved at keV ion kinetic energies
are electronic and nuclear stopping. Nuclear stopping is related to surface modification and thus damage of the IonCCD detector
material. By application of the surface characterization techniques atomic force microscopy (AFM) and X-ray photoelectrons
spectroscopy (XPS), we could show that the detector performance remains unaffected by ion impact for the parameter range observed
in this study. Secondary electron emission from the (detector) surface is a feature typically related to electronic stopping.
We show experimentally that the properties of the MH-mass spectrometer used in the experiments, in combination with the IonCCD,
are ideally suited for observation of these stopping related secondary electrons, which manifest in reproducible artifacts
in the mass spectra. The magnitude of the artifacts is found to increase linearly as a function of detected ion velocity.
The experimental findings are in agreement with detailed modeling of the ion trajectories in the mass spectrometer. By comparison
of experiment and simulation, we show that a detector bias retarding the ions or an increase of the B-field of the IonCCD
can efficiently suppress the artifact, which is necessary for quantitative mass spectrometry. 相似文献
A new method for the analysis of cyclic peptides (Pseudostellarins) in traditional Chinese medicine, Pseudostellaria heterophylla (Miq.) Pax, was established by high performance liquid chromatography–atmospheric pressure chemical ionization–mass spectrometry
(HPLC–APCI–MS). The real samples were separated by a reversed-phase C18 column using a binary eluent under gradient conditions. Six cyclic peptides were isolated and detected with a DAD detector.
The Pseudostellarins components were identified by APCI–MS in a negative mode. In the negative ion APCI mode, the best sensitivity
and the lowest detection limit for Pseudostellarins were obtained by using a mobile phase consisting of acetonitrile and pure
water. The APCI spectra were characterized by [M-H]− peak. The parent ions [M-H]− with highest intensity was used for quantification of one cyclic peptide-Pseudostellarin B. 相似文献
A low-temperature clean-up method for residue determination was developed and validated for 14 organophosphorus pesticides
in soybean oil, peanut oil and sesame oil by gas chromatography with flame photometric detector (GC-FPD). A different matrix
influenced the response and retention time of pesticides. Hence matrix-matched calibration standards were used to counteract
the matrix effect. The pesticide responses in blank samples of soybean oil, peanut oil and sesame oil were within the linear
range of 0.02–1 mg kg−1 and the correlation coefficients were higher than 0.9989. Average recoveries obtained from different oil samples at three
fortified levels were higher than 50% with relative standard deviations (RSDs) of less than 15%. The limit of detections (LODs)
of studied pesticides ranged from 2 to 5 μg kg−1. Thirty-nine commercial samples were analyzed, and the results were confirmed by gas chromatography–mass spectrometry (GC–MS)
in selective ion monitoring (SIM) mode. 相似文献
A method to obtain laser desorption/ionization mass spectra of organic compounds by depositing sample solutions onto a carbon substrate surface is demonstrated. The substrate consists of a thin layer of activated carbon particles immobilized on an aluminum support. In common with the porous carbon suspension samples used in previous “surface-assisted laser desorption/ionization” (SALDI) work, the mass spectra contain only a few “matrix” background ion peaks, minimizing interference with analyte ion peaks. The presence of glycerol ensured that the ion signals were stable over hundreds of laser shots. In addition, the carbon substrate surface has several advantages over the suspension samples. The use of a very thin layer of carbon significantly improves the sensitivity. Detection limits range from attomoles for crystal violet to femtomoles for bradykinin. Very little sample preparation is required as the analyte solution is simply pipetted onto the substrate surface and glycerol added. When using an alternate sample deposition method, a mass resolution for bradykinin of 1800 is achieved in linear time-of-flight mode. This is close to the resolution limit set by the detector system and above instrument specification for matrix-assisted laser desorption/ionization mass spectra. 相似文献
We have used an infrared laser to ablate materials under ambient conditions that were captured in solvent droplets. The droplets
were either deposited on a MALDI target for off-line analysis by MALDI time-of-flight mass spectrometry or flow-injected into
a nanoelectrospray source of an ion trap mass spectrometer. An infrared optical parametric oscillator (OPO) laser system at
2.94 μm wavelength and approximately 1 mJ pulse energy was focused onto samples for ablation at atmospheric pressure. The
ablated material was captured in a solvent droplet 1–2 mm in diameter that was suspended from a silica capillary a few millimeters
above the sample target. Once the sample was transferred to the droplet by ablation, the droplet was deposited on a MALDI
target. A saturated matrix solution was added to the deposited sample, or in some cases, the suspended capture droplet contained
the matrix. Peptide and protein standards were used to assess the effects of the number of IR laser ablation shots, sample
to droplet distance, capture droplet size, droplet solvent, and laser pulse energy. Droplet collected samples were also injected
into a nanoelectrospray source of an ion trap mass spectrometer with a 500 nL injection loop. It is estimated that pmol quantities
of material were transferred to the droplet with an efficiency of approximately 1%. The direct analysis of biological fluids
for off-line MALDI and electrospray was demonstrated with blood, milk, and egg. The implications of this IR ablation sample
transfer approach for ambient imaging are discussed. 相似文献
During the past decade, inductively coupled plasma mass spectrometry (ICPMS) has evolved from a delicate research tool, intended
for the well-trained scientist only, into a more robust and well-established analytical technique for trace and ultra-trace
element determination, with a few thousand of instruments used worldwide. Despite this immense success, it should be realized
that in its ’standard configuration’– i.e. equipped with a pneumatic nebulizer for sample introduction and with a quadrupole
filter – ICPMS also shows a number of important limitations and disadvantages: (i) the occurrence of spectral interferences
may hamper accurate trace element determination, (ii) solid samples have to be taken into solution prior to analysis and (iii)
no information on the ‘chemical form’ in which an element appears can be obtained. Self-evidently, efforts have been and still
are made to overcome the aforementioned limitations to the largest possible extent. The application of a double focusing sector
field mass spectrometer in ICPMS instrumentation offers a higher mass resolution, such that spectral overlap can be avoided
to an important extent. Additionally, in a sector field instrument, photons are efficiently eliminated from the ion beam,
resulting in very low background intensities, making it also very well-suited for extreme trace analysis. Also the combination
of the ICP as an ion source and a quadrupole filter operated in a so-called ‘alternate’ stability region, an ion trap or a
Fourier transform ion cyclotron resonance mass spectrometer allows high(er) mass resolution to be obtained. With modern quadrupole-based
instruments, important types of spectral interferences can be avoided by working under ‘cool plasma’ conditions or by applying
a collision cell. The use of electrothermal vaporization (ETV) or especially laser ablation (LA) for sample introduction permits
direct analysis of solid samples with sufficient accuracy for many purposes. The application range of LA-ICPMS has become
very wide and the introduction of UV lasers has led to an improved spatial resolution. Solid sampling ETV-ICPMS on the other
hand can be used for some specific applications only, but accurate calibration is more straightforward than with LA-ICPMS.
Limited multi-element capabilities, resulting from the transient signals observed with ETV or single shot LA, can be avoided
by the use of a time-of-flight (TOF) ICPMS instrument. Finally, when combined with a powerful chromatographic separation technique,
an ICP-mass spectrometer can be used as a highly sensitive, element-specific multi-element detector in elemental speciation
studies. Especially liquid (HPLC-ICPMS) and – to a lesser extent – gas (GC-ICPMS) chromatography have already been widely
used in combination with ICPMS. In speciation work, sample preparation is often observed to be troublesome and this aspect
is presently receiving considerable attention. For GC-ICPMS, new sample pretreatment approaches, such as headspace solid phase
microextraction (headspace SPME) and the purge-and-trap technique have been introduced. Also supercritical fluid chromatography
(SFC) and capillary electrophoresis (CE) show potential to be of use in combination with ICPMS, but so far the application
ranges of SFC-ICPMS and CE-ICPMS are rather limited. It is the aim of the present paper to concisely discuss the aforementioned
recent ’trends’ in ICPMS, using selected real-life applications reported in the literature.
Received: 30 November 1998 / Revised: 22 March 1999 / Accepted: 24 March 1999 相似文献
The quality of the determination of compound-specific isotopic content at natural abundance by gas chromatography–isotope
ratio measurement–mass spectrometry (GC-irm-MS) relies on the stability of the voltage generated by the ion detector Faraday
cages. The application of GC-irm-MS to the determination of δ13C (‰) and δ15N (‰) is now routine. However, for numerous applications, it is necessary to determine both the isotope content (δ15N) and the quantity (in micromoles) of analyte present. We now show that it is possible for nitrogen-containing compounds
to measure how much analyte is present with an irm mass spectrometer linked to a GC by exploiting the integrated N2 total ion current intensity (Vs) generated by measuring the 15N/14N isotope ratio. The method is validated over a range of concentration (2–70 mmol/L) and δ15N (−70 to +50‰) values for six molecules of diverse chemical nature and functionality (nortropine, norpseudotropine, nortropinone,
cysteine, taurine, glutathione). It is shown that once the ion current is calibrated, the quantitative values are of a comparable
quality to those obtained from GC with flame ionization detection (GC-FID). In addition, it is demonstrated that over a definable
range, the δ15N (‰) value is independent of the quantity of analyte introduced, confirming the validity of this method. 相似文献
We report on the preliminary testing of a new position-sensitive detector (PSD) by combining a microchannel plate (MCP) and
a charge-sensitive pixilated anode with a direct readout based on charge-coupled detector (CCD) technology, which will be
referred to as IonCCD (Hadjar et al. J Am Soc Mass Spectrom 22(4):612–623, 2011; Johnson et al. J Am Soc Mass Spectrom 22(8):1388–1394, 2011; Hadjar et al. J Am Soc Mass Spectrom 22(10):1872–1884, 2011). This work exploits the recently discovered electron detection capability of the IonCCD (Hadjar et al. J Am Soc Mass Spectrom 22(4):612–623, 2011), allowing it to be used directly behind an MC. This MCP-IonCCD configuration potentially obviates the need for electro-optical
ion detector systems (EOIDs), which typically feature a relatively difficult-to-implement 5-kV power source as well as a phosphorus
screen behind the MCP for conversion of electrons to photons prior to signal generation in a photosensitive CCD. Thus, the
new system (MCP-IonCCD) has the potential to be smaller, simpler, more robust, and more cost efficient than EOID-based technologies
in many applications. The use of the IonCCD as direct MCP readout anode, as opposed to its direct use as an ion detector,
will benefit from the instant three-to-four-order-of-magnitude gain of the MCP with virtually no additional noise. The signal/noise
gain can be used for either sensitivity or speed enhancement of the detector. The speed enhancement may motivate the development
of faster IonCCD readout speeds (currently at 2.7 ms) to achieve the 2 kHz frame rate for which the IonCCD chip was designed,
a must for transient signal applications. The presented detector exhibits clear potential not only as a trace analysis detector
in scan-free mass spectrometry and electron spectroscopy but also as a compact detector for photon and particle imaging applications. 相似文献
Microextraction by packed sorbent (MEPS) has been evaluated for fast screening of drugs of abuse with mass spectrometric detection.
In this study, C8 (octyl-silica, useful for nonpolar to moderately polar compounds), ENV+ (hydroxylated polystyrene-divinylbenzene copolymer, for extraction of aliphatic and aromatic polar compounds), Oasis MCX
(sulfonic-poly(divinylbenzene-co-N-polyvinyl-pyrrolidone) copolymer), and Clean Screen DAU (mixed mode, ion exchanger for
acidic and basic compounds) were used as sorbents for the MEPS. The focus was on fast extraction and preconcentration of the
drugs with rapid analysis using a time-of-flight (TOF) mass spectrometer as the detector with direct analysis in a real-time
(DART) source. The combination of an analysis time of less than 1 min and accurate mass of the first monoisotopic peak of
the analyte and the relative abundances of the peaks in the isotopic clusters provided reliable information for identification.
Furthermore, the study sought to demonstrate that it is possible to quantify the analyte of interest using a DART source when
an internal standard is used. Of all the sorbents used in the study, Clean Screen DAU performed best for extraction of the
analytes from urine. Using Clean Screen DAU to extract spiked samples containing the drugs, linearity was demonstrated for
ecgonine methyl ester, benzoylecgonine, cocaine, and cocaethylene with average ranges of: 65–910, 75–1100, 95–1200, and 75–1100
ng/mL (n = 5), respectively. The limits of detection (LOD) for ecgonine methyl ester, benzoylecgonine, cocaine, and cocaethylene were
22. 9 ng/mL, 23. 7 ng/mL, 4. 0 ng/mL, and 9.8 ng/mL respectively, using a signal-to-noise ratio of 3:1. 相似文献
NPC1161 is an 8-aminoquinoline anti-malarial analog, which has a favorable toxicity profile relative to primaquine and other 8-aminoquinolines. High-performance liquid chromatographic method was developed for the determination of NPC1161, primaquine and their metabolites in biological samples in order to facilitate metabolic and pharmacokinetic studies. The method includes extraction of the unchanged drugs and their metabolites from the biological samples. Separation was achieved by reversed-phase chromatography on a C18 column with water–acetonitrile both containing 0.025% trifluoroacetic acid as the mobile phase. Recoveries of NPC1161 and its metabolites were greater than 60% in various biological samples tested. No interference with the components of the biological material was observed. The detector response was linear with concentrations of NPC1161 and its metabolites (desalkyl NPC1161 and carboxy NPC1161) in the ranges from 0.5 to 80.0, 0.4–60.0 and 0.4–70.0 μg mL−1, respectively. A mass spectrometry coupled with electrospray ionization (ESI) interface method is described for the identification of NPC1161 and its metabolites in biological samples. This method involved the use of the [M + H]+ions of NPC1161, C3 analog (internal std. for the assay), desalkyl NPC1161 and carboxy NPC1161 at m/z 434, 406, 349 and 449 in the positive ion mode with extractive ion monitoring (EIM). This method will have an important application in pharmacokinetic studies of NPC1161 and in understanding the mechanism of metabolism of this novel 8-aminoquinoline analog in more detail. 相似文献
A fast, sensitive and specific method for routine determination of residues from Chlormequat (CAS no. 7003-89-6) is described.
The method is based on a simple clean-up using an SPE-C18 cartridge, high-performance liquid chromatography on a standard C18 column (Spherisorb S5 ODS1) and specific detection and quantification by electrospray mass spectrometry (LC-MS/MS). 13C-Chlormequat was synthesised for use as internal standard. Samples were extracted with methanol – water – acetic acid. Internal
standard and ammonium acetate were added before C18-cartridge clean up and residues eluted with methanol – water – acetic acid, containing 50 mM ammonium acetate. Chromatographic
separation was achieved using a solvent composed of acetonitrile – methanol – water – acetic acid (53:21:25:1 by volume),
containing 50 mM ammonium acetate. Electrospray ionisation mass spectrometry was employed using m/z 58 (daughter ion of the
Chlormequat quaternary ammonium ion, m/z 122) and m/z 61 (daughter ion of the 13C-Chlormequat quaternary ammonium ion, m/z 125) for quantification. The LC analysis time was 15 min and the limit of detection
of the analytical method was 9 μg/kg. The performance of the method was demonstrated analysing grain material from an inter-comparison
study. In Denmark the primary use of Chlormequat chloride (CCC, cycocel, or chlorocholin chloride, CAS no. 999-81-5) is for
winter cereals and 11 such winter wheat samples from the Danish National Pesticide Survey were analysed. Residue contents
were from below 0.01 up to 0.45 mg/kg, and thus below the EU maximum residue level of 2.0 mg/kg for wheat.
Received: 22 December 1997 / Revised: 29 January 1998 / Accepted: 31 January 1998 相似文献
Summary A method for determination of the trichothecene toxins, deoxynivalenol, 3α-acetyl-deoxynivalenol, nivalenol, T-2 toxin, HT-2
toxin and diacetoxyscirpenol in cereals (wheat, barley, oats, corn) is described. Extraction was performed according to Tanaka
et al. (J. Chromatogr.328, 271 (1985)) [33], derivatization by trifluoroacylation with trifluoroacetic acid anhydride. For quantitation and confirmation
a capillary gas chromatograph combined with a selective mass detector (ion trap) working in CI-mode with methanol as reagent
gas was used. The quantitation limit for the complete method is 1–5 μg/kg, depending on the chemical characteristics of each
toxin and cleanness of the extracts. Recoverics from spiked cereals were 78–89%. 相似文献
A new method has been developed for the mass spectrometric determination of phenylalkylamines based on surface-assisted laser
desorption/ionization (SALDI). Films of amorphous α-Si, obtained by radiofrequency sputtering have been tested as ion emitters.
The high efficiency of the ionization method combined with gas chromatography and the time-of-flight mass spectrometry has
been demonstrated. The main analytical parameters have been determined for 12 phenylalkylamines. The detection limit for the
studied compounds has been found to vary in the range 5–150 pg/mL. 相似文献
This work presents the validation study of the comprehensive two-dimensional gas chromatography (GC×GC)–time-of-flight mass
spectrometry method performance in the analysis of the key World Anti-Doping Agency (WADA) anabolic agents in doping control.
The relative abundance ratio, retention time, identification and other method performance criteria have been tested in the
GC×GC format to confirm that they comply with those set by WADA. Furthermore, tens of other components were identified with
an average similarity of >920 (on the 0–999 scale), including 10 other endogenous sterols, and full mass spectra of 5,000+
compounds were retained. The testosterone/epitestosterone ratio was obtained from the same run. A new dimension in doping
analysis has been implemented by addressing separation improvement. Instead of increasing the method sensitivity, which is
accompanied by making the detector increasingly “blind” to the matrix (as represented by selected ion monitoring mode, high-resolution
mass spectrometry (MS) and tandem MS), the method capabilities have been improved by adding a new “separation” dimension while
retaining full mass spectral scan information. Apart from the requirement for the mass spectral domain that a minimum of three
diagnostic ions with relative abundance of 5% or higher in the MS spectra, all other WADA criteria are satisfied by GC×GC
operation. The minimum of three diagnostic ions arises from the need to add some degree of specificity to the acquired mass
spectrometry data; however, under the proposed full MS scan method, the high MS similarity to the reference compounds offers
more than the required three diagnostic ions for an unambiguous identification. This should be viewed as an extension of the
present criteria to a full-scan MS method. 相似文献
The investigation and analysis of polymer thin films with Bin+, n = 1–7 cluster ions has been demonstrated by means of static secondary ion mass spectrometry (SIMS). The highly specific signal
enhancement of these primary ions combined with the individual fragmentation pattern of poly(4-vinylphenol) and poly(methyl
methacrylate) is the basic principle for a modified approach of data reduction derived from the well-established g-SIMS procedure.
Based on mass spectra, which correspond to different cluster ion sizes, not only a clear distinction between the two polymers
is feasible but also a further simplification of the data can be demonstrated. It has been successfully proven that characteristic
polymer-relevant species can be refined out of the large amount of unspecific and highly fragmented secondary ions, which
are usually present in SIMS spectra. Therefore, a more precise and direct interpretation of complex organic fragments becomes
feasible, which consequently enables the investigation of even more sophisticated samples. 相似文献
