Mass Spectrometric Performance Research Articles

Inadequate Attempts to Measure the Microheterogeneity of Transthyretin by Low-Resolution Mass Spectrometry

Recently, the authors of 2 studies have claimed to measure accurately the microheterogeneity of transthyretin (TTR) variants by surface-enhanced laser desorption/ionization time-of-flight mass spectrometry (SELDI-TOF MS) immunoassays (1)(2). Here we report that the mass spectrometric performance in those studies was not adequate to measure the respective TTR variants. A mass resolution of at least 1000 is required to separate the majority of the currently known posttranslational and mutation-based modifications of TTR (3). Wang et al.(1) performed their analysis at a resolution of 270 [estimated as follows: m /Δ m FWHM = 13828/52 = 266 in Fig. 1A of their report (1)], whereas Schweigert et al. (2) achieved a resolution of 90 [estimated as follows: m /Δ m FWHM = 13851/158 = 88 in panel A2 of Fig. 2 of their report (2)]. We therefore question whether these studies can justify their reported claims. To provide arguments, we performed MALDI-TOF MS analysis on a gold chip ProteinChip® array of a commercially available TTR preparation with an instrument typically used in SELDI-TOF MS (PBS IIc analyzer; Ciphergen). We applied …

Detection of DNA Sequence Variations in Homo- and Heterozygous Samples via Molecular Mass Measurements by Electrospray Ionization Time-of-Flight Mass Spectrometry

The potential of ion-pair reversed-phase high-performance liquid chromatography on-line hyphenated to electrospray ionization time-of-flight mass spectrometry for the characterization of polymerase chain reaction (PCR) amplified nucleic acids was evaluated. For that purpose, a "SNP toolbox" was constructed by cloning and PCR-mediated site-directed in vitro mutagenesis at nucleotide position (ntp) 16,519 of a sequence-verified fragment of the human mitochondrial genome (ntps 15,900-599). Confirmatory sequencing demonstrated that within the sequences of the clones one and the same base was mutated to all other bases. Using these clones or equimolar mixtures of these clones as PCR templates, 51-401-bp-long amplicons were generated, which were used to determine the upper size limits of PCR products for the unequivocal detection of sequence variations in homo- and heterozygous samples. Based on the high mass spectrometric performance of the applied time-of-flight mass spectrometer, the unequivocal genotyping of all kinds of single base exchanges in PCR amplicons from heterozygous samples with lengths up to 254 base pairs (bp) was demonstrated. Considering homozygous samples, the successful genotyping of single base substitutions in up to 401-bp-long PCR products was possible. Consequently, the described hyphenated technique represents one of the most powerful mass spectrometric genotyping assays available today.

Characterization of synthetic nucleic acids by electrospray ionization quadrupole time‐of‐flight mass spectrometry

The potential of electrospray ionization quadrupole-quadrupole-time-of-flight mass spectrometry (ESI-QqTOF-MS) for the characterization of synthetic nucleic acids was evaluated. Oligonucleotides ranging in size from 12 up to 51 nucleotides were analyzed via direct infusion MS as well as via liquid chromatography (LC) online hyphenated to MS. These experiments proved the outstanding mass spectrometric performance of the TOF mass analyzer in regard of accuracy, reproducibility, resolution, and sensitivity. During a 1-min run, the monoisotopic mass of (dT)(24) was measured with a maximum relative mass deviation of 7.64 ppm proving the high mass accuracy of the TOF analyzer. Over a period of 1 h, mean deviations were determined in the range between -3.58 ppm and 3.06 ppm demonstrating the high stability of the applied external calibration. The molecular mass of a 51-mer was measured with a deviation smaller than 3.23 ppm from the theoretical value. The resolution exceeded a value of m/Deltam = 20 000 (m is the measured mass and Deltam the full peak width at half-maximum), which enabled the separation of the isotopic peaks of all investigated oligonucleotides. Because of the outstanding transmission and detection efficiency of the TOF mass analyzer, detection limits in the amol/microl to low fmol/microl range were reached. The usability of LC-ESI-QqTOF-MS for the qualitative and quantitative analysis of synthetic oligonucleotide mixtures was demonstrated.

Mass spectrometric and high performance liquid chromatography profiling of the venom of the Brazilian vermivorous mollusk Conus regius: feeding behavior and identification of one novel conotoxin

Carnivorous mollusks belonging to the genus Conus paralyze their prey by injecting a rich mixture of biologically active peptides. Conus regius is a vermivorous member of this genus that inhabits Brazilian tropical waters. Inter-, intra-species and individual variations of cone snail venom have been previously reported. In order to investigate intra-specific differences in C. regius venom, its feeding behavior and the correlation between these two factors, animals were pooled according to gender, size and season of collection, and their venom composition was compared by high performance liquid chromatography (HPLC). Both the whole venom and one specific peak were monitored by HPLC. Chromatographic profiles revealed no significant differences in their peak areas, indicating that the venom composition, based solely in the presence or absence of the major peaks, is stable regardless of season, gender and size. Therefore, analysis of one given toxin, eluting in one of the major peaks, is representative among the population. Moreover, this work presents the identification of one novel conotoxin (rg11a), which amino acid sequence was deduced by mass spectrometry.

Operational variables in high-performance liquid chromatography–electrospray ionization mass spectrometry of peptides and proteins using poly(styrene–divinylbenzene) monoliths

Capillary reversed-phase high-performance liquid chromatography (RP-HPLC) utilizing monolithic poly(styrene–divinylbenzene) columns was optimized for the coupling to electrospray ionization mass spectrometry (ESI-MS) by the application of various temperatures and mobile phase additives during peptide and protein analysis. Peak widths at half height improved significantly upon increasing the temperature and ranged from 2.0 to 5.4 s for peptide and protein separations at 70 °C. Selectivity of peptide elution was significantly modulated by temperature, whereas the effect on proteins was only minor. A comparison of 0.10% formic acid (FA), 0.050% trifluoroacetic acid (TFA), and 0.050% heptafluorobutyric acid (HFBA) as mobile phase additives revealed that highest chromatographic efficiency but poorest mass spectrometric detectabilities were achieved with HFBA. Clusters of HFBA, water, and acetonitrile were observed in the mass spectra at m/ z values >500. Although the signal-to-noise ratios for the individual peptides diverged considerably both in the selected ion chromatograms and extracted mass spectra, the average mass spectrometric detectabilities varied only by a factor of less than 1.7 measured with the different additives. Limits of detection for peptides with 500 nl sample volumes injected onto a 60 mm × 0.20 mm monolithic column were in the 0.2–13 fmol range. In the analysis of hydrophobic membrane proteins, HFBA enabled highest separation selectivity at the cost of lower mass spectral quality. The use of 0.050% TFA as mobile phase additive turned out to be the best compromise between chromatographic and mass spectrometric performance in the analysis of peptides and proteins by RP-HPLC–ESI-MS using monolithic separation columns.

The effect of N2O on the isotopic composition of air‐CO2 samples

The ionisation efficiencies of N2O vs. CO2 as well as their ratios were measured in detail introducing clean N2O and CO2 into the electron impact ion source of an isotope ratio mass spectrometer. Changes in the ionisation efficiency ratio (IER) were found for different electron energy settings and compared with the ratios of literature ionisation cross-section values for pure N2O and CO2. To establish the influence of mixtures of N2O and CO2 in a mass spectrometer, artificial air mixtures were prepared by mixing different amounts of N2O and CO2 from well-calibrated spike cylinders with CO2-free air. The mixing ratios varied from 8-512 ppb for N2O and from 328-744 ppm for CO2. With these mixtures the effects of varying N2O concentrations on apparent CO2 isotope ratios in air samples were determined. After applying a mass balance correction the delta13C results were consistent within small error margins. The data seemed almost independent from a particular choice for the IER of N2O vs. CO2 in the correction algorithm. For delta18O a small effect of the ionisation efficiency ratio of N2O vs. CO2 was found. Several sets of calculations were made varying the IER between 0.88 and 0.62. The dependence of delta18O was the smallest with an adopted IER of 0.68-0.72 in the mass balance correction equation for isotopic analysis of CO2 in air. For high-precision measurements of the CO2 stable isotope ratios in air samples a careful assessment of the mass spectrometer performance is necessary. Different ion sources, even different ion source settings, alter the IER of N2O vs. CO2 which is used in the N2O correction algorithm. Preferably, the specific mass spectrometric behaviour should be established with clean N2O/CO2 mixtures or with air mixtures covering a larger range of N2O concentrations.

Intercomparison study on accurate mass measurement of small molecules in mass spectrometry

The results from an intercomparison of accurate mass measurement of a small molecule (molecular weight 475 Da) across a broad range of mass spectrometers are reported. The intercomparison was designed to evaluate the relative capabilities and the optimum methodology of the diverse range of mass spectrometers currently used to record accurate mass measurements. The data will be used as a basis for developing guidance on accurate mass measurement. The need for guidance has resulted from the continued growth in the use of accurate mass measurements for assignment of elemental formula in the chemical and biochemical industries. This has been fuelled by a number of factors and includes the rapid pace of instrument development, which has enabled accurate mass measurements to be made in a less costly, yet robust fashion. The data from the intercomparison will allow us to compare those protocols that produced excellent accuracy and precision with those that produced poorer accuracy and/or precision for each type of mass spectrometer. The key points for best practice will then be established from this comparison for each type of mass spectrometer and accurate mass measurement technique. A compound was sent to the participating laboratories (in the UK, Europe, and USA), the identity of which was not revealed. Each laboratory was asked to record a minimum of five repeat mass measurements of the molecular species using their local protocols and their preferred ionization technique or techniques. To the best of our knowledge there were no interfering (unresolved) ions that originated from the sample. A questionnaire was also completed with the experimental work. The information from the questionnaires was used to evaluate the protocols used to record the measurements. Forty-five laboratories have reported their results. To summarize the performance of mass spectrometers in the intercomparison, magnetic sector field mass spectrometers used in peak matching mode and FTMS reported the highest mean mass measurement accuracy (88 and 83%, respectively, achieved ≤1 ppm). Magnetic sector field mass spectrometers used in voltage scanning produced 60% of the mean mass measurements with accuracy ≤1 ppm. Magnetic sector field mass spectrometers used in magnet scanning modes, quadrupole-TOF and TOF instruments generally achieved mean mass measurement accuracy between 5 and 10 ppm. The two low resolution triple quadrupoles used in the inter-comparison produced mean mass measurement accuracy of <2 ppm. The precision of the data from each instrument and experiment type is an important consideration when evaluating their relative capabilities. Using both the precision and accuracy, it will be possible to define the uncertainty associated with the elemental formulae derived from accurate mass measurements. Therefore, a thorough statistical evaluation of the data is underway and will be presented in a subsequent publication.

The role of the laser pulse duration in infrared matrix-assisted laser desorption/ionization mass spectrometry

The role of the laser pulse duration in matrix-assisted laser desorption/ionization mass spectrometry with infrared lasers (IR-MALDI-MS) emitting in the 3 μm wavelength range has been evaluated. Mass spectrometric performance and characteristics of the IR-MALDI process were examined by comparing a wavelength-tuneable mid-infrared optical parametric oscillator (OPO) laser of 6 ns pulse duration, tuned to wavelengths of 2.79 and 2.94 μm, with an Er:YAG laser (λ = 2.94 μm) with two pulse durations of 100 and 185 ns, and an Er:YSGG laser (λ = 2.79 μm) with a pulse duration of 75 ns. Threshold fluences for the desorption of cytochrome C ions were determined as a function of the laser pulse duration for various common IR-MALDI matrices. For the majority of these matrices a reduction in threshold fluence by a factor of 1.2–1.9 was found by going from the 75–100 ns long pulses of the Erbium lasers to the short 6 ns OPO pulse. Within the experimental accuracy threshold fluences were equal for the 100 and the 185 ns pulse duration of the Er:YAG laser. Some pronounced pulse duration effects related to the ion formation from a glycerol matrix were also observed. The effect of the laser pulse length on the duration of ion emission was furthermore investigated.

Short capillary ion‐pair high‐performance liquid chromatography coupled to electrospray (tandem) mass spectrometry for the simultaneous analysis of nucleoside mono‐, di‐ and triphosphates

A liquid chromatography/mass spectrometry (LC/MS) method for the analysis of complex mixtures of nucleoside mono-, di- and triphosphates has been developed. A short capillary column (35mm x 0.3mm i.d.) was operated under ion-pair high-performance liquid chromatography conditions and hyphenated to (negative) electrospray (tandem) mass spectrometry. As such, the separation of 12 nucleotides was performed by a binary gradient elution using CH(3)OH/H(2)O and N,N-dimethylhexylamine (N,N-DMHA) as ion-pairing agent. The influence of different N,N-DMHA concentrations on the chromatographic and mass spectrometric performance was evaluated to achieve optimal LC/MS conditions. In addition it was demonstrated that a controlled admission of ammonium dihydrogen phosphate (NH(4)H(2)PO(4)) improved both chromatographic performance and mass spectrometric detection. Because the system was hyphenated to an orthogonal designed electrospray interface (Z-spraytrade mark), long acquisition times were possible without loss of sensitivity.

Use of an adsorbed chiral selector in capillary LC-MS.

Lasalocid was utilized as a chiral selector adsorbed on porous graphitic carbon. Important parameters were identified for the use of the chiral selector in capillary liquid chromatography combined with MS detection. The influence on both retention and enantioselectivity as well as mass spectrometric performance was studied at lasalocid concentrations of up to 12 mg/l (20 microM). Moreover, the stability of retention factors and enantioselectivities was also evaluated at low selector concentration of 1 mg/l (2 microM). The results show that in order to optimize the MS performance the selector concentration should be kept at low microM. The chromatographic performance at reduced selector concentration (1 mg/l = 2 microM) was studied over a 10-day period, showing satisfactory enantioselectivity and stable performance concerning enantioselectivity and retention.

Biodegradation studies of 4-fluorobenzoic acid and 4-fluorocinnamic acid: an evaluation of membrane inlet mass spectrometry as an alternative to high performance liquid chromatography and ion chromatography

The biodegradation of 4-fluorobenzoic acid (4-FBA) and 4-fluorocinnamic acid (4-FCA) has been monitored by membrane inlet mass spectrometry (MIMS) using a hollow-fibre silicone membrane. A novel in-membrane pre-concentration/thermal desorption (IMP-MIMS) technique was employed for MIMS analysis using an oven temperature profile that allowed semi-volatile organic compounds to be accumulated in the membrane and then released by rapid heating. Air drying of the membrane between the analyte pre-concentration and thermal desorption stages improved mass spectrometric performance by removing residual water from the membrane. The concentrations of 4-FBA and 4-FCA determined by MIMS compare well with data obtained by high performance liquid chromatography (HPLC). Stoichiometric amounts of fluoride were monitored using ion chromatography (IC). Intermediates in the biodegradation pathway were identified by liquid chromatography/mass spectrometry (LC/MS). These data establish the potential of MIMS as an alternative to chromatographic methods for monitoring the biodegradation of semi-volatile organic compounds.

Tandem mass spectrometric accurate mass performance of time-of-flight and Fourier transform ion cyclotron resonance mass spectrometry: a case study with pyridine derivatives.

The interpretation of mass spectra is a key process during compound identification, and the combination of tandem mass spectrometry (MS/MS) with high-accuracy mass measurements may deliver crucial information on the identity of a compound. Obtaining accurate mass data of fragment ions in MS/MS reveals the particular problem of mass calibration when a lockmass, which is frequently used to obtain accurate masses in MS, is absent. An alternative technique is to recalibrate the MS/MS spectrum using a reference MS/MS spectrum acquired under the same conditions. We have tested and validated this approach using a hybrid quadrupole/orthogonal acceleration reflectron-type time-of-flight (TOF) mass spectrometer. The results were compared with those obtained under similar conditions on a Fourier transform ion cyclotron resonance (FT-ICR) instrument. We found that the mass accuracy observed with such an "external" recalibration on the TOF instrument in MS/MS is identical to what can be obtained on a similar instrument operating in one-dimensional MS mode using the lockmass technique. However, mass accuracy in both cases is one order of magnitude inferior to that obtained using FTMS, and also inferior to that observed using sector field MS when operated at comparable resolution. Nevertheless, for small (<200 Da) molecules, this mass accuracy was still sufficient to have the "true" elemental composition identified as the first hit in about 70% of all cases. It was possible to elucidate the fragmentation mechanism of eight azaheterocycles containing a pyridine moiety, where the accurate mass data from the TOF instrument allowed distinction between two alternative fragmentation pathways.

Effective potential and the ion axial beat motion near the boundary of the first stable region in a nonlinear ion trap

Small higher-order field imperfections of the main trapping quadrupole field are well known to have a strong influence on the performance of modern quadrupole mass spectrometers. Mass selectivity is usually achieved by means of the stability region boundaries. The stability diagram for ion motion is the area on the plane of voltage parameters for which the quadrupole field is able to trap ions of a given mass. Hence, the trapping efficiency of the quadrupole field is equal to zero at a boundary of the stability region. In this case, the trapping properties of the RF field depend on higher field imperfections regardless of how small they are compared to the quadrupole field. The ion motion with parameters close to the boundary β z = 1 is investigated in this article. The influence of nonlinear field imperfections is taken into account. A treatment similar to trajectory averaging in a pseudopotential is possible in this case. The ion motion has the characteristics of a beat with a fast oscillation at half the frequency of the RF and a slowly varying envelope. The ion motion is described by a dynamic equation for the envelope. This equation has the form of a Newton equation for the motion of a particle in a potential field. The effective potential function of the envelope is derived and investigated. The effective potential well is rather different for the cases of negative and positive even-order higher fields. The results are applied to the mass-selective axial instability scan of an ion trap. The influence of negative higher field harmonics explains the ejection delay and poor mass resolution of the Paul trap with truncated electrodes. Positive even-field imperfections are shown to be beneficial to the mass selective axial instability scan. This explains why stretched or hyperbolic angle modified traps give improved performance. Stable ion motion outside of the first stable region is predicted. This motion has the character of a limit cycle, and all ions move coherently in the radio frequency field.

An interlaboratory study to test instrument performance of hydrogen dual-inlet isotope-ratio mass spectrometers.

An interlaboratory comparison of forty isotope-ratio mass spectrometers of different ages from several vendors has been performed to test 2H/1H performance with hydrogen gases of three different isotopic compositions. The isotope-ratio results (unsufficiently corrected for H3+ contribution to the m/z = 3 collector, uncorrected for valve leakage in the change-over valves, etc.) expressed relative to one of these three gases covered a wide range of values: -630% to -790% for the second gas and -368% to -462% for the third gas. After normalizing the isotopic abundances of these test gases (linearly adjusting the delta values so that the gases with the lowest and highest 2H content were identical for all laboratories), the standard deviation of the 40 measurements of the intermediate gas was a remarkably low 0.85%. It is concluded that the use of scaling factors is mandatory for providing accurate internationally comparable isotope-abundance values. Linear scaling for the isotope-ratio scales of gaseous hydrogen mass spectrometers is completely adequate.

Experimental constraints on the stable-isotope systematics of CO 2 ice/vapor systems and relevance to the study of Mars

Variations in the isotopic compositions of oxygen, hydrogen, and carbon in the near-surface environment of Mars are likely influenced by condensation, evaporation, and sublimation of major volatile species (H 2O, CO 2). We present here an experimental study of the fractionations of 18O/ 16O and 13C/ 12C ratios between CO 2 ice and vapor at conditions relevant to the present near-surface of Mars; these experiments constrain isotopic variations generated by the current Martian CO 2 condensation/sublimation cycle. Oxygen-isotope fractionation between ice and vapor (Δ ice-vapor = 1000 · ln ([ 18O ice/ 16O ice] / [ 18O vapor/ 16O vapor]) varies approximately linearly vs. 1/T between temperatures of 150 and 130 K (from 4.2 and 7.5 ‰, respectively). Carbon isotopes are unfractionated (Δ 13C ice-vapor ≤ 0.2‰) at temperatures ≥ 135 K and only modestly fractionated (Δ 13C ice-vapor ≤ 0.4‰) at temperatures between 135 and 130 K. Martian atmospheric volumes that are residual to high extents of condensation (i.e., at high latitudes during the winter) may vary in δ 18O by up to tens of per mil, depending on the scales and mechanisms of ice/vapor interaction and atmospheric mixing. Precise (i.e., per mil level) examination of the Martian atmosphere or ices could be used as a tool for examining the Martian climate; at present such precision is only likely to be had from laboratory study of returned samples or substantial advances in the performance of mass spectrometers on landers and/or orbital spacecraft. Oxygen-isotope fractionations accompanying the CO 2 condensation/sublimation cycle may play a significant role in the oxygen-isotope geochemistry of secondary phases formed in SNC meteorites, in particular as a means of generating 18O-depleted volatile reservoirs.

Repetitive pulsed sampling interface for combined thermogravimetry/mass spectrometry

A pneumatic sampling switch which can be adapted to the outlet of a thermogravimetric analyzer furnace with a horizontal purge gas flow was developed. This system allows a repetitive introduction of short sampling pulses of thermogravimetric analyzer evolved gases to a quadrupole mass spectrometric detector. System performance was evaluated through measuring the level of repeatability under different operation conditions. In addition, pulsed sampling thermogravimetry/mass spectrometry introduced no measurable quantitative or qualitative errors. This system can be used for monitoring thermooxidative decomposition reactions, without accelerating the deterioration of quadrupole mass spectrometric detector performance. Furthermore, it can be used as an inlet system for a future on-line TG/GC/MS system.

Properties and performance of a quadrupole mass filter used for resonance ionization mass spectrometry

The performance of commercial quadrupole mass spectrometers (QMS) with a number of imperfections, as compared to the ideal hyperbolic geometry, has been characterized using the computer simulation program simion 3d version 6.0. The analysis of simulated QMS geometries focuses primarily on modeling of the internal potential, the study of field deviations, and the influence of finite length on performance of the QMS. The computer simulation of ion trajectories in the QMS field yields predictions for optimum working conditions and provides estimates for the resolving power and the maximum isotopic abundance sensitivity. Experimental measurements that confirm these expectations are presented. Optimization of the geometry and various operational parameters of the QMS is an important step in the development of a system for highly selective ultratrace determination using laser-based resonance ionization mass spectrometry.

Affinity methods for purification of DNA sequencing reaction products for mass spectrometric analysis.

Time-of-flight mass spectrometry has the potential to replace gel electrophoresis for rapid and accurate analysis of DNA sequencing mixtures. However, impurities in the Sanger sequencing reaction solutions can complicate and degrade the mass spectrometric performance. Therefore, a fast purification procedure is necessary for mass spectrometric analysis. Two affinity methods were tested for the capture of the target fragments: a probe strand, complementary to the primer used to initiate synthesis of the Sanger fragments, is immobilized to a solid support either before or after hybridization so that the impurities are readily separated by filtering and washing the support material. The approaches were tested using mock sequencing mixtures assembled from synthetic DNA strands, to which representative impurities could be added. The results showed that the latter method has better overall yield. The recovered fragments were analyzed by matrix-assisted laser desorption/ionization.

Ion‐Optical solutions in time‐of‐flight mass spectrometry

AbstractTime‐of‐flight mass spectrometers are able to cover mass ranges to around a half a million Da. The mass resolution of these instruments has been improved drastically by incorporation of electrostatic mirrors. The ion‐optical solutions enabling these achievements and other promising features are discussed in terms of: First‐ and second‐order space focusing in time for linear drift time‐of‐flight mass spectrometers; velocity focusing by time lag; ion‐packet bunching in post‐source impulse focusing; first‐ and second‐order energy focusing in time, in single‐ and double‐stage homogeneous electrostatic mirrors with normal and oblique ion incidence; gridless designs; perfect time focusing in parabolic potential and axial symmetry; cylindrical ion mirrors and toroidal electrostatic deflectors as time‐of‐flight mass analyzers; three electrostatic sector geometry applied in secondary ion microscopy and four toroidal sector systems for tandem mass spectrometry; poloidal electrostatic sectors. Estimation of time‐of‐flight mass spectrometer performance limits is discussed and the stable as well as the metastable peak shapes found in time‐of‐flight mass spectra.

Acquisition and processing of data for isotope-ratio-monitoring mass spectrometry

Methods are described for continuous monitoring of signals required for precise analyses of 13C, 18O, and 15N in gas streams containing varying quantities of CO 2 and N 2. The quantitative resolution (i.e. maximum performance in the absence of random errors) of these methods is adequate for determination of isotope ratios with an uncertainty of one part in 10 5; the precision actually obtained is often better than one part in 10 4. This report describes data-processing operations including definition of beginning and ending points of chromatographic peaks and quantitation of background levels, allowance for effects of chromatographic separation of isotopically substituted species, integration of signals related to specific masses, correction for effects of mass discrimination, recognition of drifts in mass spectrometer performance, and calculation of isotopic δ values. Characteristics of a system allowing off-line revision of parameters used in data reduction are described and an algorithm for identification of background levels in complex chromatograms is outlined. Effects of imperfect chromatographic resolution are demonstrated and discussed and an approach to deconvolution of signals from coeluting substances described.