B. Varadarajan scite author profile

B. Varadarajan

4Publications

52Citation Statements Received

101Citation Statements Given

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104

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University Hospital of Bern, University of Bern, Dräger (Germany)

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The relative influence of phosphorylation and methylation on responsiveness of peptides to MALDI and ESI mass spectrometry

et al. 2009

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Qualitative and quantitative analysis of post-translational protein modifications by mass spectrometry is often hampered by changes in the ionization/detection efficiencies caused by amino acid modifications. This paper reports a comprehensive study of the influence of phosphorylation and methylation on the responsiveness of peptides to matrix-assisted laser desorption/ionization (MALDI) and electrospray ionization (ESI) mass spectrometry. Using well-characterized synthetic peptide mixtures consisting of modified peptides and their unmodified analogs, relative ionization/detection efficiencies of phosphorylated, monomethylated, and dimethylated peptides were determined. Our results clearly confirm that the ion yields are generally lower and the signal intensities are reduced with phosphopeptides than with their nonphosphorylated analogs and that this has to be taken into account in MALDI and ESI mass spectrometry. However, the average reduction of ion yield caused by phosphorylation is more pronounced with MALDI than with ESI. The unpredictable impact of phosphorylation does not depend on the hydrophobicity and net charge of the peptide, indicating that reliable quantification of phosphorylation by mass spectrometry requires the use of internal standards. In contrast to phosphorylation, mono- and dimethylated peptides frequently exhibit increased signal intensities in MALDI mass spectrometry (MALDI-MS). Despite minor matrix-dependent variability, MALDI methods are well suited for the sensitive detection of dimethylated arginine and lysine peptides. Mono- and dimethylation of the arginine guanidino group did not significantly influence the ionization efficiency of peptides in ESI-MS.

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Time course of ethanol and propofol exhalation after bolus injection using ion molecule reaction–mass spectrometry

Großherr

Varadarajan²,

Dibbelt

et al. 2010

Anal Bioanal Chem

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The transit of ethanol from blood to breath gas is well characterised. It is used for intraoperative monitoring and in forensic investigations. A further substance, which can be measured in breath gas, is the phenol propofol. After a simultaneous bolus injection, the signals (time course and amplitude) of ethanol and propofol in breath gas were detected by ion molecule reaction-mass spectrometry (IMR-MS) and compared. After approval by the regional authorities, eight pigs were endotracheally intubated after a propofol-free induction with etomidate. Boluses of ethanol (16 μg/kg) and propofol (4 or 2 mg/kg) were infused alone and in combination. For both substances, breath gas concentrations were continuously measured by IMR-MS; the delay time, time to peak and amplitude were determined and compared using non-parametric statistic tests. IMR-MS allows a simultaneous continuous measurement of both substances in breath gas. Ethanol appeared (median delay time, 12 vs 29.5 s) and reached its peak concentration (median time to peak, 45.5 vs 112 s) significantly earlier than propofol. Time courses of ethanol and propofol in breath gas can be simultaneously described with IMR-MS. Differing pharmacological and physicochemical properties of the two substances can explain the earlier appearance and time to peak of ethanol in breath gas compared with propofol.

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Near-real-time pulmonary shunt and dead space measurement with micropore membrane inlet mass spectrometry in pigs with induced pulmonary embolism or acute lung failure

Gerber

Vasireddy

Varadarajan

et al. 2019

J Clin Monit Comput

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The multiple inert gas elimination technique (MIGET) using gas chromatography (GC) is an established but time-consuming method of determining ventilation/perfusion (VA/Q) distributions. MIGET-when performed using Micropore Membrane Inlet Mass Spectrometry (MMIMS)-has been proven to correlate well with GC-MIGET and reduces analysis time substantially. We aimed at comparing shunt fractions and dead space derived from MMIMS-MIGET with Riley shunt and Bohr dead space, respectively. Thirty anesthetized pigs were randomly assigned to lavage or pulmonary embolism groups. Inert gas infusion (saline mixture of SF6, krypton, desflurane, enflurane, diethyl ether, acetone) was maintained, and after induction of lung damage, blood and breath samples were taken at 15-min intervals over 4 h. The samples were injected into the MMIMS, and resultant retention and excretion data were translated to VA/Q distributions. We compared MMIMS-derived shunt (MM-S) to Riley shunt, and MMIMS-derived dead space (MM-VD) to Bohr dead space in 349 data pairs. MM-S was on average lower than Riley shunt (− 0.05 ± 0.10), with lower and upper limits of agreement of − 0.15 and 0.04, respectively. MM-VD was on average lower than Bohr dead space (− 0.09 ± 0.14), with lower and upper limits of agreement of − 0.24 and 0.05. MM-S and MM-VD correlated and agreed well with Riley shunt and with Bohr dead space. MM-S increased significantly after lung injury only in the lavage group, whereas MM-VD increased significantly in both groups. This is the first work evaluating and demonstrating the feasibility of near real-time VA/Q distribution measurements with the MIGET and the MMIMS methods.

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Monitoring of Propofol Boli in Breathing Gas using Ion Molecule Reaction Mass Spectrometry

Varadarajan

Großherr

Meyer

et al. 2009

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B. Varadarajan

The relative influence of phosphorylation and methylation on responsiveness of peptides to MALDI and ESI mass spectrometry

Time course of ethanol and propofol exhalation after bolus injection using ion molecule reaction–mass spectrometry

Near-real-time pulmonary shunt and dead space measurement with micropore membrane inlet mass spectrometry in pigs with induced pulmonary embolism or acute lung failure

Monitoring of Propofol Boli in Breathing Gas using Ion Molecule Reaction Mass Spectrometry

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