Pulsed Nano-ESI Atmospheric-Pressure Ion Mobility Mass Spectrometry with Enhanced Ion Sampling.

Ion mobility-mass spectrometry (IM-MS) has gained considerable attention for detection of clusters and weakly bound species created by electrospray ionization (ESI). Atmospheric-pressure (AP) IM-MS offers an advantage in these studies compared to its low-pressure counterpart, owing to soft introduction of ions into the mobility cell with minimal ion activation. Here, we report new approaches to improve the sensitivity and soft ion introduction in AP-IM-MS. For the former, we demonstrate enhanced aerodynamic sampling of ions from the mobility cell into the MS using pulsed-field sampling. In this approach, ions are driven toward the MS, and the field is shut down once the ions reach the vicinity of the MS inlet orifice. The pulsed-field operation provides arrival times without the need for an exit ion gate in the mobility cell and leads to improvements in sensitivity of up to 1 order of magnitude. For soft ion generation, we report a pulsed nano-ESI source to introduce a packet of ions into the room-temperature mobility cell without induced desolvation. Further, we demonstrate the application of the pulsed nano-ESI AP-IM-MS with enhanced ion sampling for detection of solvent clusters of amines and peptide aggregates.

High-sensitivity elemental ionization for quantitative detection of halogenated compounds.

The rising importance of organohalogens in environmental, pharmaceutical, and biological applications has drawn attention to analysis of these compounds in recent years. Elemental mass spectrometry (MS) is particularly advantageous in this regard because of its ability to quantify without compound-specific standards. However, low sensitivity of conventional elemental MS for halogens has hampered applications of this powerful method in organohalogen analyses. To this end, we have developed a high-sensitivity elemental ion source compatible with widely available atmospheric-sampling mass spectrometers. We utilize a helium-oxygen plasma for atomization followed by negative ion formation in plasma afterglow, a configuration termed as plasma-assisted reaction chemical ionization (PARCI). The effect of oxygen on in-plasma and afterglow reactions is investigated, leading to fundamental understanding of ion generation processes as well as optimized operating conditions. Coupled to a gas chromatograph, PARCI shows constant ionization efficiency for F, Cl, and Br regardless of the chemical structure of the compounds. Negative ionization in the afterglow improves halide ion formation efficiency and eliminates isobaric interferences, offering sub-picogram elemental detection for F, Cl, and Br using low-resolution MS. Notably, the detection limit for F is about one order of magnitude better than other elemental MS techniques. The high sensitivity and facile adoptability of PARCI pave the way for combined elemental-molecular characterization, a comprehensive analytical scheme for rapid identification and quantification of organohalogens.

Reagent delivery by partial coalescence and noncoalescence of aqueous microdroplets in oil.

Reagent delivery constitutes a key step for reaction initiation in droplet-in-oil microfluidic platforms. Currently, this function is performed by complete fusion of a reagent droplet with the reactor droplet. The full coalescence, however, constrains the lower limit of volume delivery because reproducible droplet generation becomes exceedingly difficult as the reagent droplet volume is decreased. Here, we demonstrate fractional volume delivery based on partially coalescent and noncoalescent droplet collisions as a new reagent delivery mechanism. A charged reagent droplet is generated by pulsing a flow carrying needle to high voltage. The charged droplet is directed toward a grounded reactor droplet. Upon collision, the reagent droplet inverts its charge and is pulled away from the reactor droplet prior to full fusion, injecting only a fraction of its volume. The undelivered portion of the reagent drop is then merged with a collector droplet. We demonstrate that a wide range of fractional injections (0.003%-56%) can be reproducibly achieved, providing a means for minute volume delivery without small drop generation.

Naphthenic acids as indicators of crude oil biodegradation in soil, based on semi-quantitative electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry.

Crude oil contaminated soil cores were collected from a basin that contained oily solids left from three decades of oil production. Hydrocarbon biomarker analyses revealed that the soil extracts were moderately biodegraded compared with the non-degraded source oil. The degree of biodegradation also decreased with core depth (7 cm to 1 m). These data were correlated to compositional changes observed in acidic NSO-compounds that were selectively ionized and mass resolved by negative ion electrospray Fourier transform ion cyclotron resonance mass spectrometry (ESI FT-ICR MS). Among the NSO-compounds ionized, the increase in naphthenic acid concentration (e.g., acyclic and alicyclic carboxylic acids) best correlated with the increase in biodegradation (e.g., from non-degraded to moderately degraded) as determined by the hydrocarbon biomarker analyses. The most biodegraded surface extracts (7 cm) exhibited an 80% increase in the abundance of acids relative to the source oil. Use of an internal standard allowed the semi-quantitative determination of the total naphthenic acid concentration, which decreased significantly (P < 0.05) with soil depth. Furthermore, the shift to higher double bond equivalents (DBEs), from acyclic to alicyclic acids, indicated that the increase in acids in the soil extracts was predominantly due to biotic processes. This work demonstrates the potential of ESI FT-ICR MS as a semi-quantitative tool to monitor the production of naphthenic acids during crude oil biotransformation in the environment.

Capillary liquid chromatography-mass spectrometry for the rapid identification and quantification of almond flavonoids.

A rapid negative ion ESI high-performance capillary liquid chromatography-mass spectrometry method was developed to identify and quantify flavonoids (e.g., flavanols, flavonols, flavanones and glycosides). Fifteen standards and two varieties of almond skin extract powder (Carmel and Nonpareil) were used to demonstrate the chromatographic separation, reproducibility and accuracy of the method that employed a 150 mm x 0.3 mm ChromXP 3C18-EP-120 column. All standards eluted in less than 10 min, providing a 9-12x reduction in analysis time compared to existing methods (90-120 min). However, isomers (e.g., catechin/epicatechin and galactosides/glucosides) were not resolved and, therefore, identified and quantified collectively. RSDs for retention time and peak area reproducibility (mass spectrometry data) were <0.5% and <5.0%, respectively. Peak area reproducibility was greatly improved (from a RSD>10%) after the implementation of a low-flow metal needle in the ESI source. Quantitation by mass spectrometry also afforded a % error less than 5% for most compounds.