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1. Experimental Evaluation of Higher Order Stability Zones Using a Digitally Operated Quadrupole Mass Filter

   https://doi.org/10.1021/jasms.4c00110  

   Chakravorty, Sumeet; Groetsema, Elizabeth; Obe, Fatima Olayemi; Huntley, Adam P; Anderson, Gordon A; Clowers, Brian H; Reilly, Peter_T A (July 2024, Journal of the American Society for Mass Spectrometry)

   Recent improvements to the comparison-based method of digital waveform generation increased the reproducibility of the waveforms so that the higher-order Mathieu stability zones can be accessed reliably. Digitally driven quadrupole mass filters access these zones using a fixed AC voltage and rectangular waveforms that are defined by a duty cycle. In this context, the duty cycle is the fraction of the waveform period where the waveform remains in the high state. Because digitally driven quadrupoles navigate stability using a duty cycle, there is no need to apply a resolving DC offset between electrode pairs. Accessing the higher stability zones using a conventional resonantly-tuned RF requires the use of thousands of AC and DC voltages making the mode of operation less accessible with these devices. Stability zones higher than (1,1) and (2,1) have theoretical resolving powers that are on the order 1,140 and 3,447 at FWHM which drives efforts to practically access these operational conditions. Accessing these zones digitally requires the use of extremely precise waveforms. In a previous effort, waveform generation produced waveforms to reliably access the (1,1) and (2,1) zones without impacting performance. However, recent work found more improvement was needed to reliably access neighboring higher stability zones. Derived from that work, it was determined that a waveform resolution of ~10 ppm or less was needed to reliably access the (3,1) and (3,2) zones. The present work utilized digital waveforms that achieve this level of precision to experimentally access and characterize attributes of the (3,1) and (3,2) zones. This work dives into the investigation of different beam energies to overcome the destabilizing fringing fields, improve transmission, and their overall effect on the experimental resolving power and signal-to-noise. In addition, the AC voltage of the driving RF was varied to understand the effects on the initial ion beam energy that is needed to achieve balanced separation and how the overall signal-to-noise is affected. Lastly, an assessment was made on the effects of the temporal parameters of a digital mass scan on peak sensitivity, peak fidelity, and overall duration for a scan. 

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2. Control system for an underwater coded aperture miniature mass spectrometer

   https://doi.org/10.1016/j.greeac.2025.100241  

   Serpa, Rafael Bento; Keogh, Justin A; Jablonski, Thomas; Parker, Charles B; Goetz, Stefan M; Denton, MBonner; Hemond, Harold F; Glass, Jeffrey T; Cassar, Nicolas; Amsden, Jason J (June 2025, Green Analytical Chemistry)

   In situ measurements of the spatiotemporal distribution of dissolved gases in the ocean are useful for a wide variety of applications including monitoring biogeochemical cycles (e.g., methane, oxygen, and carbon dioxide fluxes), detecting pollutants, studying submarine groundwater discharge, and tracking chemical gradients in water columns or sediment interfaces. Over the past two decades, underwater membrane inlet mass spectrometry has emerged as a leading technology for in situ dissolved gas analysis, leveraging various mass analyzers such as quadrupole, ion trap, and cycloidal systems. While quadrupoles and ion traps face challenges such as water vapor interference and resolution limitations, cycloidal analyzers offer higher resolution at low mass-to-charge ratios with reduced power requirements. However, they have historically suffered from sensitivity and sequential analysis limitations. Recent advances, including ion array detectors and computational sensing, now enable simultaneous mass detection and improved sensitivity in cycloidal mass analyzers. This study introduces the development of an underwater coded aperture miniature mass spectrometer (UW-CAMMS), incorporating a cycloidal mass analyzer, ion array detector, and spatially coded apertures. A low-power electronic control system for the UW-CAMMS is designed and characterized, with performance comparable to laboratory-based systems, showcasing progress toward efficient, compact underwater dissolved gas monitoring. This technology can be used to study dynamic processes in marine, freshwater, and brackish systems with high spatial and temporal resolution. 

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3. Broadband ion mobility deconvolution for rapid analysis of complex mixtures

   https://doi.org/10.1039/C8AN00193F  

   Pettit, Michael E.; Brantley, Matthew R.; Donnarumma, Fabrizio; Murray, Kermit K.; Solouki, Touradj (January 2018, The Analyst)

   High resolving power ion mobility (IM) allows for accurate characterization of complex mixtures in high-throughput IM mass spectrometry (IM-MS) experiments. We previously demonstrated that pure component IM-MS data can be extracted from IM unresolved post-IM/collision-induced dissociation (CID) MS data using automated ion mobility deconvolution (AIMD) software [Matthew Brantley, Behrooz Zekavat, Brett Harper, Rachel Mason, and Touradj Solouki, J. Am. Soc. Mass Spectrom. , 2014, 25 , 1810–1819]. In our previous reports, we utilized a quadrupole ion filter for m / z -isolation of IM unresolved monoisotopic species prior to post-IM/CID MS. Here, we utilize a broadband IM-MS deconvolution strategy to remove the m / z -isolation requirement for successful deconvolution of IM unresolved peaks. Broadband data collection has throughput and multiplexing advantages; hence, elimination of the ion isolation step reduces experimental run times and thus expands the applicability of AIMD to high-throughput bottom-up proteomics. We demonstrate broadband IM-MS deconvolution of two separate and unrelated pairs of IM unresolved isomers ( viz. , a pair of isomeric hexapeptides and a pair of isomeric trisaccharides) in a simulated complex mixture. Moreover, we show that broadband IM-MS deconvolution improves high-throughput bottom-up characterization of a proteolytic digest of rat brain tissue. To our knowledge, this manuscript is the first to report successful deconvolution of pure component IM and MS data from an IM-assisted data-independent analysis (DIA) or HDMS E dataset. 

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4. Mass Spectrometry Imaging of Diclofenac and Its Metabolites in Tissues Using Nanospray Desorption Electrospray Ionization

   https://doi.org/10.26434/chemrxiv.13194422  

   Brown, H.; Mesa Sanchez, D.; Yin, R.; Chen, B.; Vavrek, M.; Cancilla, M.; Zhong, W.; Shyong, B.; Zhang, R.; Li, F.; et al (May 2020, ChemRxiv)

   null (Ed.)

   Glucuronidation is a common phase II metabolic process for drugs and xenobiotics which increases their solubility for excretion. Acyl glucuronides (glucuronides of carboxylic acids) present concerns of toxicity as they have been implicated in gastrointestinal toxicity and hepatic failure. Despite the substantial success in the bulk analysis of these species, little is known about their localization in tissues. Herein, we used nanospray desorption electrospray ionization mass spectrometry imaging (nano-DESI-MSI) to examine the localization of diclofenac, a widely used nonsteroidal anti-inflammatory drug, and its metabolites in mouse kidney and liver tissues. Nano-DESI allows for label-free imaging with high spatial resolution and sensitivity without special sample pretreatment. Using nano-DESI-MSI, ion images for diclofenac and its major metabolites were produced. MSI data acquired over a broad m/z range showed fairly low signals of the drug and its metabolites. At least an order of magnitude improvement in the signals was obtained using selected ion monitoring (SIM), with m/z windows centered around the low-abundance ions of interest. Using nano-DESI MSI in SIM mode, we observed that diclofenac acyl glucuronide is localized to the inner medulla and hydroxydiclofenac to the cortex of the kidney. The distributions observed for both metabolites closely match the previously reported localization of enzymes that process diclofenac into its respective metabolites. The localization of diclofenac acyl glucuronide to medulla likely indicates that the toxic metabolite is being excreted from the tissue. In contrast, a uniform distribution of diclofenac, hydroxydiclofenac and the diclofenac acyl glucuronide metabolite was observed in the liver tissue. Semiquantitative analysis found the metabolite to diclofenac ratios calculated from nano-DESI in agreement to those calculated from liquid chromatography tandem mass spectrometry (LC-MS/MS) experiments. Collectively, our results demonstrate nano-DESI-MSI can be successfully used to image diclofenac and its primary metabolites in dosed liver and kidney tissues from mice and derive semi-quantitative data from localized tissue regions. 

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5. Deep profiling of plant stress biomarkers following bacterial pathogen infection with protein corona based nano-omics

   https://doi.org/10.1101/2024.12.12.627884  

   Coreas, Roxana; Sridhar, Nikitha; Lin, Teng-Jui; Squire, Henry J; Voke, Elizabeth; Landry, Markita P (December 2024, bioRxiv)

   Abstract Detection and remediation of stress in crops is vital to ensure agricultural productivity. Conventional forms of assessing stress in plants are limited by feasibility, delayed phenotypic responses, inadequate specificity, and lack of sensitivity during initial phases of stress. While mass spectrometry is remarkably precise and achieves high-resolution, complex samples, such as plant tissues, require time-consuming and biased depletion strategies to effectively identify low-abundant stress biomarkers. Here, we bypassed these reduction methods via a nano-omics approach, where gold nanoparticles were used to enrich time- and temperature-dependent stress-related proteins through biomolecular corona formation that were subsequently analyzed by ultra-high performance liquid chromatography tandem mass spectrometry (UHPLC-MS/MS). This nano-omic approach was more effective than a conventional proteomic analysis using UHPLC- MS/MS for resolving biotic-stress induced responses at early stages of pathogen infection inArabidopsis thaliana, well before the development of visible phenotypic symptoms, as well as in distal tissues of pathogen infected plants at early timepoints. The enhanced sensitivity of this nano-omic approach enables the identification of stress-related proteins at early critical timepoints, providing a more nuanced understanding of plant-pathogen interactions that can be leveraged for the development of early intervention strategies for sustainable agriculture. 

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