The rapid chemical analysis of individual cells is an analytical capability that will profoundly impact many fields including bioaerosol detection for biodefense and cellular diagnostics for clinical medicine. This article describes a mass spectrometry-based analytical technique for the real-time and reagentless characterization of individual airborne cells without sample preparation. We characterize the mass spectral signature of individual Bacillus spores and demonstrate the ability to distinguish two Bacillus spore species, B. thuringiensis and B.atrophaeus, from one another very accurately and from the other biological and nonbiological background materials tested with no false positives at a sensitivity of 92%. This example demonstrates that the chemical differences between these two Bacillus spore species are consistently and easily detected within single cells in seconds.
Bioaerosol mass spectrometry is being developed to analyze and identify biological aerosols in real time. Characteristic mass spectra from individual bacterial endospores of Bacillus subtilis var. niger were obtained in a bipolar aerosol time-of-flight mass spectrometer using a pulsed 266-nm laser for molecular desorption and ionization. Spectra from single spores collected at an average fluence of approximately 0.1 J/cm2 frequently contain prominent peaks attributed to arginine, dipicolinic acid, and glutamic acid, but the shot-to-shot (spore-to-spore) variability in the data may make it difficult to consistently distinguish closely related Bacillus species with an automated routine. Fortunately, a study of the laser power dependence of the mass spectra reveals clear trends and a finite number of "spectral types" that span most of the variability. This, we will show, indicates that a significant fraction of the variability must be attributed to fluence variations in the profile of the laser beam.
Single vegetative cells and spores of Bacillus atrophaeus, formerly Bacillus subtilis var. niger, were analyzed using bioaerosol mass spectrometry. Key biomarkers were identified from organisms grown in 13C and 15N isotopically enriched media. Spore spectra contain peaks from dicipolinate and amino acids. The results indicate that compounds observed in the spectra correspond to material from the spore's core and not the exosporium. Standard compounds and mixtures were analyzed for comparison. The biomarkers for vegetative cells were clearly different from those of the spores, consisting mainly of phosphate clusters and amino acid fragments.
We have fully characterized the mass spectral signatures of individual Bacillus atrophaeus spores obtained using matrix-free laser desorption/ionization bioaerosol mass spectrometry (BAMS). Mass spectra of spores grown in unlabeled, 13C-labeled, and 15N-labeled growth media were used to determine the number of carbon and nitrogen atoms associated with each mass peak observed in mass spectra from positive and negative ions. To determine the parent ion structure associated with fragment ion peaks, the fragmentation patterns of several chemical standards were independently determined. Our results confirm prior assignments of dipicolinic acid, amino acids, and calcium complex ions made in the spore mass spectra. The identities of several previously unidentified mass peaks, key to the recognition of Bacillus spores by BAMS, have also been revealed. Specifically, a set of fragment peaks in the negative polarity is shown to be consistent with the fragmentation pattern of purine nucleobase-containing compounds. The identity of m/z = +74, a marker peak that helps discriminate B. atrophaeus from Bacillus thuringiensis spores grown in rich media is [N1C4H12]+. A probable precursor molecule for the [N1C4H12]+ ion observed in spore spectra is trimethylglycine (+N(CH3)3CH2COOH), which produces a m/z = +74 peak when ionized in the presence of dipicolinic acid. A clear assignment of all the mass peaks in the spectra from bacterial spores, as presented in this work, establishes their relationship to the spore chemical composition and facilitates the evaluation of the robustness of "marker" peaks. This is especially relevant for peaks that have been used to discriminate Bacillus spore species, B. thuringiensis and B. atrophaeus, in our previous studies.
Bioaerosol mass spectrometry (BAMS) is being developed to analyze and identify biological aerosols in real-time. Mass spectra of individual Bacillus endospores were measured here with a bipolar aerosol time-of-flight mass spectrometer in which molecular desorption and ionization were produced using a single laser pulse from a Q-switched, frequency-quadrupled Nd:YAG laser that was modified to have an approximately flattop profile. The flattened laser profile allowed the minimum fluence required to desorb and ionize significant numbers of ions from single aerosol particles to be determined. For Bacillus spores this threshold had a mean value of approximately 1 nJ/µm 2 (0.1 J/cm 2 ). Thresholds for individual spores, however, could apparently deviate by 20% or more from the mean. Threshold distributions for clumps of MS2 bacteriophage and bovine serum albumin were subsequently determined. Finally, the flattened profile was observed to increase the reproducibility of single spore mass spectra. This is consistent with the general conclusions of our earlier paper on the fluence * E-mail: frank1@llnl.gov Telephone: 925-423-5068 Fax: 925-424-2778 2 dependence of single spore mass spectra and is particularly significant because it is expected to enable more robust differentiation and identification of single bioaerosol particles.
Bioaerosol mass spectrometry (BAMS) performs single-cell analysis in real time. However, the specificity of BAMS mass signatures has been limited by low sensitivity at high masses. To increase the mass range and sensitivity of BAMS, a novel design was developed that utilizes a linear flight tube with delayed extraction and an electrostatic ion guide. This study quantifies the sensitivity limits of the novel BAMS design and evaluates the feasibility of BAMS to detect higher mass biomarkers from single cells. All experiments were carried out using MALDI aerosol particles that were nebulized from solution. Sensitivity was assessed by generating particles with decreasing amounts of analyte via serial dilutions. The amount of analyte contained within each particle was calculated based on particle size, density, and molarity of the analyte within solution. A variety of biomolecular ions were studied and signals obtained from particles containing 300 zmol of maltopentaose, 132 zmol of alpha-cyclodextrin, and 14 zmol (approximately 8400 molecules) of gramicidin S are reported. The detection of 14 zmol of gramicidin S is to the best of our knowledge a record in sensitivity for MALDI TOF-MS.
Actual or surrogate chemical, biological, radiological, nuclear, and explosive materials and illicit drug precursors can be rapidly detected and identified when in aerosol form by a Single-Particle Aerosol Mass Spectrometry (SPAMS) system. This entails not only the sampling of such particles but also the physical analysis and subsequent data analysis leading to a highly reliable alarm state. SPAMS hardware is briefly reviewed. SPAMS software algorithms are discussed in greater detail. A laboratory experiment involving actual threat and surrogate releases mixed with ambient background aerosols demonstrates broad-spectrum detection within seconds. Data from a field test at the San Francisco International Airport demonstrate extended field operation with an ultralow false alarm rate. Together these data sets demonstrate a significant and important advance in rapid aerosol threat detection.Single-Particle Aerosol Mass Spectrometry (SPAMS) was initially developed at Lawrence Livermore National Laboratory to detect and identify biological aerosols.1,2 Since such aerosols are arguably among the most difficult to rapidly and accurately detect, this was a significant achievement. It also had immediate and important applications: biological warfare agents are potentially lethal in picogram quantities, 3,4 have been aerosolized for terrorist purposes, 5,6 and must be rapidly detected if medical treatment is to be maximally effective. Nonetheless, there are many other types of particles that are lethal or indicative of nefarious activity and far more frequently encountered. Chemical, biological, radiological, nuclear, and explosive (CBRNE) materials and illicit drugs or their precursors can all form airborne particles. Consequently, SPAMS is now being investigated as a potential means for their detection. SPAMS is even being explored as a means to analyze human respiratory effluent for various biomedical applications. 7,8 Such applications, however, present unique challenges and will not be discussed here. It should be noted that the technique was initially called Bio-Aerosol Mass Spectrometry (BAMS), but due to its growing range of applications a name change was requisite.In brief, SPAMS samples particles directly from the air and then reagentlessly and individually analyzes them. Correlated data on single-particle size, charge, and laser-induced fluorescence (LIF; measured for two excitation wavelengths independently) can be collected in addition to a full dual-polarity mass spectrum. Accurate single-particle identification is possible, and very accurate alarms can be triggered. Early SPAMS hardware evolved from ATOFMS instruments, 9 which were developed by the Prather group at U.C. Riverside and commercialized by TSI Inc., but the newest SPAMS systems are entirely distinct. Other varieties of aerosol mass spectrometer exist as well, 10,11 but few if any such instruments were specifically intended for rapid detection of lowconcentration aerosols in high-concentration backgrounds. The instrument of Wuijckhuijse et al....
Bioearosol mass spectrometry (BAMS) analyzes single particles in real time from ambient air, placing strict demands on instrument sensitivity. Modeling of the BAMS reflectron time of flight (TOF) with SIMION revealed design limitations associated with ion transmission and instrument sensitivity at higher masses. Design and implementation of a BAMS linear TOF with electrostatic ion guide and delayed extraction capabilities has greatly increased the sensitivity and mass range relative to the reflectron design. Initial experimental assessment of the new instrument design revealed improved sensitivity at high masses as illustrated when using standard particles of cytochrome C (m/z ϳ 12,000), from which the compound's monomer, dimer (m/z ϳ 24,000) and trimer (m/z ϳ 36,000) were readily detected. (J Am Soc Mass Spectrom 2005, 16, 1866 -1875
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.