William M. Draper

The Photochemical Generation of Hydrogen Peroxide in Natural Waters

The photochemical formation of hydrogen peroxide in tryptophan solutions and natural waters was monitored by a sensitive spectrophotometric assay. Peroxide was characterized by ion exchange properties and mobility via thin-layer chromatography. Tryptophan photodecomposed in sunlight or near ultraviolet light (λ > 283 nm) with the formation of uncharacterized, acidic photoproducts and hydrogen peroxide; other oxidants (i.e. organic peroxides) were not detected in tryptophan photolysis mixtures. After brief exposure to sunlight, hydrogen peroxide in natural waters varied from below the detection limit (1.5μM) to 6.8μM; in highly eutrophic samples peroxide was formed in excess of 30μM. A humic acid soil extract, tyrosine, and several aromatic compounds including substituted phenols and anilines also generated stable photochemical oxidants suggesting that many compounds may serve as sources for hydrogen peroxide in natural waters.

Identification of Unknowns in Atmospheric Pressure Ionization Mass Spectrometry Using a Mass to Structure Search Engine

This study evaluates a new model for identifying unknown compounds in atmospheric pressure ionization mass spectrometry based on a mass-to-structure (MTS) paradigm. In this method, rudimentary ESI spectrum interpretation is required to recognize key spectral features such as MH (+), MNa (+), and MNH 4 (+), which lead to the unknowns monoisotopic mass. The unknowns mass is associated directly with known organic compounds using an Access 2003 database containing records of 19,438 substances assembled from common sources such as the Merck Index, pesticide and pharmaceutical compilations, and chemical catalogues. A user-defined mass tolerance (+/-0.001-0.5 Da) is set according to the instrument mass accuracyunit mass resolution data require a wide mass tolerance ( approximately 0.5 Da) while tolerances for accurate mass data can be as narrow as +/-0.001 Da. Candidate structures retrieved with the MTS Search Engine appear in a report window providing formulas, mass error, and Internet links. This paper provides examples of structure elucidation with 15 organic compounds based on ESI mass spectra from both unit mass resolution (e.g., quadrupole ion trap and triple-stage quadrupole) and accurate mass instruments (e.g., TOF and Q-TOF). Orthogonal information (e.g., isotope ratios and fragmentation data) is complementary and useful for ranking candidates and confirming assignments. The MTS Search Engine identifies unknowns quickly and efficiently, and supplements existing interpretation schemes for unknown identification.

Electrolyte-Induced Ionization Suppression and Microcystin Toxins: Ammonium Formate Suppresses Sodium Replacement Ions and Enhances Protiated and Ammoniated Ions for Improved Specificity in Quantitative LC-MS-MS

This study examines the effects of electrolytes on microcystin (MC) electrospray ionization (ESI) mass spectrometry and quantitative LC-MS-MS. Sodium replacement ions (SRI) are prominent in MC ESI spectra in protic solvents such as HPLC grade methanol. In a methanol-water-0.006% acetic acid (v/v) gradient, envelopes with up to 11 SRI were apparent in both the +1 and +2 charge states with structures [M + Na(x) - (x-1)H](+) and [M + Na(x) - (x-2)H](+2). The m/z 135 product ion, [Ø-CH(2)-CH=O-CH(3)](+), widely used in tandem LC-MS-MS determination of MC, is a low collision energy fragment of many doubly charged MC precursor ions (e.g., [M+Na+H](+2), [M+Na+NH(4)](+2), M+Na+H+CH(3)OH](+2), [M+2H](+2)). These phenomena impair congener-specific LC-MS-MS detection of MC and degrade quantitative accuracy and precision. Pulse addition experiments established that ammonium formate (AF) strongly suppresses SRI in both +1 and +2 charge states and enhances MH(+) and MNH(4)(+) adducts in neutral MC. Addition of the buffer either post-column or by incorporation in the mobile phase increases specificity for all of the MC which were determined as the MNH(4)(+) > MH(+) and MH(+) > [MH - 134](+) transitions for neutral MC (MCLA, MCLF, MCLW) and [M+2H](+2) > 135(+) and [M+2H](+2) > [M+2H - 135](+) transitions for arginine-containing MC (MCLR, MCYR, MCRR). These findings shed light on mechanisms of electrolyte-induced ionization suppression, and demonstrate beneficial use of a buffer electrolyte for improved specificity and analytical ruggedness in quantitative LC-MS-MS.