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1.
Anal Biochem ; 676: 115249, 2023 09 01.
Artigo em Inglês | MEDLINE | ID: mdl-37454965

RESUMO

Recently, we have developed heat pulse desorption/mass spectrometry (HPD/MS). In HPD/MS, a heated N2 gas pulse was directed to the sample surface and desorbed analytes were mass analyzed by corona discharge ionization/mass spectrometry using an Orbitrap mass spectrometer. In this work, HPD/MS was applied to the analysis of skin surface components sampled from the forehead, nose, and jaw of three volunteers. It was found that various kinds of biological compounds such as squalene, free fatty acids, wax esters, triacylglycerols, and amino acids were detected. The simultaneous detection of compounds with a wide range of proton affinities suggests that the occurrence of consecutive proton transfer reactions is less likely to occur in the present experimental system. This is mainly due to the short distance of 1.5 mm between the tip of the corona needle and the inlet of the mass spectrometer (i.e., proximity corona discharge ion source). Under this condition, the transition time of the primary reactant ions (e.g., H3O+) from the tip of the corona discharge needle to the ion sampling orifice is roughly estimated to be ∼20 µs. This value nearly corresponds to the reaction lifetime of exoergic proton transfer reactions with a rate constant: ∼10-9 cm3 s-1 for the analytes of 1 ppm. Accordingly, analytes with concentrations less than 1 ppm would be ionized semi-quantitatively by the present method, making this method highly suitable for the rapid analysis of samples composed of complex mixture of compounds, e.g., non-target lipidomics.


Assuntos
Temperatura Alta , Prótons , Animais , Humanos , Sebo , Espectrometria de Massas/métodos , Carne , Íons
2.
J Am Soc Mass Spectrom ; 33(11): 2046-2054, 2022 Nov 02.
Artigo em Inglês | MEDLINE | ID: mdl-36227061

RESUMO

For the thermal desorption of low-volatility compounds, rapid heating followed by instant cooling is desirable to suppress thermal decomposition. In this work, a new thermal desorption method, heat pulse desorption (HPD), was developed. A heated N2 gas pulse (350 °C, 50 ms) was directed to the solid sample surface, and desorbed analytes were ionized by DC corona discharge and mass analyzed by an Orbitrap mass spectrometer. Because heat transfer from the heated N2 gas to the solid surface is not very efficient, desorption of the solid sample occurs at a certain temperature before reaching 350 °C. In short, there is a self-controlling desorption depending on the volatility of each analyte. Because the exit of the copper tube for gas blowing is separated from the sample surface, no carryover occurs, enabling the repetitive analysis of samples. HPD was applied to various compounds such as narcotics, pharmaceutical tablets, and explosives. Because analysis is completed within a few seconds per sample, this method is highly useful for quick and consecutive analysis of real samples, having potential utility in food quality control, counterfeit drugs analysis, and the detection of explosives for safety and security.


Assuntos
Substâncias Explosivas , Temperatura Alta , Espectrometria de Massas , Temperatura Baixa , Calefação
3.
Mass Spectrom (Tokyo) ; 10(1): A0100, 2021.
Artigo em Inglês | MEDLINE | ID: mdl-34993049

RESUMO

CO3 -• and O2 -• are known to be strong oxidizing reagents in biological systems. CO3 -• in particular can cause serious damage to DNA and proteins by H• abstraction reactions. However, H• abstraction of CO3 -• in the gas phase has not yet been reported. In this work we report on gas-phase ion/molecule reactions of CO3 -• and O2 -• with various molecules. CO3 -• was generated by the corona discharge of an O2 reagent gas using a cylindrical tube ion source. O2 -• was generated by the application of a 15 kHz high frequency voltage to a sharp needle in ambient air at the threshold voltage for the appearance of an ion signal. In the reactions of CO3 -•, a decrease in signal intensities of CO3 -• accompanied by the simultaneous increase of that of HCO3 - was observed when organic compounds with H-C bond energies lower than ∼100 kcal mol-1 such as n-hexane, cyclohexane, methanol, ethanol, 1-propanol, 2-propanol, and toluene were introduced into the ion source. This clearly indicates the occurrence of H• abstraction. O2 -• abstracts H+ from acid molecules such as formic, acetic, trifluoroacetic, nitric and amino acids. Gas-phase CO3 -• may play a role as a strong oxidizing reagent as it does in the condensed phase. The major discharge product CO3 -• in addition to O2 -•, O3, and NO x • that are formed in ambient air may cause damage to biological systems.

4.
J Am Soc Mass Spectrom ; 28(11): 2393-2400, 2017 11.
Artigo em Inglês | MEDLINE | ID: mdl-28699062

RESUMO

A novel method for the simultaneous detection of ingredients in pharmaceutical applications such as creams and lotions was developed. An ultrasonic atomizer has been used to produce a mist containing ingredients. The analyte molecules in the mist can be ionized by using direct analysis in real time (DART) at lower temperature than traditionally used, and we thus solved the problem of normal DART-MS measurement using a high-temperature gas. Thereby, molecular-related ions of heat-unstable components and nonvolatile components became detectable. The deprotonated molecular ion of glycyrrhizic acid (m/z 821), which is unstable at high temperatures, was detected without pyrolysis by ultrasonic mist-DART-MS using unheated helium gas, although it was not detected by normal DART-MS using heated helium gas. The cationized molecular ions of derivatives of polyethylene glycol fatty acid monoesters, which are nonvolatile compounds, were also detected as m/z peaks observed from 800 to 2300. Although the protonated molecular ion of tocopherol acetate was not detected in ionization by ultrasonic mist, it was detected by ultrasonic mist-DART-MS even in the emulsion. It was not necessary to dissolve a sample completely to detect its ions. This method enabled us to obtain the composition of pharmaceutical applications simply and rapidly. Graphical Abstract ᅟ.

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