Effect of oleoresin capsicum (OC) and ortho-chlorobenzylidene malononitrile (CS) on ciliary beat frequency.

Tear gases are largely used to control civil unrest. Their incapacitating effects involve the eyes, skin, and respiratory tract. We aimed to evaluate the effects of ortho-chlorobenzylidene malononitrile (CS) and oleoresin capsicum (OC) on ciliary beat frequency (CBF) of mouse tracheal rings. Addition of 0.05% OC or 0.01% CS induced a progressive decrease in CBF, from 11.5+/-0.5 to 4+/-0.1 Hz (P<0.05) and from 12.5+/-0.5 to 2.5+/-0.1 Hz (P<0.05), respectively, 30 min after exposure to the tear gas. Addition of exogenous ATP inhibited the effect of OC, suggesting that ATP could be used to counteract these adverse effects on CBF. However, ATP was inefficient against CS. Methylene blue and H7 inhibited the effects of OC, whereas indomethacin had no effect. None of these drugs affected the inhibitory action of CS. These results suggest that the inhibitory effect of OC is mediated through the guanylate cyclase-dependent pathway or protein kinase C-dependent phosphorylation. Another mechanism is probably involved in CS-induced inhibitory effect. Histological analysis of the trachea revealed an increase in mucus secretion after exposure to OC, and cytoplasmic vacuoles in epithelial cells after exposure to CS.

High-pressure ion source combined with an in-axis ion trap mass spectrometer. 1. Instrumentation and applications

A new combination of a dual EI/CI ion source with a quadrupole ion trap mass spectrometer has been realized in order to efficiently produce negative ions in the reaction cell. Analysis of volatile compounds was performed under negative ion chemical ionization (NICI) during a reaction period where selected reactant negative ions, previously produced in the external ion source, were allowed to interact with molecules, introduced by hyphenated techniques such as gas chromatography. The O2*-, CH3O-, and Cl- reactant ions were used in this study to ensure specific ion/molecule interactions such as proton transfer, nucleophilic displacement, or charge exchange processes, respectively leading to even-electron species, i.e., deprotonated [M - H]- molecules, diagnostic [M - R]- ions, or odd-electron M*- molecular species. The reaction orientation depends on the thermochemistry of reactions within kinetic controls. First analytical results are presented here for the trace-level detection of several contaminants under NICI/Cl- conditions. Phosphorus-containing compounds (malathion, ethyl parathion, and methyl parathion as representative for pesticides) and nitro-containing compounds (2,4,6-trinitrotoluene for explosive material) have been chosen in order to explore the analytical ability of this promising instrumental coupling.

High-pressure ion source combined with an in-axis ion trap mass spectrometer. 2. Application of selective low-pressure negative ion chemical ionization

Negative ion chemical ionization was carried out using a quadrupole ion trap mass spectrometer with selected reactant negative ions, primarily injected from a homemade dual EI/CI external ion source. Hence, selective ion/molecule reactions were provided according to the reaction time, which induce a greater control over bimolecular ionization mechanisms than in conventional a high-pressure ion source combined with beam instruments, where several competitive ionization processes take place mainly due to source conditions (e.g., temperature, pressure, and repeller). By selecting the reactant ions, ion/molecule reactions were specifically produced (i.e., charge exchange, proton transfer, nucleophilic substitution, and/or alpha-beta elimination) with several organic target compounds. Gas-phase reactivity of phosphorus- and nitrogen-containing compounds (such as phosphonates as representative for chemical warfare agents and phosphorothionates, phosphorodithionates, and triazines for pesticides) as well as dinitro aromatic compounds (for pesticides) has been explored, in the present work, to ensure further unambiguous detection.

Comparative acute toxicity of o-chlorobenzylidene malononitrile (CS) and oleoresin capsicum (OC) in awake rats.

Tear gases are largely used to control civil unrest. Their incapaciting effects involve eyes, skin and respiratory tract. This study was performed to compare acute respiratory effects of o-chlorobenzylidene malononitrile (CS), oleoresin capsicum (OC) and their respective solvents in awake rats, using an integrated system of nose-only exposure and multiple monitoring of breathing. Aerosols were generated by a Collison Nebulizer from the solutions held in tear gas sprays. The reduction of minute ventilation, observed during a 5 min exposure, was significantly more important with CS than with OC: minute ventilation represented 29+/-8 and 50+/-6% of pre-exposure minute ventilation respectively (P<0.05). The reduction of minute ventilation observed with CS and OC solvents alone was not significantly different from that observed with the tear gases themselves. The decrease in minute ventilation observed, between the second and the fifth minute of exposure, was of the same level for repeated exposure separated by 24 h. Time necessary to recover to 80% of pre-exposure minute ventilation was not significantly different between the two tear gases: 722+/-272 and 691+/-262 s for CS and OC respectively (NS). Histological analysis of the trachea, performed at the end of exposures, revealed an increase in mucus secretion after exposure to OC and cytoplasmic vacuoles in epithelial cells after exposure to CS. In the lungs, interstitial oedema was observed after exposure to OC and emphysema after exposure to CS.