Continuous vapor sampling of volatile organic compounds associated with explosives using capillary microextraction of volatiles (CMV) coupled to a portable GC-MS

The dynamic sampling and preconcentration device, capillary microextraction of volatiles (CMV), is coupled to a portable GC-MS for the rapid field detection of volatile organic compounds (VOCs) associated with explosives. The results of the portable GC-MS were compared to a benchtop GC-MS throughout this study. Sub-nanogram (ng) instrumental detection limits were achieved for each of the following analytes of interest (3-NT, 2,4-DNT, DPA, EC, DBP and 2-NDPA). Three different dynamic sampling methods were used with the CMV to sample and preconcentrate the volatiles prior to analysis. The headspace of a closed system was sampled over 10 min resulting in recoveries between 0.3 and 12%. Simulated open-air vapor sampling using a previously described vapor source resulted in an improvement of analyte recovery (ranging from 1.6 to 25%), for the same 10-minute sampling. A novel, continuous vapor delivery and sampling system was used, for the first time, to facilitate the delivery of sub-nanogram quantities of explosive analytes. The new continuous delivery system achieved significantly higher recoveries (3.0-89%) for all the analytes while requiring less sampling time (similar to 5 min) and sampling volumes than the other sampling techniques. The rapid sampling and preconcentration of sub-ng levels of VOCs in field scenarios was coupled to a similar to 10-minute portable GC-MS method that compares favorably to the analytical figures of merit achieved by laboratory benchtop instruments and approximates the detection limits reported for canines.

Automated summary

The study utilized a dynamic sampling and preconcentration device, CMV, coupled with a portable GC-MS for rapid detection of volatile organic compounds associated with explosives. Different sampling methods achieved sub-nanogram instrumental detection limits for various analytes of interest. A novel continuous vapor delivery system improved analyte recovery rates significantly in a shorter sampling time.