Development and evaluation of a prototype ambient particle concentrator for inhalation exposure studies

Abstract

A number of studies have underlined the importance of the acute and chronic effects of ambient particles on respiratory health. Because fine particles are capable of penetrating deeply into the respiratory system, most of the health studies have focused on the res-pirable portion of the particle size spectrum. Previous studies to examine exposureJ response relationships between particle exposure and adverse respiratory effects have been based on artificial preparations, or collected and resuspended ambient particles, rather than the natural material found in ambient air. Artificial particles may not be representative, and collected particles may be difficult to redisperse. In addition, the chemical and physical characteristics of ambient particles may change upon resuspension. We have developed a new technique that enables us to increase the concentration of ambient particles to levels about 10 times higher (or more, if desirableJ than their ambient values and supply them to an exposure chamber. Ambient aerosol containing particles in the size range 0.1-2.5 Aim can be concentrated using a series of two slit-nozzle virtual impactors. The intake flow rates are 1 m3Jmin and 200 Umin in the first and second virtual impactors, respectively. The virtual impactors were characterized in terms of their cutpoints and interstage losses using artificial monodisperse fluorescent aerosols as well as indoor ambient aerosols. Since the concentrated particles are maintained airborne, they can be supplied to a human or animal exposure chamber for conduction of exposure studies. The supply flow rate in the prototype concentrator is 40 Umin. Higher flow rates can be achieved by using more than one such system in parallel. © 1995 Informa UK Ltd All rights reserved: reproduction in whole or part not permitted.