Methods, apparatus, and systems for provision of an aerosol/vapor trap for elemental impurities emission analysis of high viscosity matrices used in non-burning vaporization devices are disclosed. In an embodiment, filter material filter material captures one or more elemental impurities from a non-burning vaporization device. A vessel contains the filter material. Other embodiments are also disclosed and claimed.

Methods, apparatus, and systems for provision of an aerosol/vapor trap for elemental impurities emission analysis of high viscosity matrices used in non-burning vaporization devices are disclosed. In an embodiment, filter material filter material captures one or more elemental impurities from a non-burning vaporization device. A vessel contains the filter material. Other embodiments are also disclosed and claimed.

A method of assembling and testing a simulated cigarette. Assembling the simulated cigarette to have an elongate main body containing a reservoir for an inhalable composition, a breath operated valve, and a refill valve. Testing the integrity of the reservoir requires applying a pressured gas to open the refill valve to pressurise the reservoir, measuring the pressure drop in the reservoir, and providing a pass indication if the pressure drop remains below a predetermined threshold. It also requires testing the breath operated valve by applying suction at an inhaling end, measuring the flow rate from the cigarette and providing a pass indication if the flow rate falls outside a predetermined limit.

A vapor/smoke capturing trap system featuring a smoke chamber trap for precipitating the smoke dispersed in the chamber. The chamber includes a bottom pool for containing a reservoir of a liquid solvent, and a gas filled portion in which a lower smog portion contains fog-sized droplets of the liquid solvent and into which the smoke is introduced, and an upper clear portion in which the concentration of the smoke and the droplets is decreased, respective of their concentration in the smog portion. A fog-condenser, disposed between the smog portion and the clear portion, precipitates the fog droplets of the smog portion into the pool. A fine mist generator streams a jet of fog-sized droplets of the liquid solvent mixed with smoke toward a concentration of the smoke at the smog portion. A closed loop gas circulator withdraws gas from the clear portion and recirculates the gas under pressure through the fine mist generator into the smog portion. Fresh smoke is introduced into the gas circulator via a smoke conveying conduit. A complementary smoke capturing method includes filling the reservoir, streaming the jet of fog-sized droplets toward a concentration of smoke dispersed within the lower smog portion of the gas filled portion, precipitating droplets, in the smog portion, into the pool by a fog-condenser disposed between the lower smog portion and the upper clear portion of the gas filled portion, recirculating under pressure, in a closed loop gas circulator, gas withdrawn from the clear portion into the smog portion through the fine mist generator, and conducting fresh smoke via smoke conveying conduit into the gas circulator.

A vapor/smoke capturing trap system featuring a smoke chamber trap for precipitating the smoke dispersed in the chamber. The chamber includes a bottom pool for containing a reservoir of a liquid solvent, and a gas filled portion in which a lower smog portion contains fog-sized droplets of the liquid solvent and into which the smoke is introduced, and an upper clear portion in which the concentration of the smoke and the droplets is decreased, respective of their concentration in the smog portion. A fog-condenser, disposed between the smog portion and the clear portion, precipitates the fog droplets of the smog portion into the pool. A fine mist generator streams a jet of fog-sized droplets of the liquid solvent mixed with smoke toward a concentration of the smoke at the smog portion. A closed loop gas circulator withdraws gas from the clear portion and recirculates the gas under pressure through the fine mist generator into the smog portion. Fresh smoke is introduced into the gas circulator via a smoke conveying conduit. A complementary smoke capturing method includes filling the reservoir, streaming the jet of fog-sized droplets toward a concentration of smoke dispersed within the lower smog portion of the gas filled portion, precipitating droplets, in the smog portion, into the pool by a fog-condenser disposed between the lower smog portion and the upper clear portion of the gas filled portion, recirculating under pressure, in a closed loop gas circulator, gas withdrawn from the clear portion into the smog portion through the fine mist generator, and conducting fresh smoke via smoke conveying conduit into the gas circulator.

A vapor/smoke capturing trap system featuring a smoke chamber trap for precipitating the smoke dispersed in the chamber. The chamber includes a bottom pool for containing a reservoir of a liquid solvent, and a gas filled portion in which a lower smog portion contains fog-sized droplets of the liquid solvent and into which the smoke is introduced, and an upper clear portion in which the concentration of the smoke and the droplets is decreased, respective of their concentration in the smog portion. A fog-condenser, disposed between the smog portion and the clear portion, precipitates the fog droplets of the smog portion into the pool. A fine mist generator streams a jet of fog-sized droplets of the liquid solvent mixed with smoke toward a concentration of the smoke at the smog portion. A closed loop gas circulator withdraws gas from the clear portion and recirculates the gas under pressure through the fine mist generator into the smog portion. Fresh smoke is introduced into the gas circulator via a smoke conveying conduit. A complementary smoke capturing method includes filling the reservoir, streaming the jet of fog-sized droplets toward a concentration of smoke dispersed within the lower smog portion of the gas filled portion, precipitating droplets, in the smog portion, into the pool by a fog-condenser disposed between the lower smog portion and the upper clear portion of the gas filled portion, recirculating under pressure, in a closed loop gas circulator, gas withdrawn from the clear portion into the smog portion through the fine mist generator, and conducting fresh smoke via smoke conveying conduit into the gas circulator.

This document generally describes a system and method configured to generate vapor samples from one or more smoking articles used for testing purposes. The system can be configured in a manner that generates a predetermined flow profile by driving a fluid pump in a scheme that accounts for fluid inertia.

This document generally describes a system and method configured to generate vapor samples from one or more smoking articles used for testing purposes. The system can be configured in a manner that generates a predetermined flow profile by driving a fluid pump in a scheme that accounts for fluid inertia.

A testing device for testing the impact of aerosolized compounds, such as e-cigarette vapors, metered-dose inhaled corticosteroids, and nebulized medications, on a human airway model system/tissue for purposes related to basic and clinical research, diagnostics, and personalized medicine. The device includes an intake fan assembly, a housing defining an exposure chamber, a holder supported on said housing for supporting an aerosol-generating device; and a control system operable to selectively energize the intake fan to draw the aerosolized compound into the exposure chamber, where human tissue is disposed. The testing device may also include an actuator operable by the control system to cause the aerosol-generating device to generate the aerosolized compound. The testing device may also include an exhaust fan operable by the control system to exhaust the aerosolized compound from the exposure chamber. Testing device components may be constructed of a biocompatible material that is autoclavable without detrimental degradation.

Disclosed is a method for monitoring use of a tobacco product by a subject, the method comprising providing the tobacco product to the subject and, at one or more times after providing the tobacco product, collecting a sample of exhaled breath from the subject and subjecting the collected sample to analysis to determine amount and/or concentration of a marker, wherein the amount and/or concentration of the marker is related to use of the tobacco product by the subject.