Ch Monn1, Ph Kindler, A Meile, O Brändli. 1. State Secretariat for Economic Affairs (SECO), Work and Health, Stauffacherstrasse 101, 8004 Zürich, Switzerland. christian.monn@seco.admin.ch
Abstract
OBJECTIVES: Ultrafine particle emissions from waterpipes and their impact on human health have not been extensively studied. The aim of this study was to characterise the inhalation pattern of waterpipe smokers, and (a) construct apparatus to simulate waterpipe smoking in the laboratory, and (b) characterise mainstream emissions from waterpipes under different smoking conditions. METHODS: Real life waterpipe smoking patterns were first measured with a spirometer. The average smoking pattern was then mechanically simulated in apparatus. Total particle number concentrations were determined with a condensation particle counter (CPC) for particles between 0.02 microm and 1 microm (P-Trak UPC, Model 8525, TSI) and the particle size fraction was determined with a differential mobility analyser (DMA) for particles from 0.01 microm to 0.5 microm. This instrument was coupled with a laser particle spectrometer for particles between 0.35 microm and 10 microm (Wide Range Particle Spectrometer, Model 1000XP, MSC Corp). Carbon monoxide levels were determined with an electrochemical sensor (Q-Trak monitor, Model 8554, TSI). RESULTS: The tidal volume of an average waterpipe breath of 5 seconds was found to be 1 (SD 0.47) litre. The intervals between breaths on average were 25.5 (SD 10.2) seconds. Particle number concentrations of ultrafine particles in mainstream smoke during waterpipe smoking ranged up to 70 x 10(9) particles per litre. The median diameter of the particles in a full smoking set with charcoal, tobacco and water was 0.04 microm. Smoke from the heated tobacco contributed to particles in the size range between 0.01 microm and 0.2 microm. The glowing piece of charcoal only contributed to particles smaller than 0.05 microm. CONCLUSIONS: Waterpipe smoking emits large amounts of ultrafine particles. With regard to particle emissions, smoking waterpipes may carry similar health risks to smoking cigarettes.
OBJECTIVES:Ultrafine particle emissions from waterpipes and their impact on human health have not been extensively studied. The aim of this study was to characterise the inhalation pattern of waterpipe smokers, and (a) construct apparatus to simulate waterpipe smoking in the laboratory, and (b) characterise mainstream emissions from waterpipes under different smoking conditions. METHODS: Real life waterpipe smoking patterns were first measured with a spirometer. The average smoking pattern was then mechanically simulated in apparatus. Total particle number concentrations were determined with a condensation particle counter (CPC) for particles between 0.02 microm and 1 microm (P-Trak UPC, Model 8525, TSI) and the particle size fraction was determined with a differential mobility analyser (DMA) for particles from 0.01 microm to 0.5 microm. This instrument was coupled with a laser particle spectrometer for particles between 0.35 microm and 10 microm (Wide Range Particle Spectrometer, Model 1000XP, MSC Corp). Carbon monoxide levels were determined with an electrochemical sensor (Q-Trak monitor, Model 8554, TSI). RESULTS: The tidal volume of an average waterpipe breath of 5 seconds was found to be 1 (SD 0.47) litre. The intervals between breaths on average were 25.5 (SD 10.2) seconds. Particle number concentrations of ultrafine particles in mainstream smoke during waterpipe smoking ranged up to 70 x 10(9) particles per litre. The median diameter of the particles in a full smoking set with charcoal, tobacco and water was 0.04 microm. Smoke from the heated tobacco contributed to particles in the size range between 0.01 microm and 0.2 microm. The glowing piece of charcoal only contributed to particles smaller than 0.05 microm. CONCLUSIONS: Waterpipe smoking emits large amounts of ultrafine particles. With regard to particle emissions, smoking waterpipes may carry similar health risks to smoking cigarettes.
Authors: Marielle C Brinkman; Hyoshin Kim; Sydney M Gordon; Robyn R Kroeger; Iza L Reyes; Dawn M Deojay; Caleb Chitwood; Timothy E Lane; Pamela I Clark Journal: Nicotine Tob Res Date: 2015-09-16 Impact factor: 4.244
Authors: Caroline Oates Cobb; Andrea Rae Vansickel; Melissa D Blank; Kade Jentink; Mark J Travers; Thomas Eissenberg Journal: Tob Control Date: 2012-03-24 Impact factor: 7.552
Authors: Aruni Bhatnagar; Wasim Maziak; Thomas Eissenberg; Kenneth D Ward; George Thurston; Brian A King; Erin L Sutfin; Caroline O Cobb; Merlyn Griffiths; Larry B Goldstein; Mary Rezk-Hanna Journal: Circulation Date: 2019-05-07 Impact factor: 29.690
Authors: Michael D Nelson; Mary Rezk-Hanna; Florian Rader; O'Neil R Mason; Xiu Tang; Sarah Shidban; Ryan Rosenberry; Neal L Benowitz; Donald P Tashkin; Robert M Elashoff; Jonathan R Lindner; Ronald G Victor Journal: Am J Cardiol Date: 2016-03-18 Impact factor: 2.778