Oxidative Potential from Common Indoor Sources of Particulate Matter
P. S. Ganesh Subramanian, Zhuying Dai, Saman Haratian, Mohammad Heidarinejad, Brent Stephens, Vishal Verma
Abstract
Although people spend nearly 90% of their time indoors, the source-specific oxidative potential (OP) from indoor emissions spanning multiple particle generation mechanisms is largely unknown. Here, we quantify the OP of the PM originating from commonly used indoor sources via three different assays, i.e., dithiothreitol consumption (OP DTT ), glutathione consumption (OP GSH ), and hydroxyl radical generation (OP OH ). The intrinsic (mass-normalized) OP m of several sources (candles, incense, cigarettes, humidifiers using tap water, toasters, and air fryers) were comparable (0.75–1.25×) or exceeded (1–6×) that of typical ambient PM 2.5 . Emissions from candles in the presence of a wind-draft had the highest OP DTT m and OP OH m while OP GSH m was highest for cigarette emissions. Elemental carbon determined the OP of PM emitted from sources undergoing incomplete combustion, whereas, for noncombustion sources (water evaporation and heating-based), metals were the important drivers. An exploratory exposure assessment in a hypothetical apartment (volume = 100 m 3, air change rate = 0.45 h –1, and penetration coefficient = 0.6) revealed that certain sources (e.g., incense, cigarettes, toasters, and air-fryers) could result in occupants being exposed to higher OP in less than 1 h of indoor operation than that resulting from inhaling typical U.S. ambient PM 2.5 (8 μg/m 3 ) over an entire day. Collectively, these results demonstrate the importance of indoor emissions, emphasizing the need for more comprehensive health impact assessments to assist in the development of policy recommendations aimed at mitigating indoor PM exposure.