Review of Urban Bicyclists' Intake and Uptake of Traffic-Related Air Pollution

Bigazzi, Alexander; Figliozzi, Miguel

doi:10.1080/01441647.2014.897772

Cited by 104 publications

(75 citation statements)

References 118 publications

(167 reference statements)

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“…Ventilation volumes are presented at ambient temperature and pressure, which allows direct application for inhalation rate estimates. Mean ventilation rate of 22.4 lpm (liters per minute) is in good agreement with past studies of bicyclist inhalation (2). The average sampling conditions were 17 kph travel speed (without stops), 19 °C (range: 11-25 °C), 75% relative humidity (range: 57-91%), and 1.8 mps wind speed (range: 0.6-3.6 mps).…”

Section: Resultssupporting

confidence: 69%

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Dynamic Ventilation and Power Output of Urban Bicyclists

Bigazzi

Figliozzi

2015

Transportation Research Record

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Bicyclist intake of air pollutants is linked to physical exertion levels, ventilation rates, and exposure concentrations. Whereas exposure concentrations have been widely studied in transportation environments, there is relatively scant research linking on-road ventilation with travel conditions and exertion levels. This paper investigates relationships among power output, heart rate, and ventilation rate for urban bicyclists. Heart rate and ventilation rate were measured on-road and combined with power output estimates from a bicycle power model. Dynamic ventilation rates increased by 0.4-0.8% per watt of power output, with a mean lag of 0.8 minutes. The use of physiology (ventilation) monitoring straps and heart rate proxies for dynamic on-road ventilation measurements are discussed. This paper provides for a clearer and more quantitative understanding of bicyclists' ventilation and power output, which is useful for studies of pollutant inhalation risks, energy expenditure, and physical activity.

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Section: Resultssupporting

confidence: 69%

“…Beyond inhalation rate, particle deposition and location of gas absorption in the respiratory tract are affected by the relative values of and , in addition to other factors such as fraction oral breathing (2).…”

Section: Introductionmentioning

confidence: 99%

Dynamic Ventilation and Power Output of Urban Bicyclists

Bigazzi

Figliozzi

2015

Transportation Research Record

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“…The solubility of the gaseous pollutants determines the absorption and the diffusion rates and particle size influence deposition fraction in the lungs (Bigazzi and Figliozzi, 2014). Smaller particles enhanced the deposition and hygroscopic aerosols will absorb water vapor from the lungs, thus growing in size and consequently changing their deposition properties (Winkler-Heil et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

Estimating the inhaled dose of pollutants during indoor physical activity

Ramos

Reis

Almeida

et al. 2015

Science of The Total Environment

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“…However, due to their proximity to the traffic source, cyclists might be exposed to higher concentrations of traffic-related atmospheric pollutants [4]. Some studies that directly compared the exposure concentrations, i.e., the concentrations to which a person is exposed, among different urban transport modes [5][6][7], reported contrasting results and highlighted the dependency of the exposure levels on a large number of variables, such as road characteristics and meteorological conditions [8][9][10][11][12]. However, most of the available evidence for urban cycling suggests that: (i) the higher the volume of motorized traffic the greater the cyclists' exposure to traffic-related pollutants, and in particular to ultrafine particles (UFPs, diameter smaller than 0.1 µm) and black carbon (BC); and (ii) bicycle paths that offer lateral separation between the cyclists and the motorized traffic reduce the concentration they are exposed to, as increased exposure concentrations are associated with increased proximity to traffic [13].…”

Section: Introductionmentioning

confidence: 99%

Variability of Black Carbon and Ultrafine Particle Concentration on Urban Bike Routes in a Mid-Sized City in the Po Valley (Northern Italy)

et al. 2017

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Abstract:Cyclists might experience increased air pollution exposure, due to the proximity to traffic, and higher intake, due to their active travel mode and higher ventilation. Several local factors, like meteorology, road and traffic features, and bike lanes features, affect cyclists' exposure to traffic-related pollutants. This paper investigates the concentration levels and the effect of the features of the bike lanes on cyclists' exposure to airborne ultrafine particulate matter (UFP) and black carbon (BC) in the mid-sized city of Piacenza, located in the middle of the Po Valley, Northern Italy. Monitoring campaigns were performed by means of portable instruments along different urban bike routes with bike lanes, characterized by different distances from the traffic source (on-road cycle lane, separated cycle lane, green cycle path), during morning (9:00 am-10:00 am) and evening (17:30 pm-18:30 pm) workday rush hours in both cold and warm seasons. The proximity to traffic significantly affected cyclists' exposure to UFP and BC: exposure concentrations measured for the separated lane and for the green path were 1-2 times and 2-4 times lower than for the on-road lane. Concurrent measurements showed that exposure concentrations to PM10, PM2.5, and PM1 were not influenced by traffic proximity, without any significant variation between on-road cycle lane, separated lane, or green cycle path. Thus, for the location of this study PM mass-based metrics were not able to capture local scale concentration gradients in the urban area as a consequence of the rather high urban and regional background that hides the contribution of local scale sources, such as road traffic. The impact of route choice on cyclists' exposure to UFPs and BC during commuting trips back and forth from a residential area to the train station has been also estimated through a probabilistic approach through an iterative Monte Carlo technique, based on the measured data. Compared to the best choice, a worst-route choice can result in an increased cumulative exposure up to about 50% for UFPs, without any relevant difference between cold and warm season, and from 20% in the cold season up to 90% in the warm season for equivalent black carbon concentration (EBC).

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Review of Urban Bicyclists' Intake and Uptake of Traffic-Related Air Pollution

Cited by 104 publications

References 118 publications

Dynamic Ventilation and Power Output of Urban Bicyclists

Dynamic Ventilation and Power Output of Urban Bicyclists

Estimating the inhaled dose of pollutants during indoor physical activity

Variability of Black Carbon and Ultrafine Particle Concentration on Urban Bike Routes in a Mid-Sized City in the Po Valley (Northern Italy)

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