Eline B Provost1, Luc Int Panis2, Nelly D Saenen3, Michal Kicinski3, Tijs Louwies1, Karen Vrijens3, Patrick De Boever1, Tim S Nawrot4. 1. Centre for Environmental Sciences, Hasselt University, Hasselt, Belgium; Environmental Risk and Health, Flemish Institute for Technological Research (VITO), Mol, Belgium. 2. Environmental Risk and Health, Flemish Institute for Technological Research (VITO), Mol, Belgium; School for Mobility, Hasselt University, Hasselt, Belgium. 3. Centre for Environmental Sciences, Hasselt University, Hasselt, Belgium. 4. Centre for Environmental Sciences, Hasselt University, Hasselt, Belgium; Department of Public Health & Primary Care, Leuven University, Leuven, Belgium. Electronic address: tim.nawrot@uhasselt.be.
Abstract
BACKGROUND: Microvascular changes may represent an underlying mechanism through which exposure to fine particulate matter with a diameter ≤ 2.5µm (PM2.5) contributes to age-related disease development. We investigated the effect of recent and chronic exposure to PM2.5 on the microcirculation, exemplified by retinal vessel diameters, using repeated measurements in 8- to 12-year-old children. METHODS: 221 children (49.1% girls; mean age 9.9 years) were examined repeatedly (25 one, 124 two, and 72 three times) adding up to 489 retinal vessel examinations. Same-day exposure to PM2.5 was measured at school. In addition, recent (same and previous day) and chronic (yearly mean) exposure was modelled at the child's residence using a high-resolution interpolation model. Residential proximity to major roads was also assessed. Changes in retinal vessel diameters associated with recent and chronic exposures were estimated using mixed models, while adjusting for other known covariates such as sex, age, BMI, blood pressure and birth weight. RESULTS: Each 10µg/m³ increment in same-day exposure to PM2.5 measured at school was associated with 0.35µm (95% CI: 0.09-0.61µm) narrower retinal arterioles and 0.35µm (-0.03 to 0.73µm) wider venules. Children living 100m closer to a major road had 0.30µm (0.05-0.54µm) narrower arterioles. CONCLUSIONS: Blood vessel diameters of the retinal microcirculation of healthy school-aged children respond to same-day PM2.5 exposure. Furthermore, children living closer to major roads had smaller arteriolar diameters. Our results suggest that the microcirculation, with retinal microvasculature as a proxy in this study, is a pathophysiological target for air pollution in children.
BACKGROUND: Microvascular changes may represent an underlying mechanism through which exposure to fine particulate matter with a diameter ≤ 2.5µm (PM2.5) contributes to age-related disease development. We investigated the effect of recent and chronic exposure to PM2.5 on the microcirculation, exemplified by retinal vessel diameters, using repeated measurements in 8- to 12-year-old children. METHODS: 221 children (49.1% girls; mean age 9.9 years) were examined repeatedly (25 one, 124 two, and 72 three times) adding up to 489 retinal vessel examinations. Same-day exposure to PM2.5 was measured at school. In addition, recent (same and previous day) and chronic (yearly mean) exposure was modelled at the child's residence using a high-resolution interpolation model. Residential proximity to major roads was also assessed. Changes in retinal vessel diameters associated with recent and chronic exposures were estimated using mixed models, while adjusting for other known covariates such as sex, age, BMI, blood pressure and birth weight. RESULTS: Each 10µg/m³ increment in same-day exposure to PM2.5 measured at school was associated with 0.35µm (95% CI: 0.09-0.61µm) narrower retinal arterioles and 0.35µm (-0.03 to 0.73µm) wider venules. Children living 100m closer to a major road had 0.30µm (0.05-0.54µm) narrower arterioles. CONCLUSIONS: Blood vessel diameters of the retinal microcirculation of healthy school-aged children respond to same-day PM2.5 exposure. Furthermore, children living closer to major roads had smaller arteriolar diameters. Our results suggest that the microcirculation, with retinal microvasculature as a proxy in this study, is a pathophysiological target for air pollution in children.
Authors: Jinghai Yi; Matthew G Duling; Lauren N Bowers; Alycia K Knepp; Ryan F LeBouf; Timothy R Nurkiewicz; Anand Ranpara; Todd Luxton; Stephen B Martin; Dru A Burns; Derek M Peloquin; Eric J Baumann; M Abbas Virji; Aleksandr B Stefaniak Journal: Inhal Toxicol Date: 2019-12-24 Impact factor: 2.724
Authors: Pauline Hautekiet; Tim S Nawrot; Stefaan Demarest; Johan Van der Heyden; Ilse Van Overmeire; Eva M De Clercq; Nelly D Saenen Journal: Arch Public Health Date: 2020-10-21
Authors: Annette Vriens; Eline B Provost; Nelly D Saenen; Patrick De Boever; Karen Vrijens; Oliver De Wever; Michelle Plusquin; Tim S Nawrot Journal: Sci Rep Date: 2018-05-29 Impact factor: 4.379
Authors: Leen J Luyten; Yinthe Dockx; Eline B Provost; Narjes Madhloum; Hanne Sleurs; Kristof Y Neven; Bram G Janssen; Hannelore Bové; Florence Debacq-Chainiaux; Nele Gerrits; Wouter Lefebvre; Michelle Plusquin; Charlotte Vanpoucke; Patrick De Boever; Tim S Nawrot Journal: BMC Med Date: 2020-05-26 Impact factor: 8.775
Authors: Nelly D Saenen; Eline B Provost; Ann Cuypers; Michal Kicinski; Nicky Pieters; Michelle Plusquin; Karen Vrijens; Patrick De Boever; Tim S Nawrot Journal: Environ Int Date: 2018-11-26 Impact factor: 9.621
Authors: Piotr Dąbrowiecki; Łukasz Adamkiewicz; Dominika Mucha; Piotr Oskar Czechowski; Mateusz Soliński; Andrzej Chciałowski; Artur Badyda Journal: J Clin Med Date: 2021-05-28 Impact factor: 4.241