Exposure to Ambient Particulate Matter During Specific Gestational Periods Produces Adverse Obstetric Consequences in Mice

Overview

Journal Environ Health Perspect

Date 2017 Sep 13

PMID 28893721

Citations 29

Authors

Jason L Blum

Lung-Chi Chen

Judith T Zelikoff

Affiliations

Soon will be listed here.

Abstract

Background: Epidemiological studies associate inhalation of fine-sized particulate matter (PM) during pregnancy with preterm birth (PTB) and low birth weight (LBW) but disagree over which time frames are most sensitive, or if effects are cumulative.

Objectives: Our objective was to provide experimental plausibility for epidemiological observations by testing the hypothesis that exposure to PM during discrete periods of pregnancy results in PTB and LBW.

Methods: For the first study, timed-pregnant B6C3F1 mice were exposed to concentrated ambient PM (CAPs) or filtered air (FA) throughout pregnancy [6 h/d from gestational day (GD) 0.5 through GD16.5]. A follow-up study examined the effects of CAPs exposure during discrete gestational periods (1: GD0.5–5.5; 2: GD6.5–14.5; 3: GD14.5–16.5; 4: GD0.5–16.5) aligning to milestones during human development.

Results: In the first experiment, exposure to 160 μg CAPs/m throughout pregnancy decreased gestational term by 0.5 d (∼1.1 wk decrease for humans) and birth weight by 11.4% compared with FA. The follow-up experiment investigated timing of CAPs exposure (mean concentrations at 178, 193, 171, and 173 μg/m for periods 1–4, respectively). Pregnancy was significantly shortened (vs. FA) by ∼0.4d when exposure occurred during gestational periods 2 and 4, and by ∼0.5d if exposure occurred during period 3. Exposure during periods 1, 2, and 4 reduced birth weight by ∼10% compared with FA, and placental weight was reduced (∼8%) on GD17.5 if exposure occurred only during period 3.

Conclusions: Adverse PM-induced outcomes such as PTB and LBW are dependent upon the periods of maternal exposure. The results of these experimental studies could contribute significantly to air pollution policy decisions in the future. https://doi.org/10.1289/EHP1029.

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