Nanopolystyrene translocation and fetal deposition after acute lung exposure during late-stage pregnancy

Fournier, Sara; D’Errico, Jeanine N; Adler, Derek; Kollontzi, Stamatina; Goedken, Michael; Fabris, Laura; Yurkow, Edward J.; Stapleton, Phoebe A.

doi:10.1186/s12989-020-00385-9

Cited by 264 publications

(114 citation statements)

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“… Type of study MP size Polymer type Exposure methods Dosage and time Findings Ref. MPs translocation from the lung to the placenta 20 nm Polypropylene Intratracheal instillation during gestation 2.64 × 10 14 MPs, 24 h The exposure resulted in the translocation of MPs to placental and fetal tissues and rendered the fetoplacental unit vulnerable to adverse effects [ 57 ] MPs in human-derived cells 25–200 μm Polypropylene Addition to cultures (media) of somatic cells, blood cells, and murine immune cells 0.1–4.5 mg per well, 24 h MPs induced and triggered pro-inflammatory cytokines that caused a local immune response [ 51 ] MPs and various phthalate esters (PAEs) on human lung epithelial cells 100 nm Polystyrene Addition to cells MPs at 10, 20, 100, 200, 500 or 1000 μg mL −1 , 24 h Cells exhibited changes in viability, oxidative stress, and inflammatory reaction. [ 52 ] MPs on human cells 1 and 10 μm Polystyrene Addition to cells 0.05–100 μg mL −1 , 24, 48, 72, and 96 h Exposure significantly retards cell proliferation and triggered morphological changes [ 53 ] MPs in human-derived cells 5−25 μm, 25–75 μm, and 75–200 μm Polystyrene Dispersed in cell culture medium 1000, 100, and 10 μg mL −1 , 1 day and 4 days MPs increased acute inflammation, cell death by chemical toxicity, and induced cell membrane damage by physical toxicity [ 54 ] MPs on human intestinal epithelial cells 0.05–0.1 μm and 0.04–0.09 μm Polystyrene Exposure in cell culture medium 1–100 μg mL −1 , 24 or 48 h Cells uptake and internalized MPs, however, no toxic effects were observed.…”

Section: Introductionmentioning

confidence: 99%

Investigating the current status of COVID-19 related plastics and their potential impact on human health

De-la-Torre

Pizarro-Ortega

Dioses-Salinas

et al. 2021

Current Opinion in Toxicology

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The COVID-19 pandemic led to a sudden global increase in the production, consumption, and mismanagement of personal protective equipment (PPE). As plastic-based PPE such as disposable face masks and gloves have become widely used, human exposure to PPE-derived pollutants may occur through indirect and direct pathways. This review explores the potential health impacts related to plastic-based PPE through these pathways. Face masks release microplastics, which are directly inhaled during use or transported through the environment. The latter can adsorb chemical contaminants and harbor pathogenic microbiota, and once consumed by organisms, they can translocate to multiple organs upon intake, potentially causing detrimental and cytotoxic effects. However, more research is required to have a comprehensive overview of the human health effects.

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Section: Introductionmentioning

confidence: 99%

Investigating the current status of COVID-19 related plastics and their potential impact on human health

De-la-Torre

Pizarro-Ortega

Dioses-Salinas

et al. 2021

Current Opinion in Toxicology

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“…Very recently, a study also ascertained the presence of microplastics in the placenta of pregnant women, causing concern in the scientific community and confirming what was previously only conceivable [126]. The translocation in the placental barrier can also occur after inhalation, as observed in rats after inhalation of rhodamine-labeled nanopolystyrene beads [127], highlighting the possibility of airborne MPs to determine toxicity in organs other than the respiratory system.…”

Section: Toxicity Of Airborne Mp-npsmentioning

confidence: 65%

Newly Emerging Airborne Pollutants: Current Knowledge of Health Impact of Micro and Nanoplastics

Facciolà

Visalli

Ciarello

et al. 2021

IJERPH

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Plastics are ubiquitous persistent pollutants, forming the most representative material of the Anthropocene. In the environment, they undergo wear and tear (i.e., mechanical fragmentation, and slow photo and thermo-oxidative degradation) forming secondary microplastics (MPs). Further fragmentation of primary and secondary MPs results in nanoplastics (NPs). To assess potential health damage due to human exposure to airborne MPs and NPs, we summarize the evidence collected to date that, however, has almost completely focused on monitoring and the effects of airborne MPs. Only in vivo and in vitro studies have assessed the toxicity of NPs, and a standardized method for their analysis in environmental matrices is still missing. The main sources of indoor and outdoor exposure to these pollutants include synthetic textile fibers, rubber tires, upholstery and household furniture, and landfills. Although both MPs and NPs can reach the alveolar surface, the latter can pass into the bloodstream, overcoming the pulmonary epithelial barrier. Despite the low reactivity, the number of surface area atoms per unit mass is high in MPs and NPs, greatly enhancing the surface area for chemical reactions with bodily fluids and tissue in direct contact. This is proven in polyvinyl chloride (PVC) and flock workers, who are prone to persistent inflammatory stimulation, leading to pulmonary fibrosis or even carcinogenesis.

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“…Other environmental exposures, such as cadmium, are known to cause changes at the transcriptional level to the glucose transport proteins (GLUTs), impairing fetal glucose transfer (Xu et al, 2016). Alternatively, physical sedimentation of particles within the placenta may be causing physical blockage of fetal nutrient transfer (D'Errico et al, 2019;Fournier et al, 2020). Additional studies are required to understand potential placental molecular mechanisms that link exposure to nano-TiO 2 to FGR outcomes.…”

Section: Discussionmentioning

confidence: 99%

Considering Intrauterine Location in a Model of Fetal Growth Restriction After Maternal Titanium Dioxide Nanoparticle Inhalation

2021

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Fetal growth restriction (FGR) is a condition with several underlying etiologies including gestational disease (e.g., preeclampsia, gestational diabetes) and xenobiotic exposure (e.g., environmental contaminants, pharmaceuticals, recreational drugs). Rodent models allow study of FGR pathogenesis. However, given the multiparous rodent pregnancy, fetal growth variability within uterine horns may arise. To ascertain whether intrauterine position is a determinant of fetal growth, we redesigned fetal weight analysis to include litter size and maternal weight. Our FGR model is produced by exposing pregnant Sprague Dawley rats to aerosolized titanium dioxide nanoparticles at 9.44 ± 0.26 mg/m3 on gestational day (GD) 4, GD 12 or GD 17 or 9.53 ± 1.01 mg/m3 between GD 4-GD 19. In this study fetal weight data was reorganized by intrauterine location (i.e., right/left uterine horn and ovarian/middle/vaginal position) and normalized by maternal weight and number of feti per uterine horn. A significant difference in fetal weight in the middle location in controls (0.061 g ± 0.001 vs. 0.055 g ± 0.002), GD 4 (0.033 g ± 0.003 vs. 0.049 g ± 0.004), and GD 17 (0.047 g ± 0.002 vs. 0.038 g ± 0.002) exposed animals was identified. Additionally, GD 4 exposure produced significantly smaller feti in the right uterine horn at the ovarian end (0.052 g ± 0.003 vs. 0.029 g ± 0.003) and middle of the right uterine horn (0.060 g ± 0.001 vs. 0.033 g ± 0.003). GD 17 exposure produced significantly smaller feti in the left uterine horn middle location (0.055g ± 0.002 vs. 0.033 ± 0.002). Placental weights were unaffected, and placental efficiency was reduced in the right uterine horn middle location after GD 17 exposure (5.74 g ± 0.16 vs. 5.09 g ± 0.14). These findings identified: (1) differences in fetal weight of controls between the right and left horns in the middle position, and (2) differential effects of single whole-body pulmonary exposure to titanium dioxide nanoparticles on fetal weight by position and window of maternal exposure. In conclusion, these results indicate that consideration for intrauterine position, maternal weight, and number of feti per horn provides a more sensitive assessment of FGR from rodent reproductive and developmental studies.

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Nanopolystyrene translocation and fetal deposition after acute lung exposure during late-stage pregnancy

Cited by 264 publications

References 53 publications

Investigating the current status of COVID-19 related plastics and their potential impact on human health

Investigating the current status of COVID-19 related plastics and their potential impact on human health

Newly Emerging Airborne Pollutants: Current Knowledge of Health Impact of Micro and Nanoplastics

Considering Intrauterine Location in a Model of Fetal Growth Restriction After Maternal Titanium Dioxide Nanoparticle Inhalation

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