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Tier 2
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Original research — experimental, observational, or case-control study. Direct primary evidence.
Detection Methods
Human Health Effects
Nanoplastics
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Polylactic acid nanoplastics (PLA-NPLs) induce adverse effects on an in vitro model of the human lung epithelium: The Calu-3 air-liquid interface (ALI) barrier
Journal of Hazardous Materials2024
26 citations
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Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count.
Score: 65
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0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.
Aliro Villacorta
Iris Romero-Andrada,
Aliro Villacorta
Laura Rubio,
Laura Rubio,
Aliro Villacorta
Iris Romero-Andrada,
Iris Romero-Andrada,
Jéssica Arribas Arranz,
Ricard Marcos,
Alba García‐Rodríguez,
Aliro Villacorta
Aliro Villacorta
Alba Hernández,
Alba Hernández,
Alba Hernández,
Aliro Villacorta
Aliro Villacorta
Alícia Lacoma,
Ricard Marcos,
Ricard Marcos,
Aliro Villacorta
Javier J. Gutiérrez,
Laura Rubio,
Aliro Villacorta
Aliro Villacorta
Aliro Villacorta
Aliro Villacorta
Aliro Villacorta
Aliro Villacorta
Alba García‐Rodríguez,
Aliro Villacorta
Aliro Villacorta
Aliro Villacorta
Laura Rubio,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Aliro Villacorta
Aliro Villacorta
Aliro Villacorta
Aliro Villacorta
Laura Rubio,
Laura Rubio,
Jéssica Arribas Arranz,
Jéssica Arribas Arranz,
Ricard Marcos,
Jéssica Arribas Arranz,
Jéssica Arribas Arranz,
Jéssica Arribas Arranz,
Alba Hernández,
Jéssica Arribas Arranz,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Laura Rubio,
Ricard Marcos,
Aliro Villacorta
Alba Hernández,
Alba Hernández,
Alba Hernández,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Alícia Lacoma,
Laura Rubio,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Ricard Marcos,
Laura Rubio,
Aliro Villacorta
Alba Hernández,
Aliro Villacorta
Alba Hernández,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Iris Romero-Andrada,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Alba García‐Rodríguez,
Javier J. Gutiérrez,
Alícia Lacoma,
Ricard Marcos,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Ricard Marcos,
Alba Hernández,
Alba Hernández,
Laura Rubio,
Alba Hernández,
Ricard Marcos,
Alba Hernández,
Alícia Lacoma,
Alba García‐Rodríguez,
Alba Hernández,
Ricard Marcos,
Alba Hernández,
Ricard Marcos,
Ricard Marcos,
Laura Rubio,
Ricard Marcos,
Aliro Villacorta
Ricard Marcos,
Alba Hernández,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Alba Hernández,
Laura Rubio,
Alba Hernández,
Alba Hernández,
Ricard Marcos,
Ricard Marcos,
Alba García‐Rodríguez,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Ricard Marcos,
Ricard Marcos,
Ricard Marcos,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Ricard Marcos,
Ricard Marcos,
Laura Rubio,
Laura Rubio,
Ricard Marcos,
Laura Rubio,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Ricard Marcos,
Alba Hernández,
Alba García‐Rodríguez,
Alba Hernández,
Alba Hernández,
Alba Hernández,
Ricard Marcos,
Alba García‐Rodríguez,
Jéssica Arribas Arranz,
Ricard Marcos,
Alba García‐Rodríguez,
Alba Hernández,
Alba Hernández,
Aliro Villacorta
Summary
Even "eco-friendly" polylactic acid (PLA) nanoplastics -- made from plant-based biodegradable plastic -- caused significant damage to human lung cells in laboratory tests. Over two weeks of exposure, the particles penetrated the lung barrier, weakened the protective junctions between cells, increased mucus production, and caused DNA damage. This challenges the assumption that biodegradable plastics are automatically safer for human health than conventional plastics.
The expected increments in the production/use of bioplastics, as an alternative to petroleum-based plastics, require a deep understanding of their potential environmental and health hazards, mainly as nanoplastics (NPLs). Since one important exposure route to NPLs is through inhalation, this study aims to determine the fate and effects of true-to-life polylactic acid nanoplastics (PLA-NPLs), using the in vitro Calu-3 model of bronchial epithelium, under air-liquid interphase exposure conditions. To determine the harmful effects of PLA-NPLs in a more realistic scenario, both acute (24 h) and long-term (1 and 2 weeks) exposures were used. Flow cytometry results indicated that PLA-NPLs internalized easily in the barrier (∼10 % at 24 h and ∼40 % after 2 weeks), which affected the expression of tight-junctions formation (∼50 % less vs control) and the mucus secretion (∼50 % more vs control), both measured by immunostaining. Interestingly, significant genotoxic effects (DNA breaks) were detected by using the comet assay, with long-term effects being more marked than acute ones (7.01 vs 4.54 % of DNA damage). When an array of cellular proteins including cytokines, chemokines, and growth factors were used, a significant over-expression was mainly found in long-term exposures (∼20 proteins vs 5 proteins after acute exposure). Overall, these results described the potential hazards posed by PLA-NPLs, under relevant long-term exposure scenarios, highlighting the advantages of the model used to study bronchial epithelium tissue damage, and signaling endpoints related to inflammation.