Back to papers
0
Article ? AI-assigned paper type based on the abstract. Classification may not be perfect — flag errors using the feedback button. Tier 2 ? Original research — experimental, observational, or case-control study. Direct primary evidence. Detection Methods Human Health Effects Nanoplastics Policy & Risk Remediation Sign in to save

Detection and Quantification of Micro(nano)plastics Release from Photolysis of Surgical Masks

2023 Score: 40 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.
Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Guyu Peng, Dušan Materić, Guyu Peng, Guyu Peng, Guyu Peng, Guyu Peng, Guyu Peng, Dušan Materić, Guyu Peng, Guyu Peng, Guyu Peng, Guyu Peng, Guyu Peng, Guyu Peng, Dušan Materić, Dušan Materić, Guyu Peng, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Thorsten Reemtsma Guyu Peng, Guyu Peng, Guyu Peng, Thorsten Reemtsma Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Thorsten Reemtsma Dušan Materić, Thorsten Reemtsma Dušan Materić, Guyu Peng, Guyu Peng, Dušan Materić, Thorsten Reemtsma Thorsten Reemtsma Thorsten Reemtsma Thorsten Reemtsma Thorsten Reemtsma Thorsten Reemtsma Dušan Materić, Guyu Peng, Guyu Peng, Thorsten Reemtsma Thorsten Reemtsma Thorsten Reemtsma Guyu Peng, Guyu Peng, Dušan Materić, Dušan Materić, Thorsten Reemtsma Thorsten Reemtsma Thorsten Reemtsma Guyu Peng, Dušan Materić, Thorsten Reemtsma Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Guyu Peng, Thorsten Reemtsma Guyu Peng, Thorsten Reemtsma Thorsten Reemtsma Thorsten Reemtsma Thorsten Reemtsma Thorsten Reemtsma Dušan Materić, Thorsten Reemtsma Dušan Materić, Dušan Materić, Thorsten Reemtsma Dušan Materić, Dušan Materić, Dušan Materić, Dušan Materić, Guyu Peng, Thorsten Reemtsma

Summary

Researchers simulated 900 days of UV photolysis on surgical mask polypropylene and detected both microplastics larger than 10 µm (10 mg per mask item) and nanoplastics averaging 149 nm, demonstrating that mask degradation releases particles small enough to penetrate deep into the respiratory tract.

Polymers
PP
Body Systems
Respiratory

Since the Covid-19 pandemic, 129 billion masks have been consumed each month worldwide. Fate of masks not only include waste disposal sites and natural environments, but masks made from synthetic fibers may release micro(nano)plastics (MNPLs) that may reach respiratory tracts. However, degradation rate of MNPLs generated from masks have been unknown.Here, we simulated the photolysis of surgical masks made from polypropylene equivalent to 900 days. Size-fractionated MNPL formation was quantified using vibrational spectroscopic imaging, and mask deformation and morphology were characterized with correlative microscopy. Three layers of masks did not exhibit signs of degradation from hydroxyl and carbonyl groups, however, the outer layer exhibited a linear increase in crystallinity calculated from the peak height of two characteristic bands, indicating that degradation started from amorphous regions. However, for microplastics > 10 μm, both groups were observed, and mass concentration was 10 mg/item calculated from FTIR imaging data. Fine microplastics <10 μm were imaged and fitted as ellipses, and the most abundant aspect ratio was 2. Nanoplastics (<1 μm) with an average size of 149 (59) nm were detected by SEM/STEM and Raman spectroscopy. Cluster analyses on spectra categorized three groups, suggesting different additives (e.g., dyes) were added. This study detected nanoplastics from degraded masks, which have major implications for their environmental fate and human health effects.

Read via DOI Download PDF

Sign in to start a discussion.

Share this paper

Post Share Share Pin Email