Spatiotemporal distribution of microplastic debris in the surface beach sediment of the southeastern coast of Bangladesh

Impact of polystyrene microplastics (PS-MPs) on the entire female mouse reproductive cycle: Assessing reproductive toxicity of microplastics through in vitro follicle culture

This study aims to investigate the effects of polystyrene microplastics (PS-MPs) on the entire female reproductive cycle and to elucidate the molecular mechanisms underlying their adverse impact on female ovaries. Additionally, it develops an in vitro follicle culture system as a novel methodological approach to evaluate reproductive toxicity, mimicking in vivo reproductive outcomes. First, PS-MPs were characterized using FTIR spectroscopy, TEM, and fluorescence microscopy. To assess reproductive toxicity, female mice were exposed to polystyrene microplastics (PS-MPs) at a dose of 30 mg/kg with an average particle size of 1 μm for 35 days. As a result, PS-MPs accumulated in the ovaries, leading to increased follicular atresia and apoptosis of granulosa cells. TEM revealed abnormal mitochondrial morphology in granulosa cells. Post-superovulation treatment, significant differences were noted in the number of ovulated metaphase II (MII) oocytes, spindle chromosome integrity, mitochondrial patterns, and ROS levels compared to controls. Mating with PS-MPs-exposed females led to fewer offspring. The in vitro follicle culture system proved promising for assessing PS-MPs reproductive toxicity. Immunohistochemistry showed increased Cleaved Caspase 3 and decreased Bcl2 levels in PS-MPs-treated groups, indicating apoptosis in granulosa cells. PS-MPs activate JNK and ERK pathways to mediate cell death, while impairing AKT signaling, reducing granulosa cell survival and ovarian function. This study highlights PS-MPs adverse reproductive effects and aids in developing strategies to protect female reproductive health.

A systematic review on microplastic contamination in marine sediment and water of Asia: Concentration, characterization, and polymeric risk assessment

Microplastics (MPs) are ubiquitous in the marine environment and harmful for biodiversity. This review was based on 311 studies published on various online platforms published between 2006 and 2024 on MP contamination in marine sediment and water in different countries of Asia. The research highlights an increasing trend in MP contamination studies, with China and India. Analytical techniques for sample collection, digestion, flotation, and polymer identification are discussed. Fourier transform infrared spectroscopy (FTIR) emerged as the preferred method for polymer identification. The maximum MP contamination in marine sediments was recorded at Taiwan and Indonesia, while the maximum MP contamination in marine water was recorded in China, Malaysia, and India. The fiber was the most dominant shape. The 1-2 mm and 500 μ-1 mm-sized MPs having blue color were found dominantly. The pollution indices revealed a very high risk of MP contamination in all the Asian countries. PRACTITIONER POINTS: China and India are the leading in publications on MP contamination studies. Common tools used are steel scoop/spatula/shovel for sediment, nets for water. FTIR is the preferred method for polymer identification. Highest MP in sediment of Indonesia and in water of China, Malaysia, and India. Dominant MP shape: fiber; size 1-2 mm and 500 μ-1 mm, blue color.

Microplastic transport and ecological risk in coastal intruded aquifers based on a coupled seawater intrusion and microplastic risk assessment model

Seawater-groundwater interactions can enhance the migration process of microplastics to coastal aquifers, posing increased associated environmental risks. Here, we aim to analyze the relationship between seawater intrusion (SWI) and groundwater microplastic pollution in Laizhou Bay (LZB), which is a typical area of sea-land interactions. The results showed that modern seawater intrusion was the main process controlling the migration of microplastics. The detected microplastics in the study area showed a migration pattern from nearshore marine areas to groundwater aquifers along the SWI direction. In addition, the microplastics also reached the brine formed by palaeo-saltwater intrusion through hydraulic exchange between aquifers. By comparing the spatial distributions of different microplastic parameters, we found that nearshore fisheries, commercial, tourism, textile, and agricultural activities were the main sources of microplastics in groundwater in the study area. A risk assessment model of microplastics associated with SWI was further optimized in this study using a three-level classification system by assigning appropriate weights to different potential influencing factors. The results showed moderate comprehensive ecological risks associated with microplastics from seawater intrusion in the study area, with high microplastic enrichment risks. This study provides a scientific basis for future research on seawater-groundwater interactions and microplastic pollution in coastal regions.

Microplastics as a Threat to Aquatic Ecosystems and Human Health

The threat posed by microplastics has become one of the world's most serious problems. Recent reports indicate that the presence of microplastics has been documented not only in coastal areas and beaches, but also in water reservoirs, from which they enter the bodies of aquatic animals and humans. Microplastics can also bioaccumulate contaminants that lead to serious damage to aquatic ecosystems. The lack of comprehensive data makes it challenging to ascertain the potential consequences of acute and chronic exposure, particularly for future generations. It is crucial to acknowledge that there is still a substantial need for rapid and effective techniques to identify microplastic particles for precise evaluation. Additionally, implementing legal regulations, limiting plastic production, and developing biodegradation methods are promising solutions, the implementation of which could limit the spread of toxic microplastics.

Characterization of microplastics in outdoor and indoor air in Ranchi, Jharkhand, India: First insights from the region

The study focused on detecting and characterizing microplastics in outdoor and indoor air in Ranchi, Jharkhand, India during post-monsoon (2022) and winter (2023). Stereo microscopic analysis showed that plastic fibres had a dominant presence, fragments were less abundant, whereas fewer films could be detected in indoor and outdoor air. The atmospheric deposition of microplastics outdoors observed 465 ± 27 particles/m2/day in PM10 and 12104 ± 665 and 13833 ± 1152 particles/m2/day in PM2.5 in quartz and PTFE, respectively during the post-monsoon months. During winter, microplastic deposition rates in PM10 samples were found to be 689 ± 52 particles/m2/day and 19789 ± 2957 and 30087 ± 13402 in quartz and PTFE particles/m2/day respectively in PM2.5. The mean deposition rate in indoor environment during post-monsoon was 8.3 × 104 and 1.03 × 105 particles/m2/day in winter. During the post-monsoon period in PM10, there were fibres from 7.7 to 40 μm and fragments from 2.3 μm to 8.6 μm. Indoor atmospheric microplastics, fibres ranged from 1.2 to 47 μm and fragments from 0.9 to 16 μm present respectively during the post-monsoon season. Fibres and fragment sizes witnessed during winter were 3.6-6.9 μm and 2.3-34 μm, respectively. Indoor air films measured in the range of 4.1-9.6 μm. Fourier transform infrared analysis showed that outdoor air contained polyethylene, polypropylene, Polystyrene, whereas indoor air had polyvinyl chloride. Polyethylene mainly was present in outdoor air, with lesser polypropylene and polystyrene than indoors, where polyvinyl chloride and polyethylene were in dominant proportions. Elemental mapping of outdoor and indoor air samples showed the presence of elements on the microplastics. The HYSPLIT models suggest that the particles predominantly were coming from North-West during the post-monsoon season. Principal component analysis indicated wind speed and direction influencing the abundance of microplastics. Microplastics concentration showed strong seasonal influence and potential to act as reservoir of contaminants.