Search Results (139)

Micro- and nanoplastics (MNPs) are pervasive environmental contaminants with growing relevance for human health across the lifespan. Older adults may be especially vulnerable to their effects due to cumulative lifetime exposure, age-related physiological changes, and a higher burden of chronic disease. Adopting a One Health perspective, this review synthesizes current evidence on the sources, exposure pathways, and biological effects of MNPs, integrating findings from environmental, animal, and human studies with a specific focus on aging populations. Experimental studies consistently show that MNP exposure triggers oxidative stress, inflammation, mitochondrial dysfunction, and cellular senescence, mechanisms central to biological aging. These processes are linked to dysfunction of the cardiovascular, nervous, gastrointestinal, and immune systems, suggesting that MNPs may contribute to the development or progression of age-related diseases. Within the One Health framework, MNPs also act as carriers of chemical additives and environmental pollutants, potentially amplifying health risks through combined and cumulative exposures along food chains and ecosystems. Despite increasing mechanistic evidence, direct epidemiological data in older adults remain limited. This review highlights key knowledge gaps and emphasizes the need for integrative, longitudinal research to clarify the role of MNPs in aging and to inform public health and environmental policy. Full article

Plastic and microplastic (MP) pollution, along with alien species invasion, are of great concern for natural habitat preservation and human health, and are two important and concomitant likely causes for global biodiversity loss. In the present study, a Seabin, a device for buoyant waste collection in calm waters, was used to also characterize the waste collected in northernmost side of Lake Garda (Italy) in a period of very low anthropogenic pressure, the Winter season of 2024–2025. During the survey, 92.6 g of plastic was collected, i.e., a total of 540 pieces. About 6.9 mg of plastic per m³ of water was found, corresponding to about 0.04 plastic items per m³ and approximately 13 pieces of microplastics per day. Fourier-transform Infrared (FTIR) spectroscopy identification showed that the plastic was composed mainly of polyethylene (PE), polypropylene (PP), and polystyrene (PS). Microorganisms (Diatoms, Bacillariophyta) and microcrack formation with deposits of inorganic matter (mainly Si, Al, O, Ca) were also evidenced by SEM/EDX in all the observed aged MP. Qualitative evaluation of the captured biota highlighted the presence of at least five alien species, including invasive Dikerogammarus villosus. This study describes an easy and cost-effective novel methodology for simultaneously monitoring plastic waste and alien species presence in calm waters, which acts also as a mitigation tool for plastic pollution. The results could be of interest not only to policymakers and scientists, but also for public health and for environmental monitoring. Full article

Reliable detection of microplastics by surface-enhanced Raman scattering (SERS) is often hindered by poor particle–substrate contact and limited access to plasmonic hotspots on conventional planar substrates optimized for molecular adsorption. Here, we report a rapid microwave-assisted carbothermal shock strategy to fabricate silver nanoparticle-decorated electrospun carbon fibers (AgNPs@ECF) as a three-dimensional plasmonic platform tailored for solid microplastic sensing. Localized microwave-induced heating in a mixed ethanol–hexane system enables Ag nanoparticle nucleation and anchoring on conductive carbon fibers within 45 s, yielding a mechanically compliant, junction-rich architecture without chemical reductants or vacuum processing. The AgNPs@ECF composite was evaluated using morphologically weathered polystyrene (PS) and polyethylene terephthalate (PET) microplastics, along with size-controlled PS bead standards ranging from ~50 nm to 45 μm. Across these models, SERS response is governed primarily by particle–substrate contact geometry and near-field accessibility rather than polymer type. The strongest enhancement occurs in the sub-micrometer regime, where particles can engage multiple AgNP-decorated fiber junctions, while ultrasmall and large, smooth particles show reduced enhancement due to limited contact or rapid field decay. Spatially resolved Raman mapping and finite-difference time-domain simulations support a contact-dominated enhancement mechanism, revealing localized field confinement at particle–fiber interfaces. These results establish the design principles for three-dimensional SERS substrates targeting heterogeneous solid particulates, demonstrating that contact-accessible plasmonic architectures are critical for reliable microplastic detection under realistic solid-particle measurement conditions. Full article

Background/Objective: Photocatalytic oxidation is often interpreted as evidence of microplastic degradation, yet whether surface chemical modification under dry conditions corresponds to meaningful bulk polymer breakdown remains unclear. To help fill that gap, this study investigates the concentration-dependent photocatalytic aging of polystyrene (PS) microplastics incorporated into Titanium dioxide-coated hollow glass microsphere (TiO₂–HGM) composites under solid-state UV irradiation, with emphasis on distinguishing surface oxidation from bulk degradation. Methods: Thin-film composites containing 1 wt%, 5 wt%, and 10 wt% TiO₂–HGMs were exposed to UV-A irradiation (365 nm) for 183.5 h under dry conditions. Chemical and structural changes were evaluated using Fourier transform infrared spectroscopy (FTIR), X-ray photoelectron spectroscopy (XPS), and UV–visible spectroscopy. The carbonyl index (CI) was calculated from baseline-corrected integrated absorbance areas relative to an invariant aromatic reference band. Results: CI values increased from 0.483 (1 wt%) to 0.702 (5 wt%) and slightly decreased to 0.645 (10 wt%), indicating non-linear oxidation behavior and partial saturation. XPS showed a corresponding rise in the O/C ratio from 0.42 to 0.51. In contrast, UV–visible spectra exhibited minimal changes in aromatic absorption. Conclusions: Increasing photocatalyst concentration enhances surface oxidation but does not induce proportional bulk polymer degradation under solid-state conditions. Full article

Polymeric micro- and nanoplastic particles (MPs/NPs) have recently been recognized as potential biomedical pollutants that can enter the human bloodstream. Advances in analytical techniques have detected various polymers in human blood, raising concerns about their possible interactions with circulating cells, especially red blood cells (RBCs). RBCs are abundant, highly flexible, and lack internal repair mechanisms. This review summarizes current knowledge of how MPs and NPs interact with RBCs, emphasizing how physicochemical factors, including particle size, surface chemistry, environmental aging, and protein corona formation, influence hemocompatibility. Studies indicate that MPs can bind to RBC membranes, change the ζ-potential, reduce deformability, induce vesiculation and eryptosis, and, in some cases, cause hemolysis. These sublethal and lethal effects could have clinical significance, as even minor impairments in RBC mechanics may affect microvascular blood flow, oxygen delivery, and splenic clearance. Vulnerable populations—such as neonates and transfusion recipients—may be particularly susceptible to microparticle-induced RBC stress. While experimental data suggest MPs can harm RBCs, significant uncertainties remain regarding actual exposure levels, in vivo toxicity, and long-term health consequences. Addressing these gaps will require a multidisciplinary approach that combines environmental science, membrane biophysics, analytical chemistry, and clinical hematology to evaluate the health risks associated with increased microplastic exposure. Full article

Oxidative stress is a key contributing and convergent pathogenic mechanism linked to retinal and optic nerve diseases including age-related macular degeneration, diabetic retinopathy, and glaucoma. The retina is highly susceptible to redox imbalance due to intense mitochondrial activity, oxygen consumption, and light exposure. While endogenous drivers are well recognized, the contribution of environmental exposure to retinal oxidative injury remains incompletely defined. This review uniquely integrates emerging environmental contaminants with canonical oxidative stress pathways. We examine how cigarette smoke, ultraviolet radiation, heavy metals, microplastics, and per- and polyfluoroalkyl substances (PFASs) promote oxidative injury through mitochondrial dysfunction, inflammatory signaling, impaired antioxidant responses, and ferroptotic pathways. We also highlight therapeutic strategies targeting oxidative pathways and emphasize the importance of exposure-informed retinal and optic nerve disease research. Full article

This review synthesizes research on mechanisms of microplastic-induced mitochondrial damage, focusing on oxidative stress and inflammation to address the mechanistic pathways linking microplastic exposure to mitochondrial dysfunction and cellular toxicity. Analysis of diverse in vitro and in vivo studies across aquatic, terrestrial, and mammalian systems was conducted, emphasizing molecular, cellular, and functional mitochondrial parameters. Findings reveal consistent microplastic-induced reactive oxygen species generation, disrupting mitochondrial membrane potential and bioenergetics, with smaller and aged particles exerting greater toxicity. Inflammatory signalling via NF-κB, the NLRP3 inflammasome, and immune cell necroptosis is closely associated with oxidative stress, forming a feedback loop that exacerbates mitochondrial impairment. Molecular mechanisms implicate endocytic uptake pathways, mitochondrial calcium dysregulation, and apoptosis-related cascades, though causal validation remains limited. The interplay between oxidative stress and inflammation emerges as a central driver of mitochondrial damage across models. These integrated insights highlight the critical influence of microplastic physicochemical properties and biological context on mitochondrial and inflammatory responses. The findings inform future mechanistic research and underscore the need for standardized models to assess microplastic toxicity, advancing understanding of environmental and human health risks associated with microplastic pollution. Full article

Foodborne microplastics (MPs) are suspected carriers of co-ingested food contaminants, yet their digestive fate remains poorly characterized. This study simulates the role of environmentally aged polylactic acid (PLA) MPs—a common food-contact material—in transporting the antibiotic tetracycline (TC) through the human gastrointestinal tract. K₂S₂O₈-induced aging significantly increased PLA surface porosity, oxygen-containing groups, and hydrophilicity, elevating TC adsorption capacity from 0.54 to 0.95 mg/g. While adsorption kinetics were consistent with pseudo-second-order behavior, mechanistic analysis indicates that aging promotes interactions dominated by hydrogen bonding and electrostatic forces, rather than purely physical deposition. Critically, in vitro digestion models revealed that simulated intestinal fluid significantly enhances TC release (up to 62.7% of adsorbed load) compared to gastric conditions. Sequential gastrointestinal simulation yielded a bioaccessibility of 32.6%, indicating substantial digestive mobilization of MP-bound antibiotics. These findings underscore the potential of aged PLA MPs to act as digestive-stage “Trojan horses” for foodborne antibiotics. Our integrated approach—combining controlled aging, adsorption thermodynamics, and physiologically relevant digestion models—provides a mechanistic screening framework for assessing the bioaccessibility and exposure potential of microplastic-vectored contaminants in food safety contexts. Full article

Airborne microplastics (AMPs) undergo ultraviolet (UV)-driven physicochemical aging during atmospheric transport, influencing cloud processes, greenhouse-gas release, and potential respiratory health impacts. Quantifying this transformation is particularly challenging for particles smaller than 10 µm and for polymers such as polyethylene terephthalate (PET), whose intrinsic ester carbonyl band obscures newly formed acid carbonyls in conventional infrared analyses. Here, we develop a µFTIR attenuated total reflection (µFTIR-ATR) imaging method combined with a fourth-derivative oxidation index (carbonyl ratio at 1701/1716 cm⁻¹) that resolves these overlapping bands and enables sensitive, quantitative evaluation of PET surface oxidation. The approach automates detection, identification, and oxidation analysis of particles down to ~2 µm. Laboratory UV irradiation experiments show a systematic increase in this derivative-based oxidation index with exposure dose. Application to ambient PET collected from Mt. Fuji, Tokyo, Osaka (Japan), and Siem Reap (Cambodia) reveals clear regional differences corresponding to local UV-A environments: PET from Siem Reap exhibited the highest oxidation, whereas particles from the Japanese sites showed moderate but variable aging. These results demonstrate that derivative-based µFTIR-ATR imaging provides a practical and highly sensitive tool for quantifying photo-oxidative degradation in fine AMPs and highlight the value of chemical-aging metrics for interpreting atmospheric processing and transport pathways. Full article

Polypropylene microplastics (PP-MPs) represent a persistent class of marine pollutants due to their hydrophobicity, high crystallinity, and resistance to environmental degradation. This review summarizes recent advances in understanding the environmental behavior, physicochemical aging, and ecotoxicological risks of PP-MPs, with emphasis on microbial degradation pathways involving bacteria, fungi, algae, and filter-feeding invertebrates. The biodegradation of PP-MPs is jointly regulated by environmental conditions, polymer properties, and the structure and function of plastisphere communities. Although photo-oxidation and mechanical abrasion enhance microbial colonization by increasing surface roughness and introducing oxygenated functional groups, overall degradation rates remain low in marine environments. Emerging mitigation strategies include biodegradable polymer alternatives, multifunctional catalytic and adsorptive materials, engineered microbial consortia, and integrated photo–biodegradation systems. Key research priorities include elucidating molecular degradation mechanisms, designing programmable degradable materials, and establishing AI-based monitoring frameworks. This review provides a concise foundation for developing ecologically safe and scalable approaches to PP-MP reduction and sustainable marine pollution management. Full article

Pervasive microplastics (MPs) and per- and polyfluoroalkyl substances (PFAS) frequently co-occur across aquatic and terrestrial environments due to shared sources, transport pathways, and persistence, yet their interaction-driven effects on environmental fate, bioavailability, and toxicity remain incompletely resolved. This review critically synthesizes current knowledge on the environmental co-occurrence of MPs and PFAS, the physicochemical mechanisms governing their interactions, and the resulting ecological and toxicological consequences across aquatic, terrestrial, and biological systems. Emphasis is placed on sorption and desorption processes; environmental modifiers such as pH, salinity, dissolved organic matter (DOM), and aging; and biological responses under combined exposure scenarios. Across laboratory and field studies, MPs–PFAS co-exposure is frequently associated with altered PFAS partitioning and enhanced organismal uptake, with reported bioaccumulation increases of up to ~2.5-fold relative to PFAS-only exposures. These changes are often accompanied by amplified oxidative stress, immune dysregulation, metabolic disturbance, and reproductive impairment, particularly in aquatic invertebrates and early life stages of fish. Evidence further indicates that the magnitude and direction of combined effects depend on polymer type, particle size, surface aging, and biological context, underscoring the highly system-specific nature of MPs–PFAS interactions. By integrating findings from environmental monitoring, laboratory toxicology, and mechanistic and modeling studies, this review identifies key knowledge gaps related to nanoplastics detection, environmentally realistic exposure conditions, sorption reversibility, and mixture toxicity assessment. Collectively, these insights highlight limitations in current single-contaminant risk frameworks and underscore the importance of incorporating MPs-mediated PFAS transport and bioavailability into exposure assessment and regulatory evaluation. Full article

Introduction: Microplastics (MPs) are widespread environmental pollutants with possible neurotoxic effects. Exploring links between plastic use, MP awareness, and cognition is key for assessing public health risks. Objective: To examine correlations between plastic consumption, MP awareness and attitudes, and neurocognitive function among Greater Jakarta residents. Methods: A cross-sectional survey of 562 adults used a validated e-questionnaire covering plastic usage, MP knowledge, attitudes, risk perception, and cognition via the Ascertain Dementia 8 (AD-8). Analyses included chi-square, t-tests, and logistic regression. Results: Suspected cognitive impairment (AD-8 ≥ 2) was observed in 44.5% of respondents. High single-use plastic consumption correlated with worse cognition (p = 0.032), while reusable plastic use showed no association (p = 0.605). Awareness of MPs was relatively low, with 19.4% of respondents having never heard of them. Awareness and knowledge also varied significantly by age (p = 0.007), gender (p = 0.004), and education level (p = 0.027). Positive attitudes and higher risk perception aligned with greater awareness (p < 0.001) but not cognitive scores. Risk perception influenced bottled water use (p = 0.009), with low-risk groups consuming more. Conclusions: Frequent single-use plastic consumption is linked to poorer cognition, while MP awareness and risk perception do not directly affect cognitive outcomes. Educational strategies may enhance awareness and reduce exposure. Full article

With the continuous rise in global plastic production and emissions, microplastics (MPs) have become ubiquitous across environmental compartments, including the atmosphere. Aging in natural settings substantially alters MP physicochemical properties and, in turn, their interactions with coexisting contaminants. Here, polyethylene (PE), polyethylene terephthalate (PET), and polystyrene (PS) were subjected to ultraviolet (UV)-accelerated aging and natural exposure in marine intertidal zones, freshwater lakes, and the atmosphere, and changes in their properties and tetracycline (TC) adsorption were systematically compared. Aging intensity followed the order seawater > freshwater > air. Fourier-transform infrared spectroscopy showed the formation and enrichment of oxygen-containing functional groups, and naturally aged samples exhibited stronger oxidation signatures than those aged solely under UV irradiation. Adsorption kinetics indicated higher equilibrium capacities and rate constants for aged MPs; after 324 h of UV exposure in seawater, TC adsorption on PE, PS, and PET increased by 64.6%, 56.6%, and 64.0%, respectively. Mechanistic analysis suggests that surface roughening, oxygenated functional groups, and enhanced negative surface charge collectively promote TC adsorption, dominated by electrostatic interactions and hydrogen bonding. These findings not only elucidate how different aging pathways modulate the interactions between MPs and pollutants but also offer new insights into assessing the carrier potential of microplastics in environments such as the atmosphere and their adsorption of other contaminants. Full article

Herein, a high-performance Ta₂O₅/AgNPs composite Surface-Enhanced Raman Scattering (SERS) substrate is engineered for highly sensitive detection of microplastics. Through morphology modulation and band-gap engineering, the semiconductor Ta₂O₅ is structured into spheres and composited with silver nanoparticles (AgNPs), facilitating efficient charge transfer and localized surface plasmon resonance (LSPR). This architecture integrates electromagnetic (EM) and chemical (CM) enhancement mechanisms, achieving an ultra-low detection limit of 10⁻¹³ M for rhodamine 6G (R6G) with excellent linearity. Furthermore, the three-dimensional “pseudo-Neuston” network structure exhibits superior capture capability for microplastics (PS, PET, PMMA). To address spectral interference in simulated complex environments, a multi-scale deep-learning model combining wavelet transform, Convolutional Neural Networks (CNN), and Transformers is proposed. This model achieves a classification accuracy of 98.7% under high-noise conditions, significantly outperforming traditional machine learning methods. This work presents a robust strategy for environmental monitoring, offering a novel solution for precise risk assessment of microplastic pollution. Full article

The environmental behavior of biodegradable plastics under long-term hydrodynamic aging processes in seawater remains poorly understood, although plastic pollution has attracted global concern. This study obtained poly(butylene adipate-co-terephthalate) (PBAT) and poly(butylene succinate) (PBS) microplastics that endured 36-month hydrodynamic aging in seawater to elucidate their physicochemical transformations and interactions with benzo(a)pyrene (BaP). Hydrodynamic aging markedly altered surface morphology, generated cracks and pores, and enriched -C=O and -OH groups, indicating oxidative degradation. Adsorption experiments showed that BaP adsorption capacity of virgin PBAT/PBS reached 213.3/235.3 μg g⁻¹, while it increased to 233.3/258.2 μg g⁻¹ after hydrodynamic aging in seawater. Elevated salinity and alkaline conditions reduced BaP adsorption on microplastics. Notably, hydrodynamic aging mitigated the risk of BaP desorption from PBAT in ectothermic organisms. Gibbs free energy calculations indicated that the adsorption process was primarily driven by hydrophobic effects, hydrogen bonding, and van der Waals forces. These findings highlight that long-term hydrodynamic aging substantially modifies the interfacial properties of biodegradable plastics to alter their capacity for mediating the environmental fate of hydrophobic organic pollutants in marine ecosystems. Full article