The issue of microplastic(MPs)pollution has received increased attention in recent years.Studies have indicated that inhalation of microplastics may result in the cardiovascular harm.However,the specific mechanism rem...The issue of microplastic(MPs)pollution has received increased attention in recent years.Studies have indicated that inhalation of microplastics may result in the cardiovascular harm.However,the specific mechanism remains to be elucidated.In this study,5μm polystyrene microplastics(PS-MPs)were employed to construct in vivo and in vitro exposure models to investigate the potential mechanisms of microplastic-induced cardiac fibrosis.In vivo model of respiratory exposure to MPs,echocardiography observed a decrease in systolic-diastolic function of the mouse heart,and myocardial tissue showed significant mitochondrial morphological abnormalities and myocardial fibrosis.In vitro models also revealed upregulation of fibrosis indicators in human cardiomyocytes AC16 cells.Transcriptome and RT-qPCR assay exposed that ferroptosis-related pathways were significantly gath-ered in the MPs group,with decreased expression of ferroptosis related genes SLC7A11 and GPX4.Liproxstatin-1(Lip-1),a ferroptosis inhibitor,significantly ameliorated MPs-induced cardiomyocyte fibrosis and ferroptosis.We further demonstrated that inhibition of hypoxia-inducible factor𝛼(HIF-𝛼)and oxidative stress ameliorated PS-MPs-induced cardiomyocyte ferroptosis,and thus upregulation of the HIF pathway and oxidative stress may be the upstream mechanism of MPs-induced ferroptosis in myocardial fibrosis.Above all,our study demonstrated that MPs exposure resulted in cardiac fibrosis via the HIF-ROS-SLC7A11/GPX4 signaling pathway.展开更多
Microplastic contamination has emerged as a threat in transplantation,with evidence of its presence in human tissues and potential to compromise grafts.Transplant recipients,vulnerable due to immunosuppression and sur...Microplastic contamination has emerged as a threat in transplantation,with evidence of its presence in human tissues and potential to compromise grafts.Transplant recipients,vulnerable due to immunosuppression and surgical exposure,face risk from microplastics via airborne particles,surgical materials,and organ preservation systems.These particles trigger inflammation,oxidative stress,and immune dysregulation—pathways critical in rejection.Microplastics support biofilm formation,potentially facilitating antimicrobial resistance in clinical settings.Despite this risk,transplant-specific research is lacking.We urge action through environmental controls,material substitutions,and procedural modifications,alongside research targeting exposure pathways,biological impact,and mitigation strategies.Transplantation has historically led medical innovation and must do so in confronting this environmental challenge.Leadership from global transplant societies is essential to protect recipients and ensure safe procedures.展开更多
Microplastics,resulting from human activities,are widespread environmental contaminants that threaten both ecosystems and human health.These particles,less than 5 mm in size,are found in air,soil,and water,originating...Microplastics,resulting from human activities,are widespread environmental contaminants that threaten both ecosystems and human health.These particles,less than 5 mm in size,are found in air,soil,and water,originating from industrial waste and everyday plastic products.They come in various shapes,sizes,and colors,with primary and secondary microplastics formed through degradation processes.Microplastics have entered the food chain,affecting all trophic levels,with detrimental effects on organisms such as plankton,fish,and corals.Research on microplastics is hindered by methodological biases and sampling inconsistencies,which impact the reliability and comparability of data,as different techniques often yield varying results.Current degradation methods,including bioremediation and filtration,show potential but remain limited.Detecting microplastics is challenging due to their small size,though advanced techniques like morphological and analytical analyses,particularly in fish guts,aid detection.Targeted studies on microplastic levels in aquatic species are crucial,and the development of biodegradable alternatives is essential to mitigate their long-term environmental impact.展开更多
Microplastic accumulation after film mulching affects nutrients cycling in the soil–crop system.Bulk soil(BS)and rhizosphere soil(RS)have two different community compositions which lead to their different microbial n...Microplastic accumulation after film mulching affects nutrients cycling in the soil–crop system.Bulk soil(BS)and rhizosphere soil(RS)have two different community compositions which lead to their different microbial nutrient acquisition abilities.Microplastics influence the rhizosphere effect.However,the mechanism by which microplastic accumulation affects the net photosynthetic rate(NPR)through rhizospheric microbial communities remains unknown.This study aimed to identify the mechanisms underlying the effects of polyethylene(PE)and polyvinyl chloride(PVC)microplastics at 0,1,and 5%(w/w)on the NPR in the wheat–soil ecosystem using a pot experiment.Superoxide dismutase(SOD)activity was reduced by 15.35–36.7%,and that of peroxidase(POD)was increased by 32.47–61.93%,causing reductions in NPR(17.94–23.81%)in the PE5%and PVC(1 and 5%)(w/w)treatments compared with the control.The Chao1,Shannon,and Simpson indices of the bacterial and fungal diversities were lower in BS than in RS at PE1%and PVC5%(w/w),respectively.The bacterial and fungal network complexities were reduced and increased,respectively,owing to alterations in the bacterial and fungal community compositions and structures for wheat growth.The Mantel test showed that the bacterial and fungal diversity indices in BS had positive correlations with Olsen-P and phosphatase;however,those in RS were positively correlated with NO_(3)^(–) and β-1,4-glucosidase.The structural equation model indicated that wheat enzymatic and soil hydrolytic activities negatively affected NPR.Wheat has a profound antioxidant defense strategy for PE and PVC microplastic stress,which produces a synergistic effect of POD by protecting organelles and reducing tissue damage to preserve the NPR.展开更多
This study investigated microplastics(MPs)sized 10–5000μm across stages of a conventional municipal wastewater treatment plant using multiple analytical techniques.Samples were collected via pumping and filtration,t...This study investigated microplastics(MPs)sized 10–5000μm across stages of a conventional municipal wastewater treatment plant using multiple analytical techniques.Samples were collected via pumping and filtration,treated with the Fenton reaction for wet peroxidation,and separated by density separation.Analysis employed Focal Plane Array Micro-Fourier Transform Infrared Spectroscopy(FPA micro-FTIR),a widely used technique in MPs analysis,alongside the less common Laser Direct Infrared Spectroscopy(LDIR),providing complementary data on particle composition,shape,size,and colour.To enhance insights,spectroscopic methods were supplemented with Thermal Desorption Gas Chromatography-Mass Spectrometry(TD-GC/MS),calibrated for specific polymers,to quantify MPs by mass and assess removal efficiency.Wastewater treatment effectively reduced MPs.In influent samples,concentrations reached 72 MPs/L(FTIR),2117 MPs/L(LDIR),and 177μg/L(TD-GC/MS).Primary treatments removed 41%–55%,while the wastewater treatment plant effluent contained 1 MPs/L(FTIR),93 MPs/L(LDIR),and 2μg/L(TD-GC/MS),reflecting 96%–99%removal efficiency.Activated sludge showed concentrations of 123 MPs/L(FTIR),10,800 MPs/L(LDIR),and 0.3 mg/g dry weight(TD-GC/MS),underscoring its role in MPs capture.However,sludge dewatering released significant MPs into centrifuge rejected water:484 MPs/L(FTIR),23,000 MPs/L(LDIR),and 1100μg/L(TD-GC/MS).These results highlight the effectiveness of conventional treatments in MPs removal and the critical role of sludge in capturing these contaminants.However,sludge dewatering poses a risk of reintroducing MPs into the environment.Effective sludge management should prioritize nutrient recovery and biomass valorisation to mitigate these risks and minimise harmful environmental impacts.展开更多
Microplastics(MPs)have attracted growing attention worldwide as an increasingly prevalent environmental pollutant.In addition,chicken meat is currently the most widely consumed kind of poultry in the global market.Con...Microplastics(MPs)have attracted growing attention worldwide as an increasingly prevalent environmental pollutant.In addition,chicken meat is currently the most widely consumed kind of poultry in the global market.Consumer demand for chicken is on the rise both at home and abroad.As a result,the safety of chicken raising has also received significant attention.The lungs play an essential role in the physiological activities of chickens,and they are also the most vulnerable organs.Lung injury is difficult to repair after the accumulation of contaminants,and the mortality rate is high,which brings huge economic losses to farmers.The research on the toxicity of MPs has mainly focused on the marine ecosystem,while the mechanisms of toxicity and lung damage in chickens have been poorly studied.Thus,this study explored the effects of exposure to polystyrene microplastics(PS-MPs)at various concentrations for 42 d on chicken lungs.PS-MPs could cause lung pathologies and ultrastructural abnormalities,such as endoplasmic reticulum(ER)swelling,inflammatory cell infiltration,chromatin agglutination,and plasma membrane rupture.Simultaneously,PS-MPs increased the expression of genes related to the heat shock protein family(Hsp60,Hsp70,and Hsp90),ER stress signaling(activating) transcription factor 6(ATF0),ATF4,protein kinase RNA-like ER kinase(PERK),and eukaryotic translation initiation factor 2 subunitα(eIF2a),pyroptosis-related genes(NOD)-,LRR-and pyrin domain-containing protein 3(NLRP3),apoptosis-associated speck-like protein containing a caspase recruitment domain(ASC),interleukin-1β(IL-1β),cysteinyl aspartate-specific proteinase 1(Caspasel),and gasdermin-D(GSDMD),and the inflammatory signaling pathway(nuclear factor-kB(NF-kB),inducible nitric oxide synthase(iNOS),and cyclooxygenase-2(COX-2).The above results showed that PS-MP exposure could result in lung stress,ER stress,pyroptosis,and inflammation in broilers.Our findings provide new scientific clues for further research on the mechanisms of physical health and toxicology regardingMPs.展开更多
In this study,the occurrence,sources,and ecological risk of microplastics(>60μm)in the surface and bottom seawater were investigated in the Beibu Gulf,the northern South China Sea.The average abundance of micropla...In this study,the occurrence,sources,and ecological risk of microplastics(>60μm)in the surface and bottom seawater were investigated in the Beibu Gulf,the northern South China Sea.The average abundance of microplastics in surface and bottom waters was 1.35±0.93 and 0.79±0.50 items/m~3,respectively.Microplastics in both surface and bottom waters were predominantly in the form of fragments,and mostly in green.The composition of microplastics in surface water was primarily poly(methyl methacrylate)(PMA),whereas in bottom water,polyethylene(PE)dominated.Positive matrix factorization(PMF)modeling revealed that the primary sources of microplastics were pipeline abrasion,fishing activities,plastic waste,landfill disposal,transportation,aquaculture,and construction activities.The pollution load index(PLI)indicated that the overall risk of microplastic pollution in the Beibu Gulf was low.Conversely,the polymer hazard index(PHI)for microplastics was relatively high.These data underscore the importance of timely and effective reduction of human-intensive activities contributing to microplastic pollution and provide valuable information for further research in microplastic ecotoxicology and biogeochemistry.展开更多
Airborne microplastics(MPs)are important pollutants that have been present in the environment for many years and are characterized by their universality,persistence,and potential toxicity.This study investigated the e...Airborne microplastics(MPs)are important pollutants that have been present in the environment for many years and are characterized by their universality,persistence,and potential toxicity.This study investigated the effects of terrestrial and marine transport of MPs in the atmosphere of a coastal city and compared the difference between daytime and nighttime.Laser direct infrared imaging(LDIR)and polarized light microscopy were used to characterize the physical and chemical properties of MPs,including number concentration,chemical types,shape,and size.Backward trajectories were used to distinguish the air masses from marine and terrestrial transport.Twenty chemical types were detected by LDIR,with rubber(16.7%)and phenol-formaldehyde resin(PFR;14.8%)being major components.Three main morphological types of MPs were identified,and fragments(78.1%)are the dominant type.MPs in the atmosphere were concentrated in the small particle size segment(20-50μm).The concentration of MPs in the air mass from marine transport was 14.7 items/m^(3)-lower than that from terrestrial transport(32.0 items/m^(3)).The number concentration of airborne MPs was negatively correlated with relative humidity.MPs from terrestrial transport were mainly rubber(20.2%),while those from marine transport were mainly PFR(18%).MPs in the marine transport air mass were more aged and had a lower number concentration than those in the terrestrial transport air mass.The number concentration of airborne MPs is higher during the day than at night.These findings could contribute to the development of targeted control measures and methods to reduce MP pollution.展开更多
Microplastics(MPs),as a new category of environmental pollutant,have been the hotspot of eco-friendly issues nowadays.Studies based on the aging process,the migration pattern of MPs in runoff rainwater,and the use of ...Microplastics(MPs),as a new category of environmental pollutant,have been the hotspot of eco-friendly issues nowadays.Studies based on the aging process,the migration pattern of MPs in runoff rainwater,and the use of bioretention cells to remove MPs from runoff rainwater are beginning to attract widespread attention.This review analyses the migration patterns of MPs in rainwater runoff through their sources,structure and characteristics.The mechanism of removing MPs from runoff stormwater,the purification efficiency of different fillers and their influencing factors,and the accumulation,fate,and aging of MPs in bioretention cells are described.Furthermore,the hazards of MP accumulation on the performance of bioretention cells are summarised.Future directions for removing MPs in bioretention cells are proposed:(1)research on MPs smaller than 100μm;(2)influence of MPs aging process on bioretention cells;(3)exploration of more effective fillers to enhance their removal efficiency;(4)research on synergistic removal mechanism of MPs and other pollution.展开更多
Microplastics(MPs)are ubiquitous in the environment,continuously undergo aging processes and release toxic chemical substances.Understanding the environmental behaviors of MPs is critical to accurately evaluate their ...Microplastics(MPs)are ubiquitous in the environment,continuously undergo aging processes and release toxic chemical substances.Understanding the environmental behaviors of MPs is critical to accurately evaluate their long-term ecological risk.Generalized twodimensional correlation spectroscopy(2D-COS)is a powerful tool for MPs studies,which can dig more comprehensive information hiding in the conventional one-dimensional spectra,such as infrared(IR)and Raman spectra.The recent applications of 2D-COS in analyzing the behaviors and fates of MPs in the environment,including their aging processes,and interactions with natural organicmatter(NOM)or other chemical substances,were summarized systematically.The main requirements and limitations of current approaches for exploring these processes are discussed,and the corresponding strategies to address these limitations and drawbacks are proposed as well.Finally,new trends of 2D-COS are prospected for analyzing the properties and behaviors of MPs in both natural and artificial environmental processes.展开更多
Microplastics(MPs)have recently emerged as a significant environmental problem with devastating consequences for organisms.Understanding MPs pollution in the Bay of Bengal is crucial for assessing its ecological impac...Microplastics(MPs)have recently emerged as a significant environmental problem with devastating consequences for organisms.Understanding MPs pollution in the Bay of Bengal is crucial for assessing its ecological impact on marine biodiversity and human health.This study examined the occurrence,spatial distribution,physical and chemical properties,ecological risks,and probable sources of MPs in estuarine and coastal marine environments in the northeastern Bay of Bengal.The average concentration of MPs in surface water of the Karnaphuli estuary,the Meghna estuary,and the southeastern coastal region were 916.7±462.6 items/m^(3),462.9±324.5 items/m^(3),and 350.0±190.5 items/m^(3),respectively,varying from 105.0±324.5 items/m^(3)to 1640.0±462.6 items/m^(3).In the sediments of the Karnaphuli estuary,the Meghna estuary,and the southeast coast of Bangladesh,the average amount of MPs were 94.3±33.1 items/kg,157.6±89.0 items/kg,and 134.3±38.7 items/kg,with a range of 60±33.1 items/kg to 334.3±89.0 items/kg.Most observed MPs were fibers(60.0%in the water;56.0%in the sediments),followed by fragments and lines.Detected MPs were dominated by polypropylene(20.7%)in the water,and acrylic(15.4%)in the sediment,black colored(76.2%in the water,72.7%in the sediments),and 200-500μm sized(48%in the water,37%in the sediments).Pollution Risk Index(PRI)indicated significant pollution levels(from medium to very high)in estuarine and coastal areas.Multi-statistical analysis indicated land-based inputs(tourists,local waste,agriculture,and industry)dominated the studied regions.The study emphasized the potential impact of MPs pollution on aquatic ecosystems,emphasizing the need for effective management,mitigation methods,continuous surveillance,and thorough evaluation.展开更多
Microplastics(MPs)are of particular concern due to their ubiquitous occurrence and propensity to interact and concentrate various waterborne contaminants from aqueous surroundings.Studies on the interaction and joint ...Microplastics(MPs)are of particular concern due to their ubiquitous occurrence and propensity to interact and concentrate various waterborne contaminants from aqueous surroundings.Studies on the interaction and joint toxicity of MPs on engineered nanoparticles(ENPs)are exhaustive,but limited research on the effect of MPs on the properties of ENPs in multisolute systems.Here,the effect of MPs on adsorption ability of ENPs to antibiotics was investigated for the first time.The results demonstrated that MPs enhanced the adsorption affinity of ENPs to antibiotics and MPs before and after aging showed different effects on ENPs.Aged polyamide prevented aggregation of ZnONPs by introducing negative charges,whereas virgin polyamide affected ZnONPs with the help of electrostatic attraction.FT-IR and XPS analyses were used to probe the physicochemical interactions between ENPs and MPs.The results showed no chemical interaction and electrostatic interactionwas the dominant force between them.Furthermore,the adsorption rate of antibiotics positively correlated with pH and humic acid but exhibited a negative correlation with ionic strength.Our study highlights that ENPs are highly capable of accumulating and transporting antibiotics in the presence of MPs,which could result in a widespread distribution of antibiotics and an expansion of their environmental risks and toxic effects on biota.It also improves our understanding of the mutual interaction of various co-existing contaminants in aqueous environments.展开更多
As a new type of pollutant,the harm caused by microplastics(MPs)to organisms has been the research focus.Recently,the proportion of MPs ingested through the digestive tract has gradually increased with the popularity ...As a new type of pollutant,the harm caused by microplastics(MPs)to organisms has been the research focus.Recently,the proportion of MPs ingested through the digestive tract has gradually increased with the popularity of fast-food products,such as takeout.The damage to the digestive system has attracted increasing attention.We reviewed the literature regarding toxicity of MPs and observed that they have different effects on multiple organs of the digestive system.The mechanism may be related to the toxic effects of MPs themselves,interactions with various substances in the biological body,and participation in various signaling pathways to induce adverse reactions as a carrier of toxins to increase the time and amount of body absorption.Based on the toxicity mechanism of MPs,we propose specific suggestions to provide a theoretical reference for the government and relevant departments.展开更多
This paper summarizes the mechanisms and environmental effects of interactions between microplastics and surfactants: surfactants adsorb onto microplastics surfaces through hydrophobic interactions and electrostatic f...This paper summarizes the mechanisms and environmental effects of interactions between microplastics and surfactants: surfactants adsorb onto microplastics surfaces through hydrophobic interactions and electrostatic forces, changing their surface properties and transport behavior. In addition, microplastics act as carriers influencing surfactant distribution. Environmental factors (pH, ionic strength, etc. ) significantly regulate this process. Current research still has limitations in areas such as desorption kinetics and combined pollution effects, necessitating in-depth studies under environmentally relevant conditions to provide a basis for risk assessment.展开更多
As ubiquitous environmental contaminants,microplastics(MPs)have garnered global concern due to their persistence,bioaccumulation potential,and multifaceted threats to ecosystem health.These particles threaten terrestr...As ubiquitous environmental contaminants,microplastics(MPs)have garnered global concern due to their persistence,bioaccumulation potential,and multifaceted threats to ecosystem health.These particles threaten terrestrial ecosystems via soil contamination;however,research on their phytotoxicity remains predominantly focused on herbaceous plants.The responses of woody plants to MPs and their interspecific differences are severely unexplored.Here,two important ecological and economical tree species in southern China,Pinus massoniana(P.massoniana)and Schima superba(S.superba),were selected to explore the ecotoxicity effects of polyethylene(PE)and polypropylene(PP)MPs(the two most abundant species in the soil)on seedling growth characteristics,specific leaf area(SLA)and biomass allocation at 0%,1%,5%and 10%concentration gradients in the 120-day potted experiment.The results showed that the inhibition effect of MPs was concentration and tree species-dependent.Seedling height,basal diameter,and total biomass of P.massoniana decreased significantly with increased concentration,while S.superba showed a non-significant growth effect at 1%concentration.The SLA was generally increased,revealing that plants enhanced their light capture ability through leaf morphological plasticity to compensate for the loss of carbon assimilation.There were interspecific differences in root investment strategies:the root-shoot ratio of P.massoniana was significantly reduced by 48.43%under 10%PP treatment.In comparison,the root-shoot ratio of S.superba was significantly reduced by maintaining a higher root-shoot ratio(65.26%higher than that of P.massoniana on average)and phased resource allocation(5%concentration biomass is higher than 10%)partially alleviated the toxic pressure.Collectively,our results indicate that the ecotoxicity of MPs was mainly driven by concentration and was not correlated with type(PE/PP),while the differences in tree species response were closely related to their resource allocation strategies and morphological plasticity.These findings imply that MPs contamination can differently impact the growth and development of dominant tree species,potentially altering the structure,diversity,and function of forest ecosystems.This study systematically revealed the growth response mechanism of native common tree species to MPs pollution and provided a theoretical basis for sustainable management of plantations and toxicological risk assessment of forest ecosystems.展开更多
基金supported by the National Natural Science Foundation of China(No.82073520).
文摘The issue of microplastic(MPs)pollution has received increased attention in recent years.Studies have indicated that inhalation of microplastics may result in the cardiovascular harm.However,the specific mechanism remains to be elucidated.In this study,5μm polystyrene microplastics(PS-MPs)were employed to construct in vivo and in vitro exposure models to investigate the potential mechanisms of microplastic-induced cardiac fibrosis.In vivo model of respiratory exposure to MPs,echocardiography observed a decrease in systolic-diastolic function of the mouse heart,and myocardial tissue showed significant mitochondrial morphological abnormalities and myocardial fibrosis.In vitro models also revealed upregulation of fibrosis indicators in human cardiomyocytes AC16 cells.Transcriptome and RT-qPCR assay exposed that ferroptosis-related pathways were significantly gath-ered in the MPs group,with decreased expression of ferroptosis related genes SLC7A11 and GPX4.Liproxstatin-1(Lip-1),a ferroptosis inhibitor,significantly ameliorated MPs-induced cardiomyocyte fibrosis and ferroptosis.We further demonstrated that inhibition of hypoxia-inducible factor𝛼(HIF-𝛼)and oxidative stress ameliorated PS-MPs-induced cardiomyocyte ferroptosis,and thus upregulation of the HIF pathway and oxidative stress may be the upstream mechanism of MPs-induced ferroptosis in myocardial fibrosis.Above all,our study demonstrated that MPs exposure resulted in cardiac fibrosis via the HIF-ROS-SLC7A11/GPX4 signaling pathway.
文摘Microplastic contamination has emerged as a threat in transplantation,with evidence of its presence in human tissues and potential to compromise grafts.Transplant recipients,vulnerable due to immunosuppression and surgical exposure,face risk from microplastics via airborne particles,surgical materials,and organ preservation systems.These particles trigger inflammation,oxidative stress,and immune dysregulation—pathways critical in rejection.Microplastics support biofilm formation,potentially facilitating antimicrobial resistance in clinical settings.Despite this risk,transplant-specific research is lacking.We urge action through environmental controls,material substitutions,and procedural modifications,alongside research targeting exposure pathways,biological impact,and mitigation strategies.Transplantation has historically led medical innovation and must do so in confronting this environmental challenge.Leadership from global transplant societies is essential to protect recipients and ensure safe procedures.
文摘Microplastics,resulting from human activities,are widespread environmental contaminants that threaten both ecosystems and human health.These particles,less than 5 mm in size,are found in air,soil,and water,originating from industrial waste and everyday plastic products.They come in various shapes,sizes,and colors,with primary and secondary microplastics formed through degradation processes.Microplastics have entered the food chain,affecting all trophic levels,with detrimental effects on organisms such as plankton,fish,and corals.Research on microplastics is hindered by methodological biases and sampling inconsistencies,which impact the reliability and comparability of data,as different techniques often yield varying results.Current degradation methods,including bioremediation and filtration,show potential but remain limited.Detecting microplastics is challenging due to their small size,though advanced techniques like morphological and analytical analyses,particularly in fish guts,aid detection.Targeted studies on microplastic levels in aquatic species are crucial,and the development of biodegradable alternatives is essential to mitigate their long-term environmental impact.
基金supported by the National Natural Science Foundation of China(42407458 and 42307420)the Global Challenges Research Fund of the UK Natural Environment Research Council(NE/V005871/1)the Shandong Province First-class Discipline Construction“811”Project,China。
文摘Microplastic accumulation after film mulching affects nutrients cycling in the soil–crop system.Bulk soil(BS)and rhizosphere soil(RS)have two different community compositions which lead to their different microbial nutrient acquisition abilities.Microplastics influence the rhizosphere effect.However,the mechanism by which microplastic accumulation affects the net photosynthetic rate(NPR)through rhizospheric microbial communities remains unknown.This study aimed to identify the mechanisms underlying the effects of polyethylene(PE)and polyvinyl chloride(PVC)microplastics at 0,1,and 5%(w/w)on the NPR in the wheat–soil ecosystem using a pot experiment.Superoxide dismutase(SOD)activity was reduced by 15.35–36.7%,and that of peroxidase(POD)was increased by 32.47–61.93%,causing reductions in NPR(17.94–23.81%)in the PE5%and PVC(1 and 5%)(w/w)treatments compared with the control.The Chao1,Shannon,and Simpson indices of the bacterial and fungal diversities were lower in BS than in RS at PE1%and PVC5%(w/w),respectively.The bacterial and fungal network complexities were reduced and increased,respectively,owing to alterations in the bacterial and fungal community compositions and structures for wheat growth.The Mantel test showed that the bacterial and fungal diversity indices in BS had positive correlations with Olsen-P and phosphatase;however,those in RS were positively correlated with NO_(3)^(–) and β-1,4-glucosidase.The structural equation model indicated that wheat enzymatic and soil hydrolytic activities negatively affected NPR.Wheat has a profound antioxidant defense strategy for PE and PVC microplastic stress,which produces a synergistic effect of POD by protecting organelles and reducing tissue damage to preserve the NPR.
基金the Italian Ministry of Universities and Research for funding his PhD scholarship(37th Cycle Ph D Programmes supported by ESF REACT-EU funds,National Operational Programme on Research and Innovation)CSGI(Consorzio Interuniversitario per lo Sviluppo dei Sistemi a Grande Interfase-Center for Colloid and Surface Science),Florence(Italy)for financial support.
文摘This study investigated microplastics(MPs)sized 10–5000μm across stages of a conventional municipal wastewater treatment plant using multiple analytical techniques.Samples were collected via pumping and filtration,treated with the Fenton reaction for wet peroxidation,and separated by density separation.Analysis employed Focal Plane Array Micro-Fourier Transform Infrared Spectroscopy(FPA micro-FTIR),a widely used technique in MPs analysis,alongside the less common Laser Direct Infrared Spectroscopy(LDIR),providing complementary data on particle composition,shape,size,and colour.To enhance insights,spectroscopic methods were supplemented with Thermal Desorption Gas Chromatography-Mass Spectrometry(TD-GC/MS),calibrated for specific polymers,to quantify MPs by mass and assess removal efficiency.Wastewater treatment effectively reduced MPs.In influent samples,concentrations reached 72 MPs/L(FTIR),2117 MPs/L(LDIR),and 177μg/L(TD-GC/MS).Primary treatments removed 41%–55%,while the wastewater treatment plant effluent contained 1 MPs/L(FTIR),93 MPs/L(LDIR),and 2μg/L(TD-GC/MS),reflecting 96%–99%removal efficiency.Activated sludge showed concentrations of 123 MPs/L(FTIR),10,800 MPs/L(LDIR),and 0.3 mg/g dry weight(TD-GC/MS),underscoring its role in MPs capture.However,sludge dewatering released significant MPs into centrifuge rejected water:484 MPs/L(FTIR),23,000 MPs/L(LDIR),and 1100μg/L(TD-GC/MS).These results highlight the effectiveness of conventional treatments in MPs removal and the critical role of sludge in capturing these contaminants.However,sludge dewatering poses a risk of reintroducing MPs into the environment.Effective sludge management should prioritize nutrient recovery and biomass valorisation to mitigate these risks and minimise harmful environmental impacts.
基金This work was supported by the Key Projects of Natural Science Foundation of Heilongjiang Province of China(No.ZD2020C005).
文摘Microplastics(MPs)have attracted growing attention worldwide as an increasingly prevalent environmental pollutant.In addition,chicken meat is currently the most widely consumed kind of poultry in the global market.Consumer demand for chicken is on the rise both at home and abroad.As a result,the safety of chicken raising has also received significant attention.The lungs play an essential role in the physiological activities of chickens,and they are also the most vulnerable organs.Lung injury is difficult to repair after the accumulation of contaminants,and the mortality rate is high,which brings huge economic losses to farmers.The research on the toxicity of MPs has mainly focused on the marine ecosystem,while the mechanisms of toxicity and lung damage in chickens have been poorly studied.Thus,this study explored the effects of exposure to polystyrene microplastics(PS-MPs)at various concentrations for 42 d on chicken lungs.PS-MPs could cause lung pathologies and ultrastructural abnormalities,such as endoplasmic reticulum(ER)swelling,inflammatory cell infiltration,chromatin agglutination,and plasma membrane rupture.Simultaneously,PS-MPs increased the expression of genes related to the heat shock protein family(Hsp60,Hsp70,and Hsp90),ER stress signaling(activating) transcription factor 6(ATF0),ATF4,protein kinase RNA-like ER kinase(PERK),and eukaryotic translation initiation factor 2 subunitα(eIF2a),pyroptosis-related genes(NOD)-,LRR-and pyrin domain-containing protein 3(NLRP3),apoptosis-associated speck-like protein containing a caspase recruitment domain(ASC),interleukin-1β(IL-1β),cysteinyl aspartate-specific proteinase 1(Caspasel),and gasdermin-D(GSDMD),and the inflammatory signaling pathway(nuclear factor-kB(NF-kB),inducible nitric oxide synthase(iNOS),and cyclooxygenase-2(COX-2).The above results showed that PS-MP exposure could result in lung stress,ER stress,pyroptosis,and inflammation in broilers.Our findings provide new scientific clues for further research on the mechanisms of physical health and toxicology regardingMPs.
基金Supported by the National Natural Science Foundation of China(No.U20A20103)the Scientific Research Fund of the Fourth Institute of Oceanography+1 种基金Guangxi Funding Project(No.304024XM20N0006)the Guangxi Talent Science and Technology Project(No.2019AC17008)。
文摘In this study,the occurrence,sources,and ecological risk of microplastics(>60μm)in the surface and bottom seawater were investigated in the Beibu Gulf,the northern South China Sea.The average abundance of microplastics in surface and bottom waters was 1.35±0.93 and 0.79±0.50 items/m~3,respectively.Microplastics in both surface and bottom waters were predominantly in the form of fragments,and mostly in green.The composition of microplastics in surface water was primarily poly(methyl methacrylate)(PMA),whereas in bottom water,polyethylene(PE)dominated.Positive matrix factorization(PMF)modeling revealed that the primary sources of microplastics were pipeline abrasion,fishing activities,plastic waste,landfill disposal,transportation,aquaculture,and construction activities.The pollution load index(PLI)indicated that the overall risk of microplastic pollution in the Beibu Gulf was low.Conversely,the polymer hazard index(PHI)for microplastics was relatively high.These data underscore the importance of timely and effective reduction of human-intensive activities contributing to microplastic pollution and provide valuable information for further research in microplastic ecotoxicology and biogeochemistry.
基金supported by the National Natural Science Foundation of China (No.42075107)the Fundamental Research Funds for the Central Universities (No.2022YJSDC05)+1 种基金the China Scholarship Council (No.202206430058)the Yueqi Scholar Fund of China University of Mining and Technology (Beijing).
文摘Airborne microplastics(MPs)are important pollutants that have been present in the environment for many years and are characterized by their universality,persistence,and potential toxicity.This study investigated the effects of terrestrial and marine transport of MPs in the atmosphere of a coastal city and compared the difference between daytime and nighttime.Laser direct infrared imaging(LDIR)and polarized light microscopy were used to characterize the physical and chemical properties of MPs,including number concentration,chemical types,shape,and size.Backward trajectories were used to distinguish the air masses from marine and terrestrial transport.Twenty chemical types were detected by LDIR,with rubber(16.7%)and phenol-formaldehyde resin(PFR;14.8%)being major components.Three main morphological types of MPs were identified,and fragments(78.1%)are the dominant type.MPs in the atmosphere were concentrated in the small particle size segment(20-50μm).The concentration of MPs in the air mass from marine transport was 14.7 items/m^(3)-lower than that from terrestrial transport(32.0 items/m^(3)).The number concentration of airborne MPs was negatively correlated with relative humidity.MPs from terrestrial transport were mainly rubber(20.2%),while those from marine transport were mainly PFR(18%).MPs in the marine transport air mass were more aged and had a lower number concentration than those in the terrestrial transport air mass.The number concentration of airborne MPs is higher during the day than at night.These findings could contribute to the development of targeted control measures and methods to reduce MP pollution.
基金supported by the National Natural Science Foundation of China(No.52070152).
文摘Microplastics(MPs),as a new category of environmental pollutant,have been the hotspot of eco-friendly issues nowadays.Studies based on the aging process,the migration pattern of MPs in runoff rainwater,and the use of bioretention cells to remove MPs from runoff rainwater are beginning to attract widespread attention.This review analyses the migration patterns of MPs in rainwater runoff through their sources,structure and characteristics.The mechanism of removing MPs from runoff stormwater,the purification efficiency of different fillers and their influencing factors,and the accumulation,fate,and aging of MPs in bioretention cells are described.Furthermore,the hazards of MP accumulation on the performance of bioretention cells are summarised.Future directions for removing MPs in bioretention cells are proposed:(1)research on MPs smaller than 100μm;(2)influence of MPs aging process on bioretention cells;(3)exploration of more effective fillers to enhance their removal efficiency;(4)research on synergistic removal mechanism of MPs and other pollution.
基金supported by the National Natural Science Foundation of China(Nos.52293444 and 22076209)the Key R&D Project of Ningxia(No.2021BEG02006).
文摘Microplastics(MPs)are ubiquitous in the environment,continuously undergo aging processes and release toxic chemical substances.Understanding the environmental behaviors of MPs is critical to accurately evaluate their long-term ecological risk.Generalized twodimensional correlation spectroscopy(2D-COS)is a powerful tool for MPs studies,which can dig more comprehensive information hiding in the conventional one-dimensional spectra,such as infrared(IR)and Raman spectra.The recent applications of 2D-COS in analyzing the behaviors and fates of MPs in the environment,including their aging processes,and interactions with natural organicmatter(NOM)or other chemical substances,were summarized systematically.The main requirements and limitations of current approaches for exploring these processes are discussed,and the corresponding strategies to address these limitations and drawbacks are proposed as well.Finally,new trends of 2D-COS are prospected for analyzing the properties and behaviors of MPs in both natural and artificial environmental processes.
基金Supported by the National Natural Science Foundation of China(NSFC)Shared Voyage Project(Nos.41776088,41976018,42049911,U20A20103,U2005207)the Natural Science Key Foundation of Fujian Province,China(No.2020J01412103)+5 种基金the Hainan Province Science and Technology Special Fund(No.ZDYF2022SHFZ317)the Guangxi Talent and Innovation Base Project(No.2018AD19280)the Guangxi Funding Project(No.04024XM20N0006)the Beihai Science&Technology Project(Nos.201995037,202082031,202082022)the Natural Science Foundation of Xiamen City of China(No.502Z20227322)the China Scholarship Council(CSC Marine Scholarship)。
文摘Microplastics(MPs)have recently emerged as a significant environmental problem with devastating consequences for organisms.Understanding MPs pollution in the Bay of Bengal is crucial for assessing its ecological impact on marine biodiversity and human health.This study examined the occurrence,spatial distribution,physical and chemical properties,ecological risks,and probable sources of MPs in estuarine and coastal marine environments in the northeastern Bay of Bengal.The average concentration of MPs in surface water of the Karnaphuli estuary,the Meghna estuary,and the southeastern coastal region were 916.7±462.6 items/m^(3),462.9±324.5 items/m^(3),and 350.0±190.5 items/m^(3),respectively,varying from 105.0±324.5 items/m^(3)to 1640.0±462.6 items/m^(3).In the sediments of the Karnaphuli estuary,the Meghna estuary,and the southeast coast of Bangladesh,the average amount of MPs were 94.3±33.1 items/kg,157.6±89.0 items/kg,and 134.3±38.7 items/kg,with a range of 60±33.1 items/kg to 334.3±89.0 items/kg.Most observed MPs were fibers(60.0%in the water;56.0%in the sediments),followed by fragments and lines.Detected MPs were dominated by polypropylene(20.7%)in the water,and acrylic(15.4%)in the sediment,black colored(76.2%in the water,72.7%in the sediments),and 200-500μm sized(48%in the water,37%in the sediments).Pollution Risk Index(PRI)indicated significant pollution levels(from medium to very high)in estuarine and coastal areas.Multi-statistical analysis indicated land-based inputs(tourists,local waste,agriculture,and industry)dominated the studied regions.The study emphasized the potential impact of MPs pollution on aquatic ecosystems,emphasizing the need for effective management,mitigation methods,continuous surveillance,and thorough evaluation.
基金supported by the National Youth Foundation of China(No.52000064)the National Natural Science Foundation of China(No.U20A20323)+5 种基金the Natural Science Foundation of Hunan Province(No.2023JJ0013)the Special Funding for the Construction of Hunan’s Innovative Province(No.2021SK2040)the Science and Technology Innovation Program of Hunan Province(No.2021RC3133)the National Youth Foundation of China(No.52300227)the HunanMunicipal Natural Science Foundation(No.2023JJ41048)the Changsha Municipal Natural Science Foundation(No.kq2208423).
文摘Microplastics(MPs)are of particular concern due to their ubiquitous occurrence and propensity to interact and concentrate various waterborne contaminants from aqueous surroundings.Studies on the interaction and joint toxicity of MPs on engineered nanoparticles(ENPs)are exhaustive,but limited research on the effect of MPs on the properties of ENPs in multisolute systems.Here,the effect of MPs on adsorption ability of ENPs to antibiotics was investigated for the first time.The results demonstrated that MPs enhanced the adsorption affinity of ENPs to antibiotics and MPs before and after aging showed different effects on ENPs.Aged polyamide prevented aggregation of ZnONPs by introducing negative charges,whereas virgin polyamide affected ZnONPs with the help of electrostatic attraction.FT-IR and XPS analyses were used to probe the physicochemical interactions between ENPs and MPs.The results showed no chemical interaction and electrostatic interactionwas the dominant force between them.Furthermore,the adsorption rate of antibiotics positively correlated with pH and humic acid but exhibited a negative correlation with ionic strength.Our study highlights that ENPs are highly capable of accumulating and transporting antibiotics in the presence of MPs,which could result in a widespread distribution of antibiotics and an expansion of their environmental risks and toxic effects on biota.It also improves our understanding of the mutual interaction of various co-existing contaminants in aqueous environments.
文摘As a new type of pollutant,the harm caused by microplastics(MPs)to organisms has been the research focus.Recently,the proportion of MPs ingested through the digestive tract has gradually increased with the popularity of fast-food products,such as takeout.The damage to the digestive system has attracted increasing attention.We reviewed the literature regarding toxicity of MPs and observed that they have different effects on multiple organs of the digestive system.The mechanism may be related to the toxic effects of MPs themselves,interactions with various substances in the biological body,and participation in various signaling pathways to induce adverse reactions as a carrier of toxins to increase the time and amount of body absorption.Based on the toxicity mechanism of MPs,we propose specific suggestions to provide a theoretical reference for the government and relevant departments.
基金Supported by Zhaoqing University Innovation and Entrepreneurship Training Program for College Students (X202410580130).
文摘This paper summarizes the mechanisms and environmental effects of interactions between microplastics and surfactants: surfactants adsorb onto microplastics surfaces through hydrophobic interactions and electrostatic forces, changing their surface properties and transport behavior. In addition, microplastics act as carriers influencing surfactant distribution. Environmental factors (pH, ionic strength, etc. ) significantly regulate this process. Current research still has limitations in areas such as desorption kinetics and combined pollution effects, necessitating in-depth studies under environmentally relevant conditions to provide a basis for risk assessment.
基金supported by the Natural Science Talent Funding of Guizhou University(202132,202318)the Innovative Talent Team Project of Seedling Breeding and plantation cultivation for Precious Tree Species in Guizhou(Qiankehe Platform Talents-CXTD[2023]006).
文摘As ubiquitous environmental contaminants,microplastics(MPs)have garnered global concern due to their persistence,bioaccumulation potential,and multifaceted threats to ecosystem health.These particles threaten terrestrial ecosystems via soil contamination;however,research on their phytotoxicity remains predominantly focused on herbaceous plants.The responses of woody plants to MPs and their interspecific differences are severely unexplored.Here,two important ecological and economical tree species in southern China,Pinus massoniana(P.massoniana)and Schima superba(S.superba),were selected to explore the ecotoxicity effects of polyethylene(PE)and polypropylene(PP)MPs(the two most abundant species in the soil)on seedling growth characteristics,specific leaf area(SLA)and biomass allocation at 0%,1%,5%and 10%concentration gradients in the 120-day potted experiment.The results showed that the inhibition effect of MPs was concentration and tree species-dependent.Seedling height,basal diameter,and total biomass of P.massoniana decreased significantly with increased concentration,while S.superba showed a non-significant growth effect at 1%concentration.The SLA was generally increased,revealing that plants enhanced their light capture ability through leaf morphological plasticity to compensate for the loss of carbon assimilation.There were interspecific differences in root investment strategies:the root-shoot ratio of P.massoniana was significantly reduced by 48.43%under 10%PP treatment.In comparison,the root-shoot ratio of S.superba was significantly reduced by maintaining a higher root-shoot ratio(65.26%higher than that of P.massoniana on average)and phased resource allocation(5%concentration biomass is higher than 10%)partially alleviated the toxic pressure.Collectively,our results indicate that the ecotoxicity of MPs was mainly driven by concentration and was not correlated with type(PE/PP),while the differences in tree species response were closely related to their resource allocation strategies and morphological plasticity.These findings imply that MPs contamination can differently impact the growth and development of dominant tree species,potentially altering the structure,diversity,and function of forest ecosystems.This study systematically revealed the growth response mechanism of native common tree species to MPs pollution and provided a theoretical basis for sustainable management of plantations and toxicological risk assessment of forest ecosystems.
