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
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
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
Microplastics are becoming well-known as chronic pollutants of terrestrial ecosystems,although their sources,dynamics of transportation,reliability of detection and ecological hazard are not evenly described.This revi...Microplastics are becoming well-known as chronic pollutants of terrestrial ecosystems,although their sources,dynamics of transportation,reliability of detection and ecological hazard are not evenly described.This review is a synthesis of the existing information about microplastics in soils,including analytical detection and characterization techniques,the major sources in the terrestrial environment,transport routes within the compartments and between compartments,and reported ecotoxicological consequences on soil biota,plants,and microbial communities.We also critically discuss the strengths and weaknesses of methodologies,making the distinction of sampling design differences,size detection limits,polymer identification methods,and quality assurance procedures on data comparability and uncertainty.An important outcome of this review is the systematic evaluation of the strength of evidence in three interrelated areas:measurement,environmental transport,and biological impacts,hence explaining which findings are strong and in which areas of research significant knowledge gaps still exist.We also suggest a conceptual framework that strongly connects the measurement uncertainty to the exposure estimation,interpretation of risk,and management relevance.This review uses mechanistic insights into transport and ecotoxicology alongside analysis constraints to add to the more comprehensive foundation of terrestrial risk assessment.Lastly,we determine research priorities,such as harmonized methodologies,realistic exposure scenarios,and cross-scale monitoring strategies,in order to assist in the science-based policies and mitigation action.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
Epoxy resins are widely employed in wind turbine blades,drone rotors,and automotive interiors due to their excel-lent mechani-cal proper-ties and long service life.However,their insoluble and infusible cross-linked ne...Epoxy resins are widely employed in wind turbine blades,drone rotors,and automotive interiors due to their excel-lent mechani-cal proper-ties and long service life.However,their insoluble and infusible cross-linked networks pose a significant re-cycling challenge,particularly with the impending retirement of the first generation of wind turbine blades.In this work,we reported a fully bio-based epoxy Vitrimer(FEP)incorporat-ing a dual-dynamic covalent network design and systematically investigated the influence of the 1,5,7-triazabicyclo[4.4.0]dec-5-ene(TBD)catalyst on its curing kinetics,thermal/mechan-ical properties,dynamic exchange behavior,and degradation performance in a mild alkaline solution.Compared to conventional epoxy resins,FEP exhibited superior tensile strength and elongation at break at an optimal TBD concentration(2 wt%),achieving an excellent strength-toughness balance.The presence of TBD accelerated the exchange rates of both disulfide and ester bonds,endowing FEP with notable stress relaxation at elevated tempera-tures.Moreover,FEP demonstrated complete dissolution in 1 mol/L NaOH within 6 h at 25℃.These results underscored the exceptional strength,toughness,and recyclability of FEP,positioning it as a promising,environmentally friendly matrix resin for next-generation appli-cations in the new energy sector.展开更多
The structural design and performance characteristics of the diaphragm have a decisive impact on the safety and electrochemical performance of lithium-ion batteries(LIBs).However,traditional polyolefin diaphragms stil...The structural design and performance characteristics of the diaphragm have a decisive impact on the safety and electrochemical performance of lithium-ion batteries(LIBs).However,traditional polyolefin diaphragms still face challenges in simultaneously improving the ion transport efficiency and thermal stability.Here,we report an in situ dynamic lithium compensation strategy for manufacturing a biobased furan aramid/ceramic diaphragm(BAS)with higher thermal stability and ion transport efficiency.Specifically,exchangeable carboxyl groups(–COOH)are introduced into the bio-based furan aramid(BA)framework,which are in situ converted into–COOLi groups to form lithium ions(Li^(+))transport channels,achieving dynamic compensation of active Li^(+).The dual transmission system of ion exchange and physical pore channels synergistically enhances the ionic conductivity of BAS to 1.536 mS cm^(-1).The high polarity structure of the furan ring and the electrolyte have excellent compatibility,significantly reducing the solid–liquid interfacial energy,making BAS have extremely high electrolyte wettability(contact angle of 0°).The BA amide group forms a multi-scale bonding network with the nano-ceramics.The BAS prepared by the water-coating process exhibits excellent thermal stability(with a thermal shrinkage rate of less than 1%after 1 h at 150℃).The LiFePO_(4)|Li half-cell assembled with BAS shows a capacity retention rate of up to 91.7%after 280 cycles at 1C,with a Coulomb efficiency of 99%,demonstrating excellent cycling stability.This design and development based on bio-materials provides a new approach for high safety and high energy density battery systems.展开更多
Developing green and efficient methods to acquire lignocellulose-based chemicals with high added value is beneficial for facilitating green chemistry and sustainable development.The goal of this study is to demonstrat...Developing green and efficient methods to acquire lignocellulose-based chemicals with high added value is beneficial for facilitating green chemistry and sustainable development.The goal of this study is to demonstrate that bio-based benzaldehyde,a noteworthy high-value chemical,is able to be directionally prepared from lignocellulosic biomass.This new control-lable transformation was materialized by uniting catalytic-pyrolysis of lignocellulose to toluene intermediate and catalytic oxidation of toluene intermediate to bio-based benzalde-hyde.This work also developed a highly active magnetic catalyst(CoFe_(2)O_(4)@Biochar(HTR)),achieving 77.1%benzaldehyde selectivity and 46.7%benzaldehyde yield using this catalyst.It was found that introducing the biochar carrier into the cobalt iron composite metal oxide cat-alyst enhanced hydroxyl radical formation and bio-based benzaldehyde synthesis.Based on catalyst characterizations and hydroxyl radical analysis,potential reaction mechanism for bio-based benzaldehyde synthesis was proposed.This strategy may provide a beneficial pathway for developing high-value bio-based chemical(benzaldehyde)using renewable lignocellulosic biomass.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
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)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
With the escalating global emphasis on environmental conservation and sustainable development,enhancing the service quality and durability of road surfaces and facilitating the green development of highways have comma...With the escalating global emphasis on environmental conservation and sustainable development,enhancing the service quality and durability of road surfaces and facilitating the green development of highways have commanded considerable attention.Bio-based polyurethane,on account of its remarkable physical and chemical properties,green,sustainable and renewable capacity,as well as its structural design capabilities,has drawn widespread attention and numerous studies have been carried out.It has gradually started to substitute traditional petroleum-based polyurethane materials in road engineering.Nevertheless,the application of bio-based polyurethane materials in road engineering remains in the exploratory phase.To stimulate the application research of bio-based polyurethane materials in road engineering and offer additional research directions,this paper reviews the research advancements of bio-based polyurethane materials and their applications in road engineering.The fundamental classification of bio-based polyurethane is introduced.The characteristics and challenges associated with various preparation methods for bio-based polyurethane are described.The influence of bio-based polyurethane on road engineering materials are analyzed.The evaluation indicators of bio-based polyurethane within the life cycle of road engineering are investigated.Finally,the development tendency towards in road engineering applications are forecasted.This paper provides a reference for the study of bio-based polyurethane materials in road engineering applications.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
Microplastics(MPs) are an emerging environmental pollutant and have penetrated the most remote and primitive areas. MPs degradation has received widespread attention. Manganese(Mn) is a highly reactive metal element i...Microplastics(MPs) are an emerging environmental pollutant and have penetrated the most remote and primitive areas. MPs degradation has received widespread attention. Manganese(Mn) is a highly reactive metal element in the environment, yet its contribution to MPs degradation remains unclear. Herein,we simulated the aging of polyethylene MPs with Mn(Ⅱ) under aqueous conditions at pH 5 and 8 for720 days. Mn greatly promoted the MPs degradation, and the average particle sizes of polyethylene MPs were reduced from 9.2 μm to 5.9 μm after aging at pH 5 under light irradiation for 720 days. Plenty of oxygen-containing groups were generated on the MPs surfaces, and the carbonyl index remarkably increased, reaching four times that of the control without adding Mn. Mechanistically, the adsorbed Mn(Ⅱ)on the MPs surfaces were primarily oxidized to high-valence Mn(Ⅲ/Ⅳ) profited from the photoproduced radicals, followed by the MPs oxidation via Mn(Ⅲ/Ⅳ), which were reduced to regenerate Mn(Ⅱ), initiating a new redox cycling. During the degradation, dissolved organic matter was continuously released, mainly including bisphenol A and phthalic acid esters. Mn acts as a catalyst to accelerate the MPs degradation by redox cycling. Our results provide a new insight into the mechanisms of abiotic degradation of MPs in aqueous environments.展开更多
Microplastics(MPs)pollution has become a worldwide environmental problem.The study about the effects of microplastics on fish,especially on the fish immune system is limited.In the present study,the transcriptome of s...Microplastics(MPs)pollution has become a worldwide environmental problem.The study about the effects of microplastics on fish,especially on the fish immune system is limited.In the present study,the transcriptome of soiny mullet(Liza haematocheila)larvae at 7 d and 14 d post 0.5μm MPs exposure were analyzed by DNBSEQ platform.A total number of 96585 unigenes were obtained with average length of 1925 bp.Approximately 72.48%(70004),76.80%(74176),and 62.94%(60787)unigenes were matched with the annotated sequences for non-redundant(NR),NCBI nucleotide(NT)and Swissprot database,respectively.Compared with control group,1336 differently expressed genes(DEGs)were identified at 7 d post MPs exposure.As the MPs exposure time extended to 14 d,the number of DEGs in the MPs exposure group reached to 3561.Further,KEGG enrichment analysis revealed that several immune-related pathways,such as interleukin(IL)-17 signaling pathway,tumor necrosis factor(TNF)signaling pathway,were affected by MPs exposure.In addition,apoptosis signaling pathway was also enriched under MPs exposure.These results demonstrated that MPs can alter the expressions of immune-related genes,providing basis for understanding the immune toxicity of MPs on fish and other vertebrates.展开更多
As the main component of electronic products,plastics contain complex and diverse metal additives.Recycling process is not conducive to stable existence of metal additives in electronic plastics.Once the e-waste plast...As the main component of electronic products,plastics contain complex and diverse metal additives.Recycling process is not conducive to stable existence of metal additives in electronic plastics.Once the e-waste plastics enter the environment,they will continue to release harmful metals into environment after aging,causing serious hazards.This study delved into the analysis and comparison of metal content of e-waste plastics,elucidating aging process and metal leaching behavior over a 112-day natural light exposure period.The findings underscored that metal content in recycled plastics surpassed that in their new counterparts.Specifically,Ti content in new plastics remained below 100 mg/kg,while recycled plastics exhibited Ti content surpassing 100 mg/kg threshold.Throughout prolonged natural light exposure,metals such as Zn,Ba and Sb demonstrated a heightened likelihood of release from electronic plastics in comparison to other metals.The aging process during light exposure led to fragmentation of electronic plastics,accompanied by a reduction in particle size.Notably,the particle size reduction was more pronounced in poly acrylonitrile butadiene styrene(ABS)and recycled ABS,experiencing reductions of 40µm and 85µm,respectively.This phenomenon was attributed to the presence of polybutadiene structural units,which proved more susceptible to aging.Along with the breaking of plastics,the ABS plastics released metal species such as Pb,Cd,Ni,Al that had not been detected in other plastics solutions.The collective evidence from this study suggested that ABS and recycled ABS electronic plastics might pose a heightened potential environmental risk compared to other electronic plastics.展开更多
As a new type of pollutant,microplastics have been widely detected in environments such as the ocean,lakes,atmosphere and soil.As a major sink for plastic waste,soil is particularly severely polluted.The current situa...As a new type of pollutant,microplastics have been widely detected in environments such as the ocean,lakes,atmosphere and soil.As a major sink for plastic waste,soil is particularly severely polluted.The current situation and hazards of microplastic pollution in agricultural soils in China are summarized,and the research progress of microplastic degradation and treatment is elaborated,providing a basis for further studies on soil microplastics.展开更多
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.
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.
文摘Microplastics are becoming well-known as chronic pollutants of terrestrial ecosystems,although their sources,dynamics of transportation,reliability of detection and ecological hazard are not evenly described.This review is a synthesis of the existing information about microplastics in soils,including analytical detection and characterization techniques,the major sources in the terrestrial environment,transport routes within the compartments and between compartments,and reported ecotoxicological consequences on soil biota,plants,and microbial communities.We also critically discuss the strengths and weaknesses of methodologies,making the distinction of sampling design differences,size detection limits,polymer identification methods,and quality assurance procedures on data comparability and uncertainty.An important outcome of this review is the systematic evaluation of the strength of evidence in three interrelated areas:measurement,environmental transport,and biological impacts,hence explaining which findings are strong and in which areas of research significant knowledge gaps still exist.We also suggest a conceptual framework that strongly connects the measurement uncertainty to the exposure estimation,interpretation of risk,and management relevance.This review uses mechanistic insights into transport and ecotoxicology alongside analysis constraints to add to the more comprehensive foundation of terrestrial risk assessment.Lastly,we determine research priorities,such as harmonized methodologies,realistic exposure scenarios,and cross-scale monitoring strategies,in order to assist in the science-based policies and mitigation action.
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support from the National Natural Science Foundation of China(Nos.22293011,T2341001)the Major Science and Technology Project of Anhui Province(202203a06020010).
文摘Epoxy resins are widely employed in wind turbine blades,drone rotors,and automotive interiors due to their excel-lent mechani-cal proper-ties and long service life.However,their insoluble and infusible cross-linked networks pose a significant re-cycling challenge,particularly with the impending retirement of the first generation of wind turbine blades.In this work,we reported a fully bio-based epoxy Vitrimer(FEP)incorporat-ing a dual-dynamic covalent network design and systematically investigated the influence of the 1,5,7-triazabicyclo[4.4.0]dec-5-ene(TBD)catalyst on its curing kinetics,thermal/mechan-ical properties,dynamic exchange behavior,and degradation performance in a mild alkaline solution.Compared to conventional epoxy resins,FEP exhibited superior tensile strength and elongation at break at an optimal TBD concentration(2 wt%),achieving an excellent strength-toughness balance.The presence of TBD accelerated the exchange rates of both disulfide and ester bonds,endowing FEP with notable stress relaxation at elevated tempera-tures.Moreover,FEP demonstrated complete dissolution in 1 mol/L NaOH within 6 h at 25℃.These results underscored the exceptional strength,toughness,and recyclability of FEP,positioning it as a promising,environmentally friendly matrix resin for next-generation appli-cations in the new energy sector.
基金the financial support from the National Natural Science Foundation of China(22293011,T2341001)the Major Science and Technology Project of Anhui Province(202203a06020010)+1 种基金the Horizontal Project Provided by Jiangsu Zhuogao New Materials Technology Co.,Ltd.(Td00923003H)Joint Laboratory by China Power Investment Ronghe New Energy Technology Co.,Ltd.and the Central Government Guiding Special Fund Project for Local Science and Technology Development(202407a12020008)。
文摘The structural design and performance characteristics of the diaphragm have a decisive impact on the safety and electrochemical performance of lithium-ion batteries(LIBs).However,traditional polyolefin diaphragms still face challenges in simultaneously improving the ion transport efficiency and thermal stability.Here,we report an in situ dynamic lithium compensation strategy for manufacturing a biobased furan aramid/ceramic diaphragm(BAS)with higher thermal stability and ion transport efficiency.Specifically,exchangeable carboxyl groups(–COOH)are introduced into the bio-based furan aramid(BA)framework,which are in situ converted into–COOLi groups to form lithium ions(Li^(+))transport channels,achieving dynamic compensation of active Li^(+).The dual transmission system of ion exchange and physical pore channels synergistically enhances the ionic conductivity of BAS to 1.536 mS cm^(-1).The high polarity structure of the furan ring and the electrolyte have excellent compatibility,significantly reducing the solid–liquid interfacial energy,making BAS have extremely high electrolyte wettability(contact angle of 0°).The BA amide group forms a multi-scale bonding network with the nano-ceramics.The BAS prepared by the water-coating process exhibits excellent thermal stability(with a thermal shrinkage rate of less than 1%after 1 h at 150℃).The LiFePO_(4)|Li half-cell assembled with BAS shows a capacity retention rate of up to 91.7%after 280 cycles at 1C,with a Coulomb efficiency of 99%,demonstrating excellent cycling stability.This design and development based on bio-materials provides a new approach for high safety and high energy density battery systems.
基金supported by the National Natural Sci-ence Foundation of China(Nos.U21A20288 and 21978280).
文摘Developing green and efficient methods to acquire lignocellulose-based chemicals with high added value is beneficial for facilitating green chemistry and sustainable development.The goal of this study is to demonstrate that bio-based benzaldehyde,a noteworthy high-value chemical,is able to be directionally prepared from lignocellulosic biomass.This new control-lable transformation was materialized by uniting catalytic-pyrolysis of lignocellulose to toluene intermediate and catalytic oxidation of toluene intermediate to bio-based benzalde-hyde.This work also developed a highly active magnetic catalyst(CoFe_(2)O_(4)@Biochar(HTR)),achieving 77.1%benzaldehyde selectivity and 46.7%benzaldehyde yield using this catalyst.It was found that introducing the biochar carrier into the cobalt iron composite metal oxide cat-alyst enhanced hydroxyl radical formation and bio-based benzaldehyde synthesis.Based on catalyst characterizations and hydroxyl radical analysis,potential reaction mechanism for bio-based benzaldehyde synthesis was proposed.This strategy may provide a beneficial pathway for developing high-value bio-based chemical(benzaldehyde)using renewable lignocellulosic biomass.
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.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(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 Key R&D Project in Shaanxi Province(No.2024GX-YBXM-371)Shaanxi Qinchuangyuan Scientists+Engineers Team Construction Project(2025QCY-KXJ-141).
文摘With the escalating global emphasis on environmental conservation and sustainable development,enhancing the service quality and durability of road surfaces and facilitating the green development of highways have commanded considerable attention.Bio-based polyurethane,on account of its remarkable physical and chemical properties,green,sustainable and renewable capacity,as well as its structural design capabilities,has drawn widespread attention and numerous studies have been carried out.It has gradually started to substitute traditional petroleum-based polyurethane materials in road engineering.Nevertheless,the application of bio-based polyurethane materials in road engineering remains in the exploratory phase.To stimulate the application research of bio-based polyurethane materials in road engineering and offer additional research directions,this paper reviews the research advancements of bio-based polyurethane materials and their applications in road engineering.The fundamental classification of bio-based polyurethane is introduced.The characteristics and challenges associated with various preparation methods for bio-based polyurethane are described.The influence of bio-based polyurethane on road engineering materials are analyzed.The evaluation indicators of bio-based polyurethane within the life cycle of road engineering are investigated.Finally,the development tendency towards in road engineering applications are forecasted.This paper provides a reference for the study of bio-based polyurethane materials in road engineering applications.
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.
基金supported by the National Natural Science Foundation of China(No.42077120)the Special Foundation for Taishan Scholar of Shandong Province(2023)the Project of Talent Introduction and Education Program of Youth Innovation Teams in Universities of Shandong Province(No.2021-05).
文摘Microplastics(MPs) are an emerging environmental pollutant and have penetrated the most remote and primitive areas. MPs degradation has received widespread attention. Manganese(Mn) is a highly reactive metal element in the environment, yet its contribution to MPs degradation remains unclear. Herein,we simulated the aging of polyethylene MPs with Mn(Ⅱ) under aqueous conditions at pH 5 and 8 for720 days. Mn greatly promoted the MPs degradation, and the average particle sizes of polyethylene MPs were reduced from 9.2 μm to 5.9 μm after aging at pH 5 under light irradiation for 720 days. Plenty of oxygen-containing groups were generated on the MPs surfaces, and the carbonyl index remarkably increased, reaching four times that of the control without adding Mn. Mechanistically, the adsorbed Mn(Ⅱ)on the MPs surfaces were primarily oxidized to high-valence Mn(Ⅲ/Ⅳ) profited from the photoproduced radicals, followed by the MPs oxidation via Mn(Ⅲ/Ⅳ), which were reduced to regenerate Mn(Ⅱ), initiating a new redox cycling. During the degradation, dissolved organic matter was continuously released, mainly including bisphenol A and phthalic acid esters. Mn acts as a catalyst to accelerate the MPs degradation by redox cycling. Our results provide a new insight into the mechanisms of abiotic degradation of MPs in aqueous environments.
基金supported by the Major Projects of Natural Science Research for University and Colleges in Jiangsu Province(No.21KJA240001)the Key Research and Development Program of Jiangsu Province(No.BE2018348)+2 种基金partially by the Jiangsu Agricultural Science and Technology Innovation Fund(No.CX(22)3199)the Projects for the High-Quality Development of Fishery Industry of Yancheng City(No.YCSCYJ20210014)supported financially by the projects for‘Six Talents’of Jiangsu Province(No.NY115)。
文摘Microplastics(MPs)pollution has become a worldwide environmental problem.The study about the effects of microplastics on fish,especially on the fish immune system is limited.In the present study,the transcriptome of soiny mullet(Liza haematocheila)larvae at 7 d and 14 d post 0.5μm MPs exposure were analyzed by DNBSEQ platform.A total number of 96585 unigenes were obtained with average length of 1925 bp.Approximately 72.48%(70004),76.80%(74176),and 62.94%(60787)unigenes were matched with the annotated sequences for non-redundant(NR),NCBI nucleotide(NT)and Swissprot database,respectively.Compared with control group,1336 differently expressed genes(DEGs)were identified at 7 d post MPs exposure.As the MPs exposure time extended to 14 d,the number of DEGs in the MPs exposure group reached to 3561.Further,KEGG enrichment analysis revealed that several immune-related pathways,such as interleukin(IL)-17 signaling pathway,tumor necrosis factor(TNF)signaling pathway,were affected by MPs exposure.In addition,apoptosis signaling pathway was also enriched under MPs exposure.These results demonstrated that MPs can alter the expressions of immune-related genes,providing basis for understanding the immune toxicity of MPs on fish and other vertebrates.
基金the Natural Science Foundation of Guangdong Province(No.2021B1515020041)the National Natural Science Foundation of China(No.42277403)+4 种基金the Projects of International Cooperation and Exchange of the National Natural Science Foundation of China(NSFC-UNEP)(No:32261143459)the Guangdong Provincial Key Laboratory of Soil and Groundwater Pollution Control(No.2023B1212060002)the Guangdong Major Project of Basic and Applied Basic Research(No.2023B0303000024)the High-level University Special Fund(No.G03050K001)the Research Projects of the General Administration of Customs(No.2022HK060)for financial support.
文摘As the main component of electronic products,plastics contain complex and diverse metal additives.Recycling process is not conducive to stable existence of metal additives in electronic plastics.Once the e-waste plastics enter the environment,they will continue to release harmful metals into environment after aging,causing serious hazards.This study delved into the analysis and comparison of metal content of e-waste plastics,elucidating aging process and metal leaching behavior over a 112-day natural light exposure period.The findings underscored that metal content in recycled plastics surpassed that in their new counterparts.Specifically,Ti content in new plastics remained below 100 mg/kg,while recycled plastics exhibited Ti content surpassing 100 mg/kg threshold.Throughout prolonged natural light exposure,metals such as Zn,Ba and Sb demonstrated a heightened likelihood of release from electronic plastics in comparison to other metals.The aging process during light exposure led to fragmentation of electronic plastics,accompanied by a reduction in particle size.Notably,the particle size reduction was more pronounced in poly acrylonitrile butadiene styrene(ABS)and recycled ABS,experiencing reductions of 40µm and 85µm,respectively.This phenomenon was attributed to the presence of polybutadiene structural units,which proved more susceptible to aging.Along with the breaking of plastics,the ABS plastics released metal species such as Pb,Cd,Ni,Al that had not been detected in other plastics solutions.The collective evidence from this study suggested that ABS and recycled ABS electronic plastics might pose a heightened potential environmental risk compared to other electronic plastics.
基金Supported by Hebei Geological Exploration Fund Project(13000024P00B04-410056L).
文摘As a new type of pollutant,microplastics have been widely detected in environments such as the ocean,lakes,atmosphere and soil.As a major sink for plastic waste,soil is particularly severely polluted.The current situation and hazards of microplastic pollution in agricultural soils in China are summarized,and the research progress of microplastic degradation and treatment is elaborated,providing a basis for further studies on soil microplastics.
