The past several decades witnessed tremendous success in controlling global plastic pollution,but most of these achievements do not involve recycling the plastic waste.Herein,we propose a recycling strategy of using p...The past several decades witnessed tremendous success in controlling global plastic pollution,but most of these achievements do not involve recycling the plastic waste.Herein,we propose a recycling strategy of using polyvinyl chloride(PVC) wastes to remove copper ions(Cu_(2+)) from electroplating wastewater for microbial control during wound healing and food preservation.The PVC wastes were recovered and crosslinked by the assistance of diethylenetriamine(DETA),which offered multiple active sites to extract Cu_(2+)ions from electroplating wastewater and in situ reduce to copper nanoparticles(CuNPs) containing crystalline Cu and Cu_(2)O.The obtained composites(i.e.,PVC-DETA@CuNPs) performed excellent antibacterial efficacies(99.999%) against Escherichia coli(E.coli) by disrupting bacterial cell membranes through contact-killing action and oxidative stress.After a series of biological evaluations on wound mice,PVC-DETA@-CuNPs exhibited promising potential in resisting wound bacterial infection,accelerating the healing process,and promoting epithelial regeneration.Interestingly,PVCDETA@CuNPs film was evidenced to delay the spoilage process of strawberries and extend their shelf life by combating with food-borne pathogens.This study presents a recycling approach towards waste reuse and the development of innovative antibacterial materials for microbial control.展开更多
The widespread use of plastic waste has caused significant environmental pollution,becoming a focal point of global concern,particularly the challenge of dechlorination in mixed plastic waste.Selective dissolution is ...The widespread use of plastic waste has caused significant environmental pollution,becoming a focal point of global concern,particularly the challenge of dechlorination in mixed plastic waste.Selective dissolution is a promising plastic chemical recycling technology that offers benefits such as simple processes,convenient operation,and recyclable solvents.However,selecting suitable solvents remains a challenge.This study establishes a virtual solvent database containing 530 common inorganic and organic solvents.By calculating theσ-profile of polyvinyl chloride(PVC)and polyethylene(PE)models using quantum mechanical calculations and employing the conductor-like screening model for real solvents(COSMO-RS)method,the solubility performance of these solvents for PVC and PE at different temperatures was predicted.The results demonstrate the high accuracy of the COSMO-RS method in predicting solubility.By comparing the solubility differences between PVC and PE in different solvents,a series of solvents suitable for selectively removing PVC from mixed plastics were identified,for example,N-methyl-2-pyrrolidone(NMP),dimethyl sulfoxide(DMSO),tetrahydrofuran(THF),and N,Ndimethylacetamide(DMAc).This method provides a novel solution to the solvent selection challenge in plastic chemical recycling,potentially shortening the research and development period,reducing experimental costs,and promoting the development of green and refined waste plastic recycling processes.展开更多
Background:Studies have shown that individuals who receive early treatment for rheumatoid arthritis(RA)are more likely to approach life positively,avoiding joint damage and the need for joint replacement surgery.The d...Background:Studies have shown that individuals who receive early treatment for rheumatoid arthritis(RA)are more likely to approach life positively,avoiding joint damage and the need for joint replacement surgery.The diagnosis of early rheumatoid arthritis(ERA)is crucial for effective treatment and prognosis of patients.Urine,as a diagnostic medium,offers the advantages of non-invasive diagnosis.Urinary metabolites can serve as biomarkers for diagnosis,prognosis,and risk prediction,improving specificity and accuracy.Methods:We recruited 37 ERA patients with a history of less than 3 months and a score of 6,26 osteoarthritis(OA)patients,and 30 healthy controls(HC).Urine samples were collected for 16S rRNA sequencing,and untargeted liquid chromatography-mass spectrometry(LC-MS)was used to detect metabolites.Bioinformatics approaches were employed to identify pathogenic metabolites as specific risk factors for ERA precisely.Results:2-methylnaphthalene was identified as a biomarker for ERA in urine.Prevotella,a major part of the urinary microbiome in ERA patients,exhibited a positive correlation with 2-methylnaphthalene.Notably,there were significant variations in urine metabolites among patients with ERA,OA,and HC.2-Methylnaphthalene was found to be significantly enriched in ERA.Besides,inflammatory factors were elevated in ERA patients.The research further demonstrated a positive correlation between rheumatoid factor(RF),erythrocyte sedimentation rate(ESR),and C-reactive protein(CRP)and the metabolite 2-methylnaphthalene.Conclusion:The urine metabolite 2-methylnaphthalene can be a risk factor for early urinary tract infections and may contribute to accurately screening early-risk metabolites in ERA.展开更多
激光雷达(light detection and ranging,LiDAR)作为一门新兴的主动遥感技术,近年来由于在提取和反演森林参数水平上不断提高,被越来越多地应用于动物生态学研究中。本文通过整理和搜集国内外文献,对激光雷达的技术特点及其在森林参数提...激光雷达(light detection and ranging,LiDAR)作为一门新兴的主动遥感技术,近年来由于在提取和反演森林参数水平上不断提高,被越来越多地应用于动物生态学研究中。本文通过整理和搜集国内外文献,对激光雷达的技术特点及其在森林参数提取和动物生境上的研究进展进行综述,指出当前基于LiDAR的森林参数反演算法主要服务于森林资源调查或林学研究,缺少对动物生态或生理意义相关的参数量化信息。目前该技术在国内的动物生态学方面的应用较少,尚未见文章发表。通过总结国外学者的研究,分别从动物生境选择与三维森林结构的关系、栖息地立体生境制图、生物多样性评估和物种分布模型预测三个方面综述了LiDAR在动物生态学研究中的应用现状。相比传统方法,LiDAR技术提供的高精度三维结构信息,能够显著提高动物生境质量的评估、生物多样性的监测水平和物种分布模型的评价精度,有利于从机理上加深对物种生境选择和集群过程的理解。但目前LiDAR技术的应用主要集中在对已知的生态关系研究,尤其是冠层结构与动物分布的关系,缺少对林下层生活的动物生境质量和生物多样性的监测和评估,同时很多有关动物生存和繁衍与立体生境的关系研究有待从LiDAR数据中进一步挖掘分析。未来应加强对森林林下层三维信息的提取,提高林下层动物生境质量和生物多样性的监测水平,同时建立适用于动物生态和生理意义相关的参数,为动物生境质量和生物多样性的评估提供标准的量化指标。展开更多
The combination of Ce6,an acknowledged photosensitizer,and TPL,a natural anticancer agent,has been demonstrated as a useful strategy to reinforce the tumor growth suppression,as well as decrease the systemic side effe...The combination of Ce6,an acknowledged photosensitizer,and TPL,a natural anticancer agent,has been demonstrated as a useful strategy to reinforce the tumor growth suppression,as well as decrease the systemic side effects compared with their monotherapy.However,in view of the optimal chemo-photodynamic combination efficiency,there is still short of the feasible nanovehicle to steadily co-deliver Ce6 and TPL,and stimuli-responsively burst release drugs in tumor site.Herein,we described the synergistic antitumor performance of a pH-sensitive supramolecular nanosystem,mediated by the host–vip complexing betweenβ-CD and acid pH-responsive amphiphilic co-polymer mPEG-PBAE-mPEG,showing the shell–core structural micelles with the tightβ-CD layer coating.Both Ce6 and TPLwere facilely co-loaded into the spherical supramolecular NPs(TPL+Ce6/NPs)by one-step nanoprecipitation method,with an ideal particle size(156.0 nm),acid pH-responsive drug release profile,and enhanced cellular internalization capacity.In view of the combination benefit of photodynamic therapy and chemotherapy,as well as co-encapsulation in the fabricated pH-sensitive supramolecular NPs,TPL+Ce6/NPs exhibited significant efficacy to suppress cellular proliferation,boost ROS level,lower MMP,and promote cellular apoptosis in vitro.Particularly,fluorescence imaging revealed that TPL+Ce6/NPs preferentially accumulated in the tumor tissue area,with higher intensity than that of free Ce6.As expected,upon 650-nm laser irradiation,TPL+Ce6/NPs exhibited a cascade of amplified synergistic chemo-photodynamic therapeutic benefits to suppress tumor progression in both hepatoma H22 tumor-bearingmice and B16 tumor-bearingmice.More importantly,lower systemic toxicitywas found in the tumor-bearingmice treated with TPL+Ce6/NPs.Overall,the designed supramolecular TPL+Ce6/NPs provided a promising alternative approach for chemo-photodynamic therapy in tumor treatment.展开更多
Although multitudinous nanoscale drug-delivery systems(DDSs)have been recommended to improve anti-ulcerative colitis(UC)outcomes,to enhance the mucoadhesion of nanosystems on the colon and specifically release the loa...Although multitudinous nanoscale drug-delivery systems(DDSs)have been recommended to improve anti-ulcerative colitis(UC)outcomes,to enhance the mucoadhesion of nanosystems on the colon and specifically release the loaded drugs in response to the colon micro-environment would be critical factors.The application of curcumin(Cur),an acknowledged anti-UC phytochemical compound,for UC therapy requires more efficient nano-carriers to improve its therapeutic outcome.Herein,we developed the colon-targeted nano-micelles with mucoadhesive effect and Azo reductase-triggered drug release profiles for Cur delivery in UC treatment.Specifically,the amphiphilic block polymer containing the Azo-reductase sensitive linkage(PEG-Azo-PLGA),and catechol-modified TPGS(Cat-TPGS)were synthesized respectively.Based on the self-assembly of the mixed polymers,Cur-micelles(142.7±1.7 nm of average size,72.36%±1.54%of DEE)were obtained.Interestingly,the Cur-micelles exhibited the Azo-reductase sensitive particle dissociation and drug release,the enhanced cellular uptake and the prolonged retention on colonic mucosa,mediated by the strong mucoadhesion of catechol structure.Ultimately,Cur-micelles significantly mitigated colitis symptoms and accelerated colitis repair in DSS-treated mice by regulating the intestinal flora and the levels of pro-inflammatory factors(MPO,IL-6,IL-1β,and TNF-α)related to TLR4/MyD88/NF-κB signaling pathway.This work provides an effective drug delivery strategy for anti-UC drugs by oral administration.展开更多
Cold atmospheric plasma shows a satisfactory ability to inactivate bacterial biofilms that are difficult to remove using conventional methods in some cases. However, the researches on the inactivation mechanism are no...Cold atmospheric plasma shows a satisfactory ability to inactivate bacterial biofilms that are difficult to remove using conventional methods in some cases. However, the researches on the inactivation mechanism are not quite sufficient. Poly-β-1–6-N-acetylglucosamine(PNAG),which is one of the important components in some biofilms, was used as the research subject,and the related mechanism of action triggered by different concentrations of the OH in plasma was studied using reactive molecular dynamics simulations. The results showed that OH radicals could not only trigger the hydrogen abstraction reaction leading to cleavage of the PNAG molecular structure, but undergo an OH addition reaction with PNAG molecules. New reaction pathways appeared in the simulations as the OH concentration increased, but the reaction efficiency first increased and then decreased. The simulation study in this paper could, to some extent, help elucidate the microscopic mechanism of the interaction between OH radicals in plasma and bacterial biofilms at the atomic level.展开更多
Increasing concern with regard to food safety in the presence of pesticide residues(PRs) on the surface of agricultural products has resulted in the rapid development of practical degrading technologies for correspond...Increasing concern with regard to food safety in the presence of pesticide residues(PRs) on the surface of agricultural products has resulted in the rapid development of practical degrading technologies for corresponding PRs. In this paper, an unconventional method of degrading pesticides, non-thermal atmospheric plasma(NTAP), was proposed to degrade the avermectin(AVM) in aqueous solution. Optical emission spectroscopy shows that NTAP, consisting of filamentary streamers, contains a variety of reactive oxygen species(ROS) that may interact with AVM. The high-performance liquid chromatography(HPLC)-MS/MS results indicate that the efficiency of AVM degradation seriously depends on multiple operation parameters of the NTAP,including the applied voltage, treatment time and gas flow rate. The maximum degradation rate of AVM was observed to be 97.47% after 240 s exposure under NTAP with an applied voltage of 18 kV and gas flow rate of 1 l min-1. Molecular dynamics simulation based on a reactive force field for the interaction between O(ground state atomic oxygen) and AVM was performed to analyze the underpinning mechanisms. The simulation result shows the possible pathways of the NTAPgenerated O degrading AVM by destroying the glycosyl group or fracturing the ester group.展开更多
Mineral carbonation is a promising CO_(2) sequestration strategy that can utilize industrial wastes to convert CO_(2) into high-value CaCO_(3).This review summarizes the advancements in CO_(2) mineralization using typ...Mineral carbonation is a promising CO_(2) sequestration strategy that can utilize industrial wastes to convert CO_(2) into high-value CaCO_(3).This review summarizes the advancements in CO_(2) mineralization using typical industrial wastes to prepare ultrafine CaCO_(3).This work surveys the mechanisms of CO_(2) mineralization using these wastes and its capacities to synthesize CaCO_(3),evaluates the effects of carbonation pathways and operating parameters on the preparation of CaCO_(3),analyzes the current industrial application status and economics of this technology.Due to the large amount of impurities in solid wastes,the purity of CaCO_(3) prepared by indirect methods is greater than that prepared by direct methods.Crystalline CaCO_(3) includes three polymorphs.The polymorph of CaCO_(3) synthesized by carbonation process is determined the combined effects of various factors.These parameters essentially impact the nucleation and growth of CaCO_(3) by altering the CO_(2) supersaturation in the reaction system and the surface energy of CaCO_(3) grains.Increasing the initial pH of the solution and the CO_(2)flow rate favors the formation of vaterite,but calcite is formed under excessively high pH.Vaterite formation is favored at lower temperatures and residence time.With increased temperature and prolonged residence time,it passes through aragonite metastable phase and eventually transforms into calcite.Moreover,polymorph modifiers can decrease the surface energy of CaCO_(3) grains,facilitating the synthesis of vaterite.However,the large-scale application of this technology still faces many problems,including high costs,high energy consumption,low calcium leaching rate,low carbonation efficiency,and low product yield.Therefore,it is necessary to investigate ways to accelerate carbonation,optimize operating parameters,develop cost-effective agents,and understand the kinetics of CaCO_(3) nucleation and crystallization to obtain products with specific crystal forms.Furthermore,more studies on life cycle assessment(LCA)should be conducted to fully confirm the feasibility of the developed technologies.展开更多
Natural radioactivity is very important for the assessment of the marine sand property and usability. By using gamma spectrometry, the concentration of the natural radionuclides 226Ra, 232Th and 40K have been measured...Natural radioactivity is very important for the assessment of the marine sand property and usability. By using gamma spectrometry, the concentration of the natural radionuclides 226Ra, 232Th and 40K have been measured in marine sand deposits from Liaodong Bay (LDB), North Yellow Sea (NYS), Zhoushan area (ZS), Taiwan Shoal (TS) and Pearl River Mouth (PR), offshore China, which are potential marine sand mining areas. The radiation activity equivalent (Raeq), indoor gamma absorbed dose rate (DR), annual effective dose (HR), alpha index (Ia), gamma index (Ig), external radiation hazard index (Hex), internal radiation hazard index (Hin), representative level index (RLI), excess lifetime cancer risk (ELCR) and annual gonadal dose equivalent (AGDE) associated with the natural radionuclides are calculated to assess the radiation hazard of the natural radioactivity in the marine sands offshore China. From the analysis, it is found that these marine sands are safe for the constructions. The Pearson correlation coefficient reveals that the 226Ra distribution in the marine sands offshore China is controlled by the variation of the 40K concentration. Principal component analysis (PCA) yields a two-component representation of the entire data from the marine sands, wherein 98.22% of the total variance is explained. Our results provide good baseline data to expand the database of radioactivity of building materials in China and all over the world.展开更多
Objective To investigate the effect of propofol on brain regions at different sedation levels and the association between changes in brain region activity and loss of consciousness using blood oxygen level-dependent f...Objective To investigate the effect of propofol on brain regions at different sedation levels and the association between changes in brain region activity and loss of consciousness using blood oxygen level-dependent functional magnetic resonance imaging(BOLD-f MRI) and bispectral index(BIS) monitoring.Methods Forty-eight participants were enrolled at Peking Union Medical College Hospital from October 2011 to March 2012 and randomly assigned to a mild or a deep sedation group using computergenerated random numbers.Preliminary tests were performed a week prior to scanning to determine target effect site concentrations based on BIS and concomitant Observer's Assessment of Alertness/Sedation scores while under propofol.Within one week of the preliminary tests where propofol dose-response was established,BOLD-f MRI was conducted to examine brain activation with the subject awake,and with propofol infusion at the sedation level.Results Mild propofol sedation inhibited left inferior parietal lobe activation.Deep sedation inhibited activation of the left insula,left superior temporal gyrus,and right middle temporal gyrus.Compared with mild sedation,deep propofol sedation inhibited activation of the left thalamus,precentral gyrus,anterior cingulate,and right basal nuclei.Conclusion Mild and deep propofol sedation are associated with inhibition of different brain regions,possibly explaining differences in the respective loss of consciousness processes.展开更多
Tartary buckwheat(Fagopyrum tataricum)is an important pseudocereal feed crop with medicinal and nutritional value.Drought is one of the main causes of reduced growth and yield in these plants.We investigated the growt...Tartary buckwheat(Fagopyrum tataricum)is an important pseudocereal feed crop with medicinal and nutritional value.Drought is one of the main causes of reduced growth and yield in these plants.We investigated the growth,physiological,and metabolic responses of the widely promoted Tartary buckwheat variety Chuan Qiao No.1 to polyethylene glycol(PEG)-mediated drought stress.Drought significantly decreased shoot length,shoot biomass and relative water content.Root length,malondialdehyde content,electrolyte leakage,activities of superoxide dismutase,peroxidase,catalase and amylase,and contents of soluble sugar,soluble protein and proline were increased by PEG-mediated drought.Untargeted metabolomics analysis identified 32 core metabolites in seedlings subjected to PEG-mediated drought,16 of which increased—including quercetin,isovitexin,cyanidin 3-O-beta-D-glucoside,L-arginine,and glycerophosphocholine,while the other 16 decreased—including 3-methoxytyramine,2,6-diaminopimelic acid,citric acid,UDP-alpha-D-glucose,adenosine,keto-D-fructose.The 32 core metabolites were enriched in 29 metabolic pathways,including lysine biosynthesis,citrate(TCA)cycle,anthocyanin biosynthesis,and aminoacyl-tRNA biosynthesis.Among them,taurine and hypotaurine metabolism,flavor and flavor biosynthesis,indole alkaline biosynthesis,and alanine,aspartate and glutamate metabolism were the four main metabolic pathways affected by drought.Our findings provide new insights into the physiological and metabolic response mechanisms of Tartary buckwheat to drought stress.展开更多
Drought can limit the growth and reduce the yield of crops,but the safe and effective bio-approach to improve the drought resistance of crops is very little.We conducted an experiment in which we monitored the effects...Drought can limit the growth and reduce the yield of crops,but the safe and effective bio-approach to improve the drought resistance of crops is very little.We conducted an experiment in which we monitored the effects of polysaccharide from the endophyte Bionectria sp.Fat6 on the growth of Tartary buckwheat(Fagopyrum tataricum(L.)Gaertn)seedlings under control and drought-stressed conditions by determining gas exchange,photosynthesis parameters,photosynthetic pigment contents,and metabolite accumulation.Results indicated that the polysaccharide from endophyte stimulated plant growth and increased the aboveground biomass,root mass,and root/shoot ratio of Tartary buckwheat.Application of the polysaccharide to drought-stressed plants resulted in a significant increase in the net photosynthetic rate,stomatal conductance,and transpiration rate of Tartary buckwheat and decreased the intercellular CO_(2) concentration.The contents of chlorophyll a,chlorophyll b,chlorophyll a+b,and carotenoids in leaves were higher in polysaccharide-treated seedlings than that in control.Polysaccharide notably increased the soluble protein and proline content and decreased the malondialdehyde content in Tartary buckwheat leaves.The endophytic polysaccharide may protect Tartary buckwheat against drought by improving leaf gas exchange and photosynthetic capacity,and altering concentrations of protective metabolites.Together,these changes may compensate for the negative impacts of drought stress on the growth of Tartary buckwheat.Thus,the polysaccharide from the endophyte Bionectria sp.Fat6 may be an effective biotic elicitor and a promising bio-approach to improve Tartary buckwheat production worldwide.展开更多
Aluminum (Al) toxicity is a considerable factor limiting crop yield and biomass in acidic soil. Tartary buckwheatgrowing in acidic soil may suffer from Al poisoning. Here, we investigated the influence of Al stress on...Aluminum (Al) toxicity is a considerable factor limiting crop yield and biomass in acidic soil. Tartary buckwheatgrowing in acidic soil may suffer from Al poisoning. Here, we investigated the influence of Al stress on the growthof tartary buckwheat seedling roots, and the alleviation of Al stress by silicon (Si), as has been demonstrated inmany crops. Under Al stress, root growth (total root length, primary root length, root tips, root surface area, androot volume) was significantly inhibited, and Al and malondialdehyde (MDA) accumulated in the root tips. At thesame time, catalase (CAT) and ascorbate peroxidase activities, polyphenols, flavonoids, and 1,1-diphenyl-2-picrylhydrazyl(DPPH) and 2,2′-azinobis-(3-ethylbenzthiazoline-6-sulphonate) (ABTS) free-radical scavenging abilitywere significantly decreased. After the application of Si, root growth, Al accumulation, and oxidative damage wereimproved. Compared to Al-treated seedlings, the contents of ·O2− and MDA decreased by 29.39% and 25.22%,respectively. This was associated with Si-induced increases in peroxidase and CAT enzyme activity, flavonoidcompounds, and free-radical scavenging (DPPH and ABTS). The application of Si therefore has positive effectson Al toxicity in tartary buckwheat roots by reducing Al accumulation in the roots and maintaining oxidationhomeostasis.展开更多
Primary open-angle glaucoma(POAG),a leading cause of irreversible blindness,involves complex neurodegeneration in which the contribution of systemic immunity remains enigmatic.Here,we dissect the circulating immune la...Primary open-angle glaucoma(POAG),a leading cause of irreversible blindness,involves complex neurodegeneration in which the contribution of systemic immunity remains enigmatic.Here,we dissect the circulating immune landscape in POAG patients via high-resolution single-cell RNA sequencing of~1.4 million peripheral blood mononuclear cells(PBMCs)from 110 patients and 110 controls of Chinese ancestry.We revealed significant immune remodeling in POAG,characterized by increased CD4+T lymphocytes and myeloid cells and impaired cytolytic potential,as evidenced by reduced cell proportions of terminally differentiated CD8+GZMK+T cells and NK cells.Transcriptomic analysis revealed a sophisticated dual transcriptional landscape in which both proinflammatory and neuroprotective signaling pathways coexist across multiple immune cell lineages.While TNF and IFNG pathway genes were broadly downregulated,specific inflammatory activation components and neuroprotective genes were upregulated in distinct cell populations,suggesting that POAG represents a complex immunometabolic syndrome characterized by a dysregulated balance between inflammatory and neuroprotective signaling.Cell type-specific eQTL mapping and SMR analysis revealed that POAG genetic risk loci exert their effects through immune gene regulation in specific PBMC subsets.Functional validation using Ifng-/-and Tnf+/-mice in an LPS/NMDA-induced retinal injury model,which mirrored the immune alterations observed in human POAG,demonstrated that genetic deficiency in these pathways markedly exacerbated retinal ganglion cell loss and visual pathway deficits.Our study establishes a crucial link between systemic immune dysregulation-specifically the disrupted balance between inflammatory and neuroprotective signaling-and retinal health,highlighting the importance of restoring this balance for future POAG therapeutic strategies.展开更多
Gear pitting fault is a common issue in gear systems,affecting transmission efficiency and potentially leading to severe equipment shutdowns.Effective diagnosis enhances reliability,reduces maintenance costs,and exten...Gear pitting fault is a common issue in gear systems,affecting transmission efficiency and potentially leading to severe equipment shutdowns.Effective diagnosis enhances reliability,reduces maintenance costs,and extends equipment lifespan.However,existing deep learning based methods often neglect the inherent structure of temporal vibration signals and fail to address domain variations,resulting in poor generalization and performance.To overcome these limitations,we propose a novel approach based on domain-independent features.Vibration signals are mapped to time-frequency representations via short-time Fourier transform,and dependencies between different frequencies are effectively captured using a Transformer encoder.The proposed method incorporates a feature decoupling structure that combines singular value decomposition and Pearson correlation coefficient to extract low-rank approximations of domain-related and pitting-related features,while quantifying their correlation.This approach mitigates feature degradation in constructing domain-independent features.Additionally,the weighted LinSoftmax function is introduced as a replacement for the traditional Softmax,leading to a more stable optimization target and improved model accuracy,with a distance-based penalty weight focusing on significant prediction errors.Experiments on the 2023 PHM Data Challenge dataset demonstrate the effectiveness of the proposed method,achieving a mean absolute error of 0.11,an accuracy of 92.32%,and a fault tolerance accuracy of 98.02%.展开更多
High wind power penetration(WPP)is challenging system frequency stability.As a countermeasure,virtual inertia controls are introduced,utilizing kinetic energy(KE)stored in wind turbine generators(WTGs)for frequency re...High wind power penetration(WPP)is challenging system frequency stability.As a countermeasure,virtual inertia controls are introduced,utilizing kinetic energy(KE)stored in wind turbine generators(WTGs)for frequency regulation.Without restoration,generation efficiency of WTGs will be degraded after inertia contribution.To counter this issue,we propose an inertia control scheme of a doubly fed induction generator(DFIG),aiming at achieving dynamic inertia recovery regarding both KE and DC link energy.An asymmetrical droop control,referred to as the rate of change of frequency(RoCoF),is proposed for KE management.The upper boundary of droop gain is extended to give full play to converters and is revised,considering the system frequency state,to counter positive feedback issues induced by reversible gain regulation,which is restricted by KE to ensure stable operations as well.The inertial DC energy needed to cooperate with KE control regarding countering small fluctuations,is improved with an orderly recovery behavior.Case studies are conducted under dynamic wind conditions and the results indicate that with our proposed scheme,the ability of dynamic inertia recovery can be obtained,bringing DFIG higher generation efficiency and more adequate operation margin for sustained regulation.Essentially,the inertial frequency response and fluctuation suppression ability is well maintained.展开更多
A two-photon ratiometric fluorescent sensor for Cu^+ in endoplasmic reticulum(ER), CNSB, was developed via coumarin/ASBD integration based on FRET mechanism. In solution, CNSB shows reversible, highly-specific ratiome...A two-photon ratiometric fluorescent sensor for Cu^+ in endoplasmic reticulum(ER), CNSB, was developed via coumarin/ASBD integration based on FRET mechanism. In solution, CNSB shows reversible, highly-specific ratiometric response to Cu^+ .Moreover, CNSB exhibits suitable K_d value, suggesting the possibility of detecting Cu^+ in the living cells. The probe can enter the MCF-7 cells easily and specifically locates in the ER. The highly specific ratiometric response of CNSB toward Cu^+ in MCF-7 cells provides the sensor the capacity to visualize both exogenous and endogenous Cu^+ in the ER via fluorescence imaging.Next, CNSB was utilized to detect the fluctuation and distribution of Cu^+ under ER stress in MCF-7 cells, which confirmed directly the relationship between Cu^+ enhancement and ER stress. Meanwhile, the two-photon ability of coumarin facilitated the sensor to visualize Cu^+ fluctuation via two-photon fluorescence imaging. In addition, the spatial distribution of Cu^+ in the heart slice of the 14-day-old rat was demonstrated using CNSB. This study demonstrates the promising potential of CNSB in clarifying the Cu^+ -dependent signaling in the ER stress-related diseases.展开更多
基金financially supported by the National Energy R&D Center of Petroleum Refining Technology (RIPP,SINOPEC)the National Natural Science Foundation of China (Nos.22062017 and 22164015)+2 种基金the Natural Science Foundation of Inner Mongolia Autonomous Region (Nos.2024ZD10 and 2023QN02011)the Program of Higher-Level Talents of Inner Mongolia University (No.10000-22311201/035)the Research Program of science and technology at Universities of Inner Mongolia Autonomous Region (No.NJZZ23091)
文摘The past several decades witnessed tremendous success in controlling global plastic pollution,but most of these achievements do not involve recycling the plastic waste.Herein,we propose a recycling strategy of using polyvinyl chloride(PVC) wastes to remove copper ions(Cu_(2+)) from electroplating wastewater for microbial control during wound healing and food preservation.The PVC wastes were recovered and crosslinked by the assistance of diethylenetriamine(DETA),which offered multiple active sites to extract Cu_(2+)ions from electroplating wastewater and in situ reduce to copper nanoparticles(CuNPs) containing crystalline Cu and Cu_(2)O.The obtained composites(i.e.,PVC-DETA@CuNPs) performed excellent antibacterial efficacies(99.999%) against Escherichia coli(E.coli) by disrupting bacterial cell membranes through contact-killing action and oxidative stress.After a series of biological evaluations on wound mice,PVC-DETA@-CuNPs exhibited promising potential in resisting wound bacterial infection,accelerating the healing process,and promoting epithelial regeneration.Interestingly,PVCDETA@CuNPs film was evidenced to delay the spoilage process of strawberries and extend their shelf life by combating with food-borne pathogens.This study presents a recycling approach towards waste reuse and the development of innovative antibacterial materials for microbial control.
基金financially supported by SINOPEC Research Institute of Petroleum Processing Co.,Ltd.the National Natural Science Foundation of China(22302220)+2 种基金the Shanxi Province Science Foundation for Youth(202203021222403)Funding support was also received from the Synfuels China Co.,Ltd.the Institute of Coal Chemistry,Chinese Academy of Sciences。
文摘The widespread use of plastic waste has caused significant environmental pollution,becoming a focal point of global concern,particularly the challenge of dechlorination in mixed plastic waste.Selective dissolution is a promising plastic chemical recycling technology that offers benefits such as simple processes,convenient operation,and recyclable solvents.However,selecting suitable solvents remains a challenge.This study establishes a virtual solvent database containing 530 common inorganic and organic solvents.By calculating theσ-profile of polyvinyl chloride(PVC)and polyethylene(PE)models using quantum mechanical calculations and employing the conductor-like screening model for real solvents(COSMO-RS)method,the solubility performance of these solvents for PVC and PE at different temperatures was predicted.The results demonstrate the high accuracy of the COSMO-RS method in predicting solubility.By comparing the solubility differences between PVC and PE in different solvents,a series of solvents suitable for selectively removing PVC from mixed plastics were identified,for example,N-methyl-2-pyrrolidone(NMP),dimethyl sulfoxide(DMSO),tetrahydrofuran(THF),and N,Ndimethylacetamide(DMAc).This method provides a novel solution to the solvent selection challenge in plastic chemical recycling,potentially shortening the research and development period,reducing experimental costs,and promoting the development of green and refined waste plastic recycling processes.
基金financially supported by the Natural Science Foundation of China(No.82003766)Taishan Scholars Program(NO.tsqn202211219)+1 种基金the Key Research and Development Project of Shandong Province(No.2021ZDSYS27)Shandong Province nature fund surface project(Grant No.ZR2024MH088)。
文摘Background:Studies have shown that individuals who receive early treatment for rheumatoid arthritis(RA)are more likely to approach life positively,avoiding joint damage and the need for joint replacement surgery.The diagnosis of early rheumatoid arthritis(ERA)is crucial for effective treatment and prognosis of patients.Urine,as a diagnostic medium,offers the advantages of non-invasive diagnosis.Urinary metabolites can serve as biomarkers for diagnosis,prognosis,and risk prediction,improving specificity and accuracy.Methods:We recruited 37 ERA patients with a history of less than 3 months and a score of 6,26 osteoarthritis(OA)patients,and 30 healthy controls(HC).Urine samples were collected for 16S rRNA sequencing,and untargeted liquid chromatography-mass spectrometry(LC-MS)was used to detect metabolites.Bioinformatics approaches were employed to identify pathogenic metabolites as specific risk factors for ERA precisely.Results:2-methylnaphthalene was identified as a biomarker for ERA in urine.Prevotella,a major part of the urinary microbiome in ERA patients,exhibited a positive correlation with 2-methylnaphthalene.Notably,there were significant variations in urine metabolites among patients with ERA,OA,and HC.2-Methylnaphthalene was found to be significantly enriched in ERA.Besides,inflammatory factors were elevated in ERA patients.The research further demonstrated a positive correlation between rheumatoid factor(RF),erythrocyte sedimentation rate(ESR),and C-reactive protein(CRP)and the metabolite 2-methylnaphthalene.Conclusion:The urine metabolite 2-methylnaphthalene can be a risk factor for early urinary tract infections and may contribute to accurately screening early-risk metabolites in ERA.
文摘激光雷达(light detection and ranging,LiDAR)作为一门新兴的主动遥感技术,近年来由于在提取和反演森林参数水平上不断提高,被越来越多地应用于动物生态学研究中。本文通过整理和搜集国内外文献,对激光雷达的技术特点及其在森林参数提取和动物生境上的研究进展进行综述,指出当前基于LiDAR的森林参数反演算法主要服务于森林资源调查或林学研究,缺少对动物生态或生理意义相关的参数量化信息。目前该技术在国内的动物生态学方面的应用较少,尚未见文章发表。通过总结国外学者的研究,分别从动物生境选择与三维森林结构的关系、栖息地立体生境制图、生物多样性评估和物种分布模型预测三个方面综述了LiDAR在动物生态学研究中的应用现状。相比传统方法,LiDAR技术提供的高精度三维结构信息,能够显著提高动物生境质量的评估、生物多样性的监测水平和物种分布模型的评价精度,有利于从机理上加深对物种生境选择和集群过程的理解。但目前LiDAR技术的应用主要集中在对已知的生态关系研究,尤其是冠层结构与动物分布的关系,缺少对林下层生活的动物生境质量和生物多样性的监测和评估,同时很多有关动物生存和繁衍与立体生境的关系研究有待从LiDAR数据中进一步挖掘分析。未来应加强对森林林下层三维信息的提取,提高林下层动物生境质量和生物多样性的监测水平,同时建立适用于动物生态和生理意义相关的参数,为动物生境质量和生物多样性的评估提供标准的量化指标。
基金supported by National Natural Science Foundation of China (No.81973662)Distinguished Young Scholar of Sichuan Provincial Science and Technology Department (No.2019JDJQ0049)111 Project (No.B18035)
文摘The combination of Ce6,an acknowledged photosensitizer,and TPL,a natural anticancer agent,has been demonstrated as a useful strategy to reinforce the tumor growth suppression,as well as decrease the systemic side effects compared with their monotherapy.However,in view of the optimal chemo-photodynamic combination efficiency,there is still short of the feasible nanovehicle to steadily co-deliver Ce6 and TPL,and stimuli-responsively burst release drugs in tumor site.Herein,we described the synergistic antitumor performance of a pH-sensitive supramolecular nanosystem,mediated by the host–vip complexing betweenβ-CD and acid pH-responsive amphiphilic co-polymer mPEG-PBAE-mPEG,showing the shell–core structural micelles with the tightβ-CD layer coating.Both Ce6 and TPLwere facilely co-loaded into the spherical supramolecular NPs(TPL+Ce6/NPs)by one-step nanoprecipitation method,with an ideal particle size(156.0 nm),acid pH-responsive drug release profile,and enhanced cellular internalization capacity.In view of the combination benefit of photodynamic therapy and chemotherapy,as well as co-encapsulation in the fabricated pH-sensitive supramolecular NPs,TPL+Ce6/NPs exhibited significant efficacy to suppress cellular proliferation,boost ROS level,lower MMP,and promote cellular apoptosis in vitro.Particularly,fluorescence imaging revealed that TPL+Ce6/NPs preferentially accumulated in the tumor tissue area,with higher intensity than that of free Ce6.As expected,upon 650-nm laser irradiation,TPL+Ce6/NPs exhibited a cascade of amplified synergistic chemo-photodynamic therapeutic benefits to suppress tumor progression in both hepatoma H22 tumor-bearingmice and B16 tumor-bearingmice.More importantly,lower systemic toxicitywas found in the tumor-bearingmice treated with TPL+Ce6/NPs.Overall,the designed supramolecular TPL+Ce6/NPs provided a promising alternative approach for chemo-photodynamic therapy in tumor treatment.
基金supported by the National Natural Science Foundation of China(No.81903811)China Postdoctoral Science Foundation(No.2021M690488)National TCM Multidisciplinary Interdisciplinary Innovation Team Project:Multidisciplinary Evaluation of Southwest Characteristic TCM Resources Multidisciplinary Interdisciplinary Innovation Team(No.ZYYCXTD-D-202209)。
文摘Although multitudinous nanoscale drug-delivery systems(DDSs)have been recommended to improve anti-ulcerative colitis(UC)outcomes,to enhance the mucoadhesion of nanosystems on the colon and specifically release the loaded drugs in response to the colon micro-environment would be critical factors.The application of curcumin(Cur),an acknowledged anti-UC phytochemical compound,for UC therapy requires more efficient nano-carriers to improve its therapeutic outcome.Herein,we developed the colon-targeted nano-micelles with mucoadhesive effect and Azo reductase-triggered drug release profiles for Cur delivery in UC treatment.Specifically,the amphiphilic block polymer containing the Azo-reductase sensitive linkage(PEG-Azo-PLGA),and catechol-modified TPGS(Cat-TPGS)were synthesized respectively.Based on the self-assembly of the mixed polymers,Cur-micelles(142.7±1.7 nm of average size,72.36%±1.54%of DEE)were obtained.Interestingly,the Cur-micelles exhibited the Azo-reductase sensitive particle dissociation and drug release,the enhanced cellular uptake and the prolonged retention on colonic mucosa,mediated by the strong mucoadhesion of catechol structure.Ultimately,Cur-micelles significantly mitigated colitis symptoms and accelerated colitis repair in DSS-treated mice by regulating the intestinal flora and the levels of pro-inflammatory factors(MPO,IL-6,IL-1β,and TNF-α)related to TLR4/MyD88/NF-κB signaling pathway.This work provides an effective drug delivery strategy for anti-UC drugs by oral administration.
基金supported by National Natural Science Foundation of China(Grant No.11675095)the Fundamental Research Funds of Shandong University(Grant No.2017JC017)。
文摘Cold atmospheric plasma shows a satisfactory ability to inactivate bacterial biofilms that are difficult to remove using conventional methods in some cases. However, the researches on the inactivation mechanism are not quite sufficient. Poly-β-1–6-N-acetylglucosamine(PNAG),which is one of the important components in some biofilms, was used as the research subject,and the related mechanism of action triggered by different concentrations of the OH in plasma was studied using reactive molecular dynamics simulations. The results showed that OH radicals could not only trigger the hydrogen abstraction reaction leading to cleavage of the PNAG molecular structure, but undergo an OH addition reaction with PNAG molecules. New reaction pathways appeared in the simulations as the OH concentration increased, but the reaction efficiency first increased and then decreased. The simulation study in this paper could, to some extent, help elucidate the microscopic mechanism of the interaction between OH radicals in plasma and bacterial biofilms at the atomic level.
基金National Natural Science Foundation of China (Grant Nos. 11675095 and 52077128)the Fundamental Research Funds of Shandong University (Grant No. 2017JC017) for supporting the research。
文摘Increasing concern with regard to food safety in the presence of pesticide residues(PRs) on the surface of agricultural products has resulted in the rapid development of practical degrading technologies for corresponding PRs. In this paper, an unconventional method of degrading pesticides, non-thermal atmospheric plasma(NTAP), was proposed to degrade the avermectin(AVM) in aqueous solution. Optical emission spectroscopy shows that NTAP, consisting of filamentary streamers, contains a variety of reactive oxygen species(ROS) that may interact with AVM. The high-performance liquid chromatography(HPLC)-MS/MS results indicate that the efficiency of AVM degradation seriously depends on multiple operation parameters of the NTAP,including the applied voltage, treatment time and gas flow rate. The maximum degradation rate of AVM was observed to be 97.47% after 240 s exposure under NTAP with an applied voltage of 18 kV and gas flow rate of 1 l min-1. Molecular dynamics simulation based on a reactive force field for the interaction between O(ground state atomic oxygen) and AVM was performed to analyze the underpinning mechanisms. The simulation result shows the possible pathways of the NTAPgenerated O degrading AVM by destroying the glycosyl group or fracturing the ester group.
基金support was received the Science&Technology Foundation of RIPP(PR20230092,PR20230259)the National Natural Science Foundation of China(22278419)the Key Core Technology Research(Social Development)Foundation of Suzhou(2023ss06).
文摘Mineral carbonation is a promising CO_(2) sequestration strategy that can utilize industrial wastes to convert CO_(2) into high-value CaCO_(3).This review summarizes the advancements in CO_(2) mineralization using typical industrial wastes to prepare ultrafine CaCO_(3).This work surveys the mechanisms of CO_(2) mineralization using these wastes and its capacities to synthesize CaCO_(3),evaluates the effects of carbonation pathways and operating parameters on the preparation of CaCO_(3),analyzes the current industrial application status and economics of this technology.Due to the large amount of impurities in solid wastes,the purity of CaCO_(3) prepared by indirect methods is greater than that prepared by direct methods.Crystalline CaCO_(3) includes three polymorphs.The polymorph of CaCO_(3) synthesized by carbonation process is determined the combined effects of various factors.These parameters essentially impact the nucleation and growth of CaCO_(3) by altering the CO_(2) supersaturation in the reaction system and the surface energy of CaCO_(3) grains.Increasing the initial pH of the solution and the CO_(2)flow rate favors the formation of vaterite,but calcite is formed under excessively high pH.Vaterite formation is favored at lower temperatures and residence time.With increased temperature and prolonged residence time,it passes through aragonite metastable phase and eventually transforms into calcite.Moreover,polymorph modifiers can decrease the surface energy of CaCO_(3) grains,facilitating the synthesis of vaterite.However,the large-scale application of this technology still faces many problems,including high costs,high energy consumption,low calcium leaching rate,low carbonation efficiency,and low product yield.Therefore,it is necessary to investigate ways to accelerate carbonation,optimize operating parameters,develop cost-effective agents,and understand the kinetics of CaCO_(3) nucleation and crystallization to obtain products with specific crystal forms.Furthermore,more studies on life cycle assessment(LCA)should be conducted to fully confirm the feasibility of the developed technologies.
文摘Natural radioactivity is very important for the assessment of the marine sand property and usability. By using gamma spectrometry, the concentration of the natural radionuclides 226Ra, 232Th and 40K have been measured in marine sand deposits from Liaodong Bay (LDB), North Yellow Sea (NYS), Zhoushan area (ZS), Taiwan Shoal (TS) and Pearl River Mouth (PR), offshore China, which are potential marine sand mining areas. The radiation activity equivalent (Raeq), indoor gamma absorbed dose rate (DR), annual effective dose (HR), alpha index (Ia), gamma index (Ig), external radiation hazard index (Hex), internal radiation hazard index (Hin), representative level index (RLI), excess lifetime cancer risk (ELCR) and annual gonadal dose equivalent (AGDE) associated with the natural radionuclides are calculated to assess the radiation hazard of the natural radioactivity in the marine sands offshore China. From the analysis, it is found that these marine sands are safe for the constructions. The Pearson correlation coefficient reveals that the 226Ra distribution in the marine sands offshore China is controlled by the variation of the 40K concentration. Principal component analysis (PCA) yields a two-component representation of the entire data from the marine sands, wherein 98.22% of the total variance is explained. Our results provide good baseline data to expand the database of radioactivity of building materials in China and all over the world.
基金Supported by National Natural Science Foundation of China(30672030)
文摘Objective To investigate the effect of propofol on brain regions at different sedation levels and the association between changes in brain region activity and loss of consciousness using blood oxygen level-dependent functional magnetic resonance imaging(BOLD-f MRI) and bispectral index(BIS) monitoring.Methods Forty-eight participants were enrolled at Peking Union Medical College Hospital from October 2011 to March 2012 and randomly assigned to a mild or a deep sedation group using computergenerated random numbers.Preliminary tests were performed a week prior to scanning to determine target effect site concentrations based on BIS and concomitant Observer's Assessment of Alertness/Sedation scores while under propofol.Within one week of the preliminary tests where propofol dose-response was established,BOLD-f MRI was conducted to examine brain activation with the subject awake,and with propofol infusion at the sedation level.Results Mild propofol sedation inhibited left inferior parietal lobe activation.Deep sedation inhibited activation of the left insula,left superior temporal gyrus,and right middle temporal gyrus.Compared with mild sedation,deep propofol sedation inhibited activation of the left thalamus,precentral gyrus,anterior cingulate,and right basal nuclei.Conclusion Mild and deep propofol sedation are associated with inhibition of different brain regions,possibly explaining differences in the respective loss of consciousness processes.
基金We acknowledge the Project of National Key Research and Development Program of China(2020YFD1001403)China Agriculture Research System(CARS-07-B-1)+3 种基金Science&Technology Department of Sichuan Province(2022YFQ0041)the National Natural Science Foundation of China(31601260,32160428)Innovative Training Program for College Students(S202111079058)Special Research Fund from Key Laboratory of Coarse Cereal Processing,Ministry of Agriculture and Rural Affairs(2020CC012)to facilitate the research.
文摘Tartary buckwheat(Fagopyrum tataricum)is an important pseudocereal feed crop with medicinal and nutritional value.Drought is one of the main causes of reduced growth and yield in these plants.We investigated the growth,physiological,and metabolic responses of the widely promoted Tartary buckwheat variety Chuan Qiao No.1 to polyethylene glycol(PEG)-mediated drought stress.Drought significantly decreased shoot length,shoot biomass and relative water content.Root length,malondialdehyde content,electrolyte leakage,activities of superoxide dismutase,peroxidase,catalase and amylase,and contents of soluble sugar,soluble protein and proline were increased by PEG-mediated drought.Untargeted metabolomics analysis identified 32 core metabolites in seedlings subjected to PEG-mediated drought,16 of which increased—including quercetin,isovitexin,cyanidin 3-O-beta-D-glucoside,L-arginine,and glycerophosphocholine,while the other 16 decreased—including 3-methoxytyramine,2,6-diaminopimelic acid,citric acid,UDP-alpha-D-glucose,adenosine,keto-D-fructose.The 32 core metabolites were enriched in 29 metabolic pathways,including lysine biosynthesis,citrate(TCA)cycle,anthocyanin biosynthesis,and aminoacyl-tRNA biosynthesis.Among them,taurine and hypotaurine metabolism,flavor and flavor biosynthesis,indole alkaline biosynthesis,and alanine,aspartate and glutamate metabolism were the four main metabolic pathways affected by drought.Our findings provide new insights into the physiological and metabolic response mechanisms of Tartary buckwheat to drought stress.
基金This work was funded by National Key R&D Program of China(Grant No.2019YFD1001302/2019YFD1001300)Supported by National Natural Science Foundation of China(31771716+2 种基金3160126031701358)the earmarked fund for China Agriculture Research System(CARS-07-02A).
文摘Drought can limit the growth and reduce the yield of crops,but the safe and effective bio-approach to improve the drought resistance of crops is very little.We conducted an experiment in which we monitored the effects of polysaccharide from the endophyte Bionectria sp.Fat6 on the growth of Tartary buckwheat(Fagopyrum tataricum(L.)Gaertn)seedlings under control and drought-stressed conditions by determining gas exchange,photosynthesis parameters,photosynthetic pigment contents,and metabolite accumulation.Results indicated that the polysaccharide from endophyte stimulated plant growth and increased the aboveground biomass,root mass,and root/shoot ratio of Tartary buckwheat.Application of the polysaccharide to drought-stressed plants resulted in a significant increase in the net photosynthetic rate,stomatal conductance,and transpiration rate of Tartary buckwheat and decreased the intercellular CO_(2) concentration.The contents of chlorophyll a,chlorophyll b,chlorophyll a+b,and carotenoids in leaves were higher in polysaccharide-treated seedlings than that in control.Polysaccharide notably increased the soluble protein and proline content and decreased the malondialdehyde content in Tartary buckwheat leaves.The endophytic polysaccharide may protect Tartary buckwheat against drought by improving leaf gas exchange and photosynthetic capacity,and altering concentrations of protective metabolites.Together,these changes may compensate for the negative impacts of drought stress on the growth of Tartary buckwheat.Thus,the polysaccharide from the endophyte Bionectria sp.Fat6 may be an effective biotic elicitor and a promising bio-approach to improve Tartary buckwheat production worldwide.
基金Science&Technology Department of Sichuan Province(2022YFQ0041,2022NSFSC1725,2023NSFSC0214)China Agriculture Research System(CARS-07-B-1)+2 种基金The National Natural Science Foundation of China(32160428)Innovative Training Program for College Students(202311079040,S202311079112,CDUCX2023550)Undergraduate Education and Teaching Reform Project of Chengdu University(cdjgb2022186).
文摘Aluminum (Al) toxicity is a considerable factor limiting crop yield and biomass in acidic soil. Tartary buckwheatgrowing in acidic soil may suffer from Al poisoning. Here, we investigated the influence of Al stress on the growthof tartary buckwheat seedling roots, and the alleviation of Al stress by silicon (Si), as has been demonstrated inmany crops. Under Al stress, root growth (total root length, primary root length, root tips, root surface area, androot volume) was significantly inhibited, and Al and malondialdehyde (MDA) accumulated in the root tips. At thesame time, catalase (CAT) and ascorbate peroxidase activities, polyphenols, flavonoids, and 1,1-diphenyl-2-picrylhydrazyl(DPPH) and 2,2′-azinobis-(3-ethylbenzthiazoline-6-sulphonate) (ABTS) free-radical scavenging abilitywere significantly decreased. After the application of Si, root growth, Al accumulation, and oxidative damage wereimproved. Compared to Al-treated seedlings, the contents of ·O2− and MDA decreased by 29.39% and 25.22%,respectively. This was associated with Si-induced increases in peroxidase and CAT enzyme activity, flavonoidcompounds, and free-radical scavenging (DPPH and ABTS). The application of Si therefore has positive effectson Al toxicity in tartary buckwheat roots by reducing Al accumulation in the roots and maintaining oxidationhomeostasis.
基金supported by the National Natural Science Foundation of China(82271105,82571240,81970839)the Sichuan Science and Technology Program(2023ZYD0059 and 2021YFS0033).
文摘Primary open-angle glaucoma(POAG),a leading cause of irreversible blindness,involves complex neurodegeneration in which the contribution of systemic immunity remains enigmatic.Here,we dissect the circulating immune landscape in POAG patients via high-resolution single-cell RNA sequencing of~1.4 million peripheral blood mononuclear cells(PBMCs)from 110 patients and 110 controls of Chinese ancestry.We revealed significant immune remodeling in POAG,characterized by increased CD4+T lymphocytes and myeloid cells and impaired cytolytic potential,as evidenced by reduced cell proportions of terminally differentiated CD8+GZMK+T cells and NK cells.Transcriptomic analysis revealed a sophisticated dual transcriptional landscape in which both proinflammatory and neuroprotective signaling pathways coexist across multiple immune cell lineages.While TNF and IFNG pathway genes were broadly downregulated,specific inflammatory activation components and neuroprotective genes were upregulated in distinct cell populations,suggesting that POAG represents a complex immunometabolic syndrome characterized by a dysregulated balance between inflammatory and neuroprotective signaling.Cell type-specific eQTL mapping and SMR analysis revealed that POAG genetic risk loci exert their effects through immune gene regulation in specific PBMC subsets.Functional validation using Ifng-/-and Tnf+/-mice in an LPS/NMDA-induced retinal injury model,which mirrored the immune alterations observed in human POAG,demonstrated that genetic deficiency in these pathways markedly exacerbated retinal ganglion cell loss and visual pathway deficits.Our study establishes a crucial link between systemic immune dysregulation-specifically the disrupted balance between inflammatory and neuroprotective signaling-and retinal health,highlighting the importance of restoring this balance for future POAG therapeutic strategies.
基金supported by the National Natural Science Foundation of China(Nos.62373360 and 62473368).
文摘Gear pitting fault is a common issue in gear systems,affecting transmission efficiency and potentially leading to severe equipment shutdowns.Effective diagnosis enhances reliability,reduces maintenance costs,and extends equipment lifespan.However,existing deep learning based methods often neglect the inherent structure of temporal vibration signals and fail to address domain variations,resulting in poor generalization and performance.To overcome these limitations,we propose a novel approach based on domain-independent features.Vibration signals are mapped to time-frequency representations via short-time Fourier transform,and dependencies between different frequencies are effectively captured using a Transformer encoder.The proposed method incorporates a feature decoupling structure that combines singular value decomposition and Pearson correlation coefficient to extract low-rank approximations of domain-related and pitting-related features,while quantifying their correlation.This approach mitigates feature degradation in constructing domain-independent features.Additionally,the weighted LinSoftmax function is introduced as a replacement for the traditional Softmax,leading to a more stable optimization target and improved model accuracy,with a distance-based penalty weight focusing on significant prediction errors.Experiments on the 2023 PHM Data Challenge dataset demonstrate the effectiveness of the proposed method,achieving a mean absolute error of 0.11,an accuracy of 92.32%,and a fault tolerance accuracy of 98.02%.
文摘High wind power penetration(WPP)is challenging system frequency stability.As a countermeasure,virtual inertia controls are introduced,utilizing kinetic energy(KE)stored in wind turbine generators(WTGs)for frequency regulation.Without restoration,generation efficiency of WTGs will be degraded after inertia contribution.To counter this issue,we propose an inertia control scheme of a doubly fed induction generator(DFIG),aiming at achieving dynamic inertia recovery regarding both KE and DC link energy.An asymmetrical droop control,referred to as the rate of change of frequency(RoCoF),is proposed for KE management.The upper boundary of droop gain is extended to give full play to converters and is revised,considering the system frequency state,to counter positive feedback issues induced by reversible gain regulation,which is restricted by KE to ensure stable operations as well.The inertial DC energy needed to cooperate with KE control regarding countering small fluctuations,is improved with an orderly recovery behavior.Case studies are conducted under dynamic wind conditions and the results indicate that with our proposed scheme,the ability of dynamic inertia recovery can be obtained,bringing DFIG higher generation efficiency and more adequate operation margin for sustained regulation.Essentially,the inertial frequency response and fluctuation suppression ability is well maintained.
基金supported by the National Basic Research Program of China (2015CB856300)the National Natural Science Foundation of China (21571099, 21731004)the Natural Science Foundation of Jiangsu (BK20150054)
文摘A two-photon ratiometric fluorescent sensor for Cu^+ in endoplasmic reticulum(ER), CNSB, was developed via coumarin/ASBD integration based on FRET mechanism. In solution, CNSB shows reversible, highly-specific ratiometric response to Cu^+ .Moreover, CNSB exhibits suitable K_d value, suggesting the possibility of detecting Cu^+ in the living cells. The probe can enter the MCF-7 cells easily and specifically locates in the ER. The highly specific ratiometric response of CNSB toward Cu^+ in MCF-7 cells provides the sensor the capacity to visualize both exogenous and endogenous Cu^+ in the ER via fluorescence imaging.Next, CNSB was utilized to detect the fluctuation and distribution of Cu^+ under ER stress in MCF-7 cells, which confirmed directly the relationship between Cu^+ enhancement and ER stress. Meanwhile, the two-photon ability of coumarin facilitated the sensor to visualize Cu^+ fluctuation via two-photon fluorescence imaging. In addition, the spatial distribution of Cu^+ in the heart slice of the 14-day-old rat was demonstrated using CNSB. This study demonstrates the promising potential of CNSB in clarifying the Cu^+ -dependent signaling in the ER stress-related diseases.
