Neural EGFL-like 2(NELL2)is a secreted protein known for its regulatory functions in the nervous and reproductive systems,yet its role in bone biology remains unexplored.In this study,we observed that NELL2 was dimini...Neural EGFL-like 2(NELL2)is a secreted protein known for its regulatory functions in the nervous and reproductive systems,yet its role in bone biology remains unexplored.In this study,we observed that NELL2 was diminished in the bone of aged and ovariectomized(OVX)mice,as well as in the serum of osteopenia and osteoporosis patients.In vitro loss-of-function and gain-offunction studies revealed that NELL2 facilitated osteoblast differentiation and impeded adipocyte differentiation from stromal progenitor cells.In vivo studies further demonstrated that the deletion of NELL2 in preosteoblasts resulted in decreased cancellous bone mass in mice.Mechanistically,NELL2 interacted with the FNI-type domain located at the C-terminus of Fibronectin 1(Fn1).Moreover,we found that NELL2 activated the focal adhesion kinase(FAK)/AKT signaling pathway through Fn1/integrinβ1(ITGB1),leading to the promotion of osteogenesis and the inhibition of adipogenesis.Notably,administration of NELL2-AAV was found to ameliorate bone loss in OVX mice.These findings underscore the significant role of NELL2 in osteoblast differentiation and bone homeostasis,suggesting its potential as a therapeutic target for managing osteoporosis.展开更多
Self-trapping excitons(STEs) emission in metal halides has been a matter of interest, correlating with the strength of electron-phonon coupling in the lattice, which are usually caused by ions with ns~2 electronic str...Self-trapping excitons(STEs) emission in metal halides has been a matter of interest, correlating with the strength of electron-phonon coupling in the lattice, which are usually caused by ions with ns~2 electronic structure. In this work, Sb^(3+)/Te^(4+)ions doped Zn-based halide single crystals(SCs) with two STEs emissions have been synthesized and the possibility of its anti-counterfeiting application was explored.Further, the relationship between the strength of electron-phonon coupling and photoluminescence quantum yields(PLQYs) for STEs in a series of metal halides has been studied. And the semi-empirical range of the Huang-Rhys factors(S) for metal halides with excellent photoluminescence(PL) property has been summarized. This work provides ideas for further research into the relationship between luminescence performance and electron-phonon coupling of metal halides, and also provides a reference for designing the metal halides with high PLQYs.展开更多
Tetracycline(TC)is a broad-spectrum antibiotic,and its residues in the environment and food are harmful to human health.Therefore,it is essential to rapidly,sensitively,and conveniently detect TC.In this work,we devel...Tetracycline(TC)is a broad-spectrum antibiotic,and its residues in the environment and food are harmful to human health.Therefore,it is essential to rapidly,sensitively,and conveniently detect TC.In this work,we developed a portable silicon nanoparticles chelated Europium(Ⅲ)-based polyacrylonitrile(Eu-SiNPs/PAN)nanofiber membrane for rapid,sensitive,and convenient detection of TC.The Eu-SiNPs were synthesized with a facile one-pot method.The Eu-SiNPs/PAN nanofiber membrane was fabricated by electrospinning,combining Eu-SiNPs and PAN with three-dimensional porous membrane structures and UV resistance.Both the Eu-SiNPs and the Eu-SiNPs/PAN nanofiber membranes have good selectivity and anti-interference ability towards TC.The combined merits of rapid response,long storage life,easy portability,and naked-eye recognition of TC make the Eu-SiNPs/PAN nanofiber membrane a promising material for convenient TC detection applications.The practicability of these nanofiber membranes was further verified by detecting TC in real samples,such as lake water,drinking water and honey,and achieved quantitative detection.展开更多
Silicosis,a major persistent occupational disease in China,is a progressive and irreversible pulmonary fibrosis disease with unclear pathogenesis.Cellular senescence,a state of stable cell cycle arrest that is recogni...Silicosis,a major persistent occupational disease in China,is a progressive and irreversible pulmonary fibrosis disease with unclear pathogenesis.Cellular senescence,a state of stable cell cycle arrest that is recognized as a key underlying factor in age-related fibroproliferative disorders,plays an important role in chronic lung diseases,particularly pulmonary fibrosis.We previously reported that SiO2-stimulated mice and alveolar type II epithelial cells develop cellular senescence,which is involved in silicosis formation in alveolar type II epithelial cells[1].Cellular senescence may play an important role in silicosis development;however,the exact underlying mechanisms are not fully understood.展开更多
Digestive health is important for overall well-being,but gut health problems are common in the Chinese population.The objective of this study was to investigate the effects of oatβ-glucan-based prebiotic blended form...Digestive health is important for overall well-being,but gut health problems are common in the Chinese population.The objective of this study was to investigate the effects of oatβ-glucan-based prebiotic blended formulas in humans on digestive health by assessing defecation frequency,defecation symptoms,stool quality,self-reported digestive feelings,defecation satisfaction,and gut bacteria.A parallel,randomized,double-blind,controlled trial was conducted in 168 eligible adults randomized to 3 groups for 14 days:Intervention groups A and B received 2 different doses of oatβ-glucan-based prebiotic blended formulas and a Control group received oatβ-glucan mixed with hydroxypropylmethyl-cellulose and microcrystalline cellulose.Participants completed a defecation diary and Bristol stool chart daily and digestive system questionnaires weekly.Fecal samples were collected on day 0 and day 14 to evaluate gut bacteria using 16S rDNA analysis.Both formulas improved defecation frequency,stool quality,defecation symptoms,defecation satisfaction,and on digestive health of human,compared with baseline(P<0.05).Both formulas led to increased quantities of Bifidobacterium and Akkermansia bacteria,compared to control,on day 14.This study therefore demonstrated the beneficial effects of oatβ-glucan-based prebiotic blended formulas on gut health in generally healthy Chinese adults.These formulas are a feasible nutritional strategy for digestive health.展开更多
In the twenty-first century,we have witnessed multiple coronavirus pandemics.Despite declining SARS-CoV-2 cases,continued research remains vital.We report the discovery of sydowiol B,a natural product,as a dual inhibi...In the twenty-first century,we have witnessed multiple coronavirus pandemics.Despite declining SARS-CoV-2 cases,continued research remains vital.We report the discovery of sydowiol B,a natural product,as a dual inhibitor of SARS-CoV-2 main protease(Mpro)and papain-like protease(PLpro).Sydowiol B interacts with the nano-channel at the Mpro dimer interface and the PLpro active site.Molecular dynamics simulations suggest that sydowiol B inhibits Mpro by limiting active site expansion rather than inducing collapse.Furthermore,sydowiol B binding may amplify the fluctuation of two loops coordinating with the structural Zn^(2+)in PLpro,displacing Zn^(2+)from the zinc finger domain to the S2 helix.Sydowiol B and its analogue,violaceol I,exhibit broad-spectrum antiviral activity against homologous coronaviruses.Given the conservation of Mpro and PLpro,sydowiol B and violaceol I are promising leads for designing and developing anti-coronavirus therapies.展开更多
Li_(6)PS_(5)Cl is a highly wanted sulfide-solid-electrolyte(SSE)for developing all-solid-state lithium batteries,due to its high ionic conductivity,good processability and abundant compositional elements.However,its c...Li_(6)PS_(5)Cl is a highly wanted sulfide-solid-electrolyte(SSE)for developing all-solid-state lithium batteries,due to its high ionic conductivity,good processability and abundant compositional elements.However,its cyclability is poor because of harmful side reactions at the Li_(6)PS_(5)Cl/Li interface and growth of lithium dendrites inside Li_(6)PS_(5)Cl phase.Herein,we report a simple interface-engineering remedy to boost the electrochemical performance of Li_(6)PS_(5)Cl,by coating its surface with a Li-compatible electrolyte Li3OCl having low electronic conductivity.The obtainedLi_(6)PS_(5)Cl@Li_(3)OCl core@shell structure exhibits a synergistic effect.Consequently,compared with the bare Li_(6)PS_(5)Cl,this composite electrolyte exhibits great performance improvements:1)In Li|electrolyte|Li symmetric cells,the critical current density at 30℃gets increased from 0.6 mA cm^(-2)to 1.6 mA cm^(-2),and the lifetime gets prolonged from 320 h to 1400 h at the cycling current of 0.2 mA cm^(-2)or from 10 h to 900 h at the cycling current of 0.5 mA cm^(-2);2)In Li|electrolyte|NCM721 full cells running at 30℃,the cycling capacity at 0.2 C(or 0.5 C)gets enhanced by 20%(or from unfeasible to be feasible)for 100 cycles and the rate capability reaches up to 2 C from 0.2 C;and in full cells running at 60℃,the cycling capacity is increased by 7%at 0.2 C and the rate capability is enhanced to 3.0 C from 0.5 C.The experimental studies and theoretical computations show that the performance enhancements are due to the confined electron penetration and suppressed lithium dendrites growth at theLi_(6)PS_(5)Cl@Li_(3)OCl interface.展开更多
As future ship system,hybrid energy ship system has a wide range of application prospects for solving the serious energy crisis.However,current optimization scheduling works lack the consideration of sea conditions an...As future ship system,hybrid energy ship system has a wide range of application prospects for solving the serious energy crisis.However,current optimization scheduling works lack the consideration of sea conditions and navigational circumstances.There-fore,this paper aims at establishing a two-stage optimization framework for hybrid energy ship power system.The proposed framework considers multiple optimizations of route,speed planning,and energy management under the constraints of sea conditions during navigation.First,a complex hybrid ship power model consisting of diesel generation system,propulsion system,energy storage system,photovoltaic power generation system,and electric boiler system is established,where sea state information and ship resistance model are considered.With objective optimization functions of cost and greenhouse gas(GHG)emissions,a two-stage optimization framework consisting of route planning,speed scheduling,and energy management is constructed.Wherein the improved A-star algorithm and grey wolf optimization algorithm are introduced to obtain the optimal solutions for route,speed,and energy optimization scheduling.Finally,simulation cases are employed to verify that the proposed two-stage optimization scheduling model can reduce load energy consumption,operating costs,and carbon emissions by 17.8%,17.39%,and 13.04%,respectively,compared with the non-optimal control group.展开更多
Reactive oxygen species(ROS)are closely related to cell death,proliferation and inflammation.However,excessive ROS levels may exceed the cellular oxidative capacity and cause irreversible damage.Organisms are often in...Reactive oxygen species(ROS)are closely related to cell death,proliferation and inflammation.However,excessive ROS levels may exceed the cellular oxidative capacity and cause irreversible damage.Organisms are often inadvertently exposed to nanomaterials(NMs).Therefore,elucidating the specific routes of ROS generation induced by NMs is crucial for comprehending the toxicity mechanisms of NMs and regulating their potential applications.This paper provides a comprehensive review of the toxicity mechanisms and applications of NMs from three perspectives:(1)Organelle perspective.Investigating the impact of NMmediated ROS onmitochondria,unravelingmechanisms at the organelle level.(2)NMs’perspective.Exploring the broad applications and biosafety considerations of Nanozymes,a unique class of NMs.(3)Cellular system.Examining the toxic effects and mechanisms of NMs in cells at a holistic cellular level.Expanding on these perspectives,the paper scrutinizes the regulation of Fenton reactions by NMs in organisms.Furthermore,it introduces diseases resulting fromNM-mediated ROS at the organism level.This comprehensive review aims to provide valuable insights for studying NM-mediated mechanisms at both cellular and organism levels,offering considerations for the safe design of nanomaterials.展开更多
Background Early embryo development plays a pivotal role in determining pregnancy outcomes,postnatal development,and lifelong health.Therefore,the strategic selection of functional nutrients to enhance embryo developm...Background Early embryo development plays a pivotal role in determining pregnancy outcomes,postnatal development,and lifelong health.Therefore,the strategic selection of functional nutrients to enhance embryo development is of paramount importance.In this study,we established a stable porcine trophectoderm cell line expressing dual fluorescent reporter genes driven by the CDX2 and TEAD4 gene promoter segments using lentiviral transfection.Results Three amino acid metabolites—kynurenic acid,taurine,and tryptamine—met the minimum z-score criteria of 2.0 for both luciferase and Renilla luciferase activities and were initially identified as potential metabolites for embryo development,with their beneficial effects validated by qPCR.Given that the identified metabolites are closely related to methionine,arginine,and tryptophan,we selected these three amino acids,using lysine as a standard,and employed response surface methodology combined with our high-throughput screening cell model to efficiently screen and optimize amino acid combination conducive to early embryo development.The optimized candidate amino acid system included lysine(1.87 mmol/L),methionine(0.82 mmol/L),tryptophan(0.23 mmol/L),and arginine(3 mmol/L),with the ratio of 1:0.43:0.12:1.60.In vitro experiments confirmed that this amino acid system enhances the expression of key genes involved in early embryonic development and improves in vitro embryo adhesion.Transcriptomic analysis of blastocysts suggested that candidate amino acid system enhances early embryo development by regulating early embryonic cell cycle and differentiation,as well as improving nutrient absorption.Furthermore,based on response surface methodology,400 sows were used to verify this amino acid system,substituting arginine with the more cost-effective N-carbamoyl glutamate(NCG),a precursor of arginine.The optimal dietary amino acid requirement was predicted to be 0.71%lysine,0.32%methionine,0.22%tryptophan,and 0.10%NCG for sows during early gestation.The optimized amino acid system ratio of the feed,derived from the peripheral release of essential amino acids,was found to be 1:0.45:0.13,which is largely consistent with the results obtained from the cell model optimization.Subsequently,we furtherly verified that this optimal dietary amino acid system significantly increased total litter size,live litter size and litter weight in sows.Conclusions In summary,we successfully established a dual-fluorescent high-throughput screening cell model for the efficient identification of potential nutrients that would promote embryo development and implantation.This innovative approach overcomes the limitations of traditional amino acid nutrition studies in sows,providing a more effective model for enhancing reproductive outcomes.展开更多
Objective To develop a facial image generation method based on a facial color-preserving generative adversarial network(FCP-GAN)that effectively decouples identity features from diagnostic facial complexion characteri...Objective To develop a facial image generation method based on a facial color-preserving generative adversarial network(FCP-GAN)that effectively decouples identity features from diagnostic facial complexion characteristics in traditional Chinese medicine(TCM)inspection,thereby addressing the critical challenge of privacy preservation in medical image analysis.Methods A facial image dataset was constructed from participants at Nanjing University of Chinese Medicine between April 23 and June 10,2023,using a TCM full-body inspection data acquisition equipment under controlled illumination.The proposed FCP-GAN model was designed to achieve the dual objectives of removing identity features and preserving colors through three key components:(i)a multi-space combination module that comprehensively extracts color attributes from red,green,blue(RGB),hue,saturation,value(HSV),and Lab spaces;(ii)a generator incorporating efficient channel attention(ECA)mechanism to enhance the representation of diagnostically critical color channels;and(iii)a dual-loss function that combines adversarial loss for de-identification with a dedicated color preservation loss.The model was trained and evaluated using a stratified 5-fold cross-validation strategy and evaluated against four baseline generative models:conditional GAN(CGAN),deep convolutional GAN(DCGAN),dual discriminator CGAN(DDCGAN),and medical GAN(MedGAN).Performance was assessed in terms of image quality[peak signal-to-noise ratio(PSNR)and structural similarity(SSIM)],distribution similarity[Fréchet inception distance(FID)],privacy protection(face recognition accuracy),and diagnostic consistency[mean squared error(MSE)and Pearson correlation coefficient(PCC)].Results The final analysis included facial images from 216 participants.Compared with baseline models,FCP-GAN achieved superior performance,with PSNR=31.02 dB and SSIM=0.908,representing an improvement of 1.21 dB and 0.034 in SSIM over the strongest baseline(MedGAN).The FID value(23.45)was also the lowest among all models,indicating superior distributional similarity to real images.The multi-space feature fusion and the ECA mechanism contributed significantly to these performance gains,as evidenced by ablation studies.The stratified 5-fold cross-validation confirmed the model’s robustness,with results reported as mean±standard deviation(SD)across all folds.The model effectively protected privacy by reducing face recognition accuracy from 95.2%(original images)to 60.1%(generated images).Critically,it maintained high diagnostic fidelity,as evidenced by a low MSE(<0.051)and a high PCC(>0.98)for key TCM facial features between original and generated images.Conclusion The FCP-GAN model provides an effective technical solution for ensuring privacy in TCM diagnostic imaging,successfully having removed identity features while preserving clinically vital facial color features.This study offers significant value for developing intelligent and secure TCM telemedicine systems.展开更多
Nitric oxide(NO)modulates several cancer-related physiological processes and has advanced the development of green methods for cancer treatment and integrated platforms for combination or synergistic therapies.Althoug...Nitric oxide(NO)modulates several cancer-related physiological processes and has advanced the development of green methods for cancer treatment and integrated platforms for combination or synergistic therapies.Although a nanoengineering strategy has been proposed to overcome deficiencies of NO gas or small NO donor molecules,such as short half-life,lipophilicity,non-selectivity,and poor stability,it remains challenging to prepare NO nanomedicines with simple composition,multiple functions and enhanced therapeutic efficacy.Herein,we build a liquid metal nanodroplet(LMND)-based NO nanogenerator(LMND@HSG)that is stabilized by a bioreducible guanylated hyperbranched poly(amido amine)(HSG)ligand.Mechanically,the tumor microenvironment specifically triggers a cascade process of glutathione elimination,reactive oxygen species(ROS)generation,and NO release.According to actual demand,the ROS and NO concentrations could be readily controlled by tuning the LMND and HSG feed amounts.Along with the intrinsic anticancer property of LMND(ROS-mediated apoptosis and anti-angiogenesis),LMND@HSG administration could further enhance tumor growth suppression compared with LMND and HSG alone.Fromthis study,leveraging LMND for NO gas therapy provides more possibilities for the prospect of LMND-based anticancer nanomedicines.展开更多
Rational tuning of crystallographic surface and metal doping were effective to enhance the catalytic performance of metal organic frameworks,but limited work has been explored for achieving modulation of crystal facet...Rational tuning of crystallographic surface and metal doping were effective to enhance the catalytic performance of metal organic frameworks,but limited work has been explored for achieving modulation of crystal facets and metal doping in a single system.MIL-68(In)was promising for photocatalytic applications due to its low toxicity and excellent photoresponsivity.However,its catalytic activity was constrained by severe carrier recombination and a lack of active sites.Herein,increased(001)facet ratio and active sites exposure were simultaneously realized by cobalt doping in MIL-68(In)through a one-pot solvothermal strategy.Optimized MIL-68(In/Co)-2.5 exhibited remarkable catalytic performance in comparison with pristine MIL-68(In)and other MIL-68(In/Co).The reaction kinetic constant and degradation efficiency of MIL-68(In/Co)were approximately twice and 17%higher than the pristine MIL-68(In)in 36 min reaction,respectively.Density functional theory calculations revealed that Co dopant could modulate the orientation of MIL-68(In)facets,facilitate the exchange of electrons and reduce the adsorption energy of peroxymonosulfate(PMS).This work provides a novel pathway for improvement of In-based MOFs in PMS/vis system,it also promotes the profound comprehension of the correlation between crystal facet regulation and catalytic activation in the PMS/vis system.展开更多
Since the discovery of carbonized polymer dots(CPDs)two decades ago,this emerging family of carbonbased nanomaterials has rapidly risen to prominence.CPDs have found widespread applications in sensing,catalysis,energy...Since the discovery of carbonized polymer dots(CPDs)two decades ago,this emerging family of carbonbased nanomaterials has rapidly risen to prominence.CPDs have found widespread applications in sensing,catalysis,energy,and biomedicine due to their flexible precursors and synthesis methods,tunable photoluminescence(PL)properties,and excellent biocompatibility.This report presents the advancements made in the realm of CPD precursors,elucidates their luminescence properties and underlying mechanisms,and explores the diverse applications of CPD-based materials.It comprehensively addresses key issues by delving into several interconnected chapters:Initially exploring the intriguing fluorescence and afterglow properties exhibited by CPDs,subsequently unraveling the complex luminescence mechanisms that underlie these phenomena,emphasizing the crucial aspect of controllable synthesis of CPDs,and ultimately culminating in the precise construction of composite materials tailored for applications in laser and electroluminescent devices.Furthermore,this report aims to provide communication and assistance for the controlled synthesis and expanded applications of CPDs.展开更多
Gasification is a highly effective technology for converting biomass into fuel gas or syngas.While various gas-ifiers have been commercialized for fuel gas production,mitigating tar formation in gasifiers remains chal...Gasification is a highly effective technology for converting biomass into fuel gas or syngas.While various gas-ifiers have been commercialized for fuel gas production,mitigating tar formation in gasifiers remains chal-lenging.This review is devoted to summarizing the general strategies adopted in various gasifiers to reduce tar formation for high-efficiency clean gasification.For single-bed and staged-gasification processes,their low-tar strategies are typically different.In the single-bed processes,the low-tar strategies involve in-bed intensifica-tion achieved by controlling flow directions of gas and particles inside the gasifier.During the gasification,these two components often have different temperatures to facilitate thermochemical interactions between them.Meanwhile,the two-stage gasifiers are generally designed to decouple pyrolysis,gasification and tar cracking reactions for maximizing the benefits(such as yield and efficiency)realized from the interactions among these reactions.In addition to minimizing tar formation,the approach of reaction decoupling can also raise the calorific value of product gas,even without use of oxygen,and/or improve the adaptability of gasification technology to the feedstocks with various moisture contents and particle sizes.The reanalysis based on those essential low-tar strategies is expected to gain alternative insights into the reaction principles implicated in most advanced biomass gasification technologies.展开更多
Nanoplastics exhibit greater environmental biotoxicity than microplastics and can be ingested by humans through major routes such as tap water,bottled water and other drinking water.Nanoplastics present a challenge fo...Nanoplastics exhibit greater environmental biotoxicity than microplastics and can be ingested by humans through major routes such as tap water,bottled water and other drinking water.Nanoplastics present a challenge for air flotation due to their minute particle size,negative surface potential,and similar density to water.This study employed dodecyltrimethylammonium chloride(DTAC)as a modifier to improve conventional air flotation,which significantly enhanced the removal of polystyrene nanoplastics(PSNPs).Conventional air flotation removed only 3.09%of PSNPs,while air flotation modified by dodecyltrimethylammonium chloride(DTAC-modified air flotation)increased the removal of PSNPs to 98.05%.The analysis of the DTAC-modified air flotation mechanism was conducted using a combination of instruments,including a zeta potential analyzer,contact angle meter,laser particle size meter,high definition camera,scanning electron microscope(SEM),energy dispersive spectrometer(EDS)and Fourier transform infrared spectrometer(FTIR).The results indicated that the incorporation of DTAC reversed the electrostatic repulsion between bubbles and PSNPs to electrostatic attraction,significantly enhancing the hydrophobic force in the system.This,in turn,improved the collision adhesion effect between bubbles and PSNPs.The experimental results indicated that even when the flotation time was reduced to 7min,the DTACmodified air flotation still achieved a high removal rate of 96.26%.Furthermore,changes in aeration,pH,and ionic strength did not significantly affect the performance of the modified air flotation for the removal of PSNPs.The removal rate of PSNPs in all three water bodies exceeded 95%.The DTAC-modified air flotation has excellent resistance to interference from complex conditions and shows great potential for practical application.展开更多
基金supported by grants from National Natural Science Foundation of China(82272444,81972031,81972033)China Postdoctoral Science Foundation(2022M722382)Tianjin Key Medical Discipline(Specialty)Construction Project(TJYXZDXK-032A)。
文摘Neural EGFL-like 2(NELL2)is a secreted protein known for its regulatory functions in the nervous and reproductive systems,yet its role in bone biology remains unexplored.In this study,we observed that NELL2 was diminished in the bone of aged and ovariectomized(OVX)mice,as well as in the serum of osteopenia and osteoporosis patients.In vitro loss-of-function and gain-offunction studies revealed that NELL2 facilitated osteoblast differentiation and impeded adipocyte differentiation from stromal progenitor cells.In vivo studies further demonstrated that the deletion of NELL2 in preosteoblasts resulted in decreased cancellous bone mass in mice.Mechanistically,NELL2 interacted with the FNI-type domain located at the C-terminus of Fibronectin 1(Fn1).Moreover,we found that NELL2 activated the focal adhesion kinase(FAK)/AKT signaling pathway through Fn1/integrinβ1(ITGB1),leading to the promotion of osteogenesis and the inhibition of adipogenesis.Notably,administration of NELL2-AAV was found to ameliorate bone loss in OVX mice.These findings underscore the significant role of NELL2 in osteoblast differentiation and bone homeostasis,suggesting its potential as a therapeutic target for managing osteoporosis.
基金supported by the financial aid from the National Natural Science Foundation of China (No. 22271273)International Partnership Program of Chinese Academy of Sciences (No. 121522KYSB20190022)。
文摘Self-trapping excitons(STEs) emission in metal halides has been a matter of interest, correlating with the strength of electron-phonon coupling in the lattice, which are usually caused by ions with ns~2 electronic structure. In this work, Sb^(3+)/Te^(4+)ions doped Zn-based halide single crystals(SCs) with two STEs emissions have been synthesized and the possibility of its anti-counterfeiting application was explored.Further, the relationship between the strength of electron-phonon coupling and photoluminescence quantum yields(PLQYs) for STEs in a series of metal halides has been studied. And the semi-empirical range of the Huang-Rhys factors(S) for metal halides with excellent photoluminescence(PL) property has been summarized. This work provides ideas for further research into the relationship between luminescence performance and electron-phonon coupling of metal halides, and also provides a reference for designing the metal halides with high PLQYs.
基金supported by the Natural Science Foundation of Tianjin(Nos.18JCQNJC72400 and 22JCQNJC01510).
文摘Tetracycline(TC)is a broad-spectrum antibiotic,and its residues in the environment and food are harmful to human health.Therefore,it is essential to rapidly,sensitively,and conveniently detect TC.In this work,we developed a portable silicon nanoparticles chelated Europium(Ⅲ)-based polyacrylonitrile(Eu-SiNPs/PAN)nanofiber membrane for rapid,sensitive,and convenient detection of TC.The Eu-SiNPs were synthesized with a facile one-pot method.The Eu-SiNPs/PAN nanofiber membrane was fabricated by electrospinning,combining Eu-SiNPs and PAN with three-dimensional porous membrane structures and UV resistance.Both the Eu-SiNPs and the Eu-SiNPs/PAN nanofiber membranes have good selectivity and anti-interference ability towards TC.The combined merits of rapid response,long storage life,easy portability,and naked-eye recognition of TC make the Eu-SiNPs/PAN nanofiber membrane a promising material for convenient TC detection applications.The practicability of these nanofiber membranes was further verified by detecting TC in real samples,such as lake water,drinking water and honey,and achieved quantitative detection.
文摘Silicosis,a major persistent occupational disease in China,is a progressive and irreversible pulmonary fibrosis disease with unclear pathogenesis.Cellular senescence,a state of stable cell cycle arrest that is recognized as a key underlying factor in age-related fibroproliferative disorders,plays an important role in chronic lung diseases,particularly pulmonary fibrosis.We previously reported that SiO2-stimulated mice and alveolar type II epithelial cells develop cellular senescence,which is involved in silicosis formation in alveolar type II epithelial cells[1].Cellular senescence may play an important role in silicosis development;however,the exact underlying mechanisms are not fully understood.
基金funded by the Chinese Nutrition Society and PepsiCo Inc.
文摘Digestive health is important for overall well-being,but gut health problems are common in the Chinese population.The objective of this study was to investigate the effects of oatβ-glucan-based prebiotic blended formulas in humans on digestive health by assessing defecation frequency,defecation symptoms,stool quality,self-reported digestive feelings,defecation satisfaction,and gut bacteria.A parallel,randomized,double-blind,controlled trial was conducted in 168 eligible adults randomized to 3 groups for 14 days:Intervention groups A and B received 2 different doses of oatβ-glucan-based prebiotic blended formulas and a Control group received oatβ-glucan mixed with hydroxypropylmethyl-cellulose and microcrystalline cellulose.Participants completed a defecation diary and Bristol stool chart daily and digestive system questionnaires weekly.Fecal samples were collected on day 0 and day 14 to evaluate gut bacteria using 16S rDNA analysis.Both formulas improved defecation frequency,stool quality,defecation symptoms,defecation satisfaction,and on digestive health of human,compared with baseline(P<0.05).Both formulas led to increased quantities of Bifidobacterium and Akkermansia bacteria,compared to control,on day 14.This study therefore demonstrated the beneficial effects of oatβ-glucan-based prebiotic blended formulas on gut health in generally healthy Chinese adults.These formulas are a feasible nutritional strategy for digestive health.
基金support by the Medical Subcenter of HUST Analytical&Testing Centersupported by the National Program for Support of Top-notch Young Professionals(No.0106514050)+4 种基金the National Natural Science Foundation of China(Nos.82273811 and U22A20380)the Hubei Provincial Natural Science Foundation of China(No.2024AFA028)the National Key Research and Development Program of China(No.2021YFA0910500)the Major Science and Technology Project of Hubei Province(No.2021ACA012)TongjiRongcheng Center for Biomedicine,Huazhong University of Science and Technology.
文摘In the twenty-first century,we have witnessed multiple coronavirus pandemics.Despite declining SARS-CoV-2 cases,continued research remains vital.We report the discovery of sydowiol B,a natural product,as a dual inhibitor of SARS-CoV-2 main protease(Mpro)and papain-like protease(PLpro).Sydowiol B interacts with the nano-channel at the Mpro dimer interface and the PLpro active site.Molecular dynamics simulations suggest that sydowiol B inhibits Mpro by limiting active site expansion rather than inducing collapse.Furthermore,sydowiol B binding may amplify the fluctuation of two loops coordinating with the structural Zn^(2+)in PLpro,displacing Zn^(2+)from the zinc finger domain to the S2 helix.Sydowiol B and its analogue,violaceol I,exhibit broad-spectrum antiviral activity against homologous coronaviruses.Given the conservation of Mpro and PLpro,sydowiol B and violaceol I are promising leads for designing and developing anti-coronavirus therapies.
基金supported by the National Key Research and Development Program of China (2018YFE0111600)Haihe Laboratory of Sustainable Chemical Transformations for financial supportpartially supported by the Graduate Top-notch Innovation Award Plan in Liberal Arts and Science of Tianjin University for the Year of 2023 (B2-2023-012)
文摘Li_(6)PS_(5)Cl is a highly wanted sulfide-solid-electrolyte(SSE)for developing all-solid-state lithium batteries,due to its high ionic conductivity,good processability and abundant compositional elements.However,its cyclability is poor because of harmful side reactions at the Li_(6)PS_(5)Cl/Li interface and growth of lithium dendrites inside Li_(6)PS_(5)Cl phase.Herein,we report a simple interface-engineering remedy to boost the electrochemical performance of Li_(6)PS_(5)Cl,by coating its surface with a Li-compatible electrolyte Li3OCl having low electronic conductivity.The obtainedLi_(6)PS_(5)Cl@Li_(3)OCl core@shell structure exhibits a synergistic effect.Consequently,compared with the bare Li_(6)PS_(5)Cl,this composite electrolyte exhibits great performance improvements:1)In Li|electrolyte|Li symmetric cells,the critical current density at 30℃gets increased from 0.6 mA cm^(-2)to 1.6 mA cm^(-2),and the lifetime gets prolonged from 320 h to 1400 h at the cycling current of 0.2 mA cm^(-2)or from 10 h to 900 h at the cycling current of 0.5 mA cm^(-2);2)In Li|electrolyte|NCM721 full cells running at 30℃,the cycling capacity at 0.2 C(or 0.5 C)gets enhanced by 20%(or from unfeasible to be feasible)for 100 cycles and the rate capability reaches up to 2 C from 0.2 C;and in full cells running at 60℃,the cycling capacity is increased by 7%at 0.2 C and the rate capability is enhanced to 3.0 C from 0.5 C.The experimental studies and theoretical computations show that the performance enhancements are due to the confined electron penetration and suppressed lithium dendrites growth at theLi_(6)PS_(5)Cl@Li_(3)OCl interface.
基金supported by the National Natural Science Foundation of China under Grant 62473328by the Open Research Fund of Jiangsu Collaborative Innovation Center for Smart Distribution Network,Nanjing Institute of Technology under No.XTCX202203.
文摘As future ship system,hybrid energy ship system has a wide range of application prospects for solving the serious energy crisis.However,current optimization scheduling works lack the consideration of sea conditions and navigational circumstances.There-fore,this paper aims at establishing a two-stage optimization framework for hybrid energy ship power system.The proposed framework considers multiple optimizations of route,speed planning,and energy management under the constraints of sea conditions during navigation.First,a complex hybrid ship power model consisting of diesel generation system,propulsion system,energy storage system,photovoltaic power generation system,and electric boiler system is established,where sea state information and ship resistance model are considered.With objective optimization functions of cost and greenhouse gas(GHG)emissions,a two-stage optimization framework consisting of route planning,speed scheduling,and energy management is constructed.Wherein the improved A-star algorithm and grey wolf optimization algorithm are introduced to obtain the optimal solutions for route,speed,and energy optimization scheduling.Finally,simulation cases are employed to verify that the proposed two-stage optimization scheduling model can reduce load energy consumption,operating costs,and carbon emissions by 17.8%,17.39%,and 13.04%,respectively,compared with the non-optimal control group.
基金supported by the National Natural Science Foundation of China(No.22176206).
文摘Reactive oxygen species(ROS)are closely related to cell death,proliferation and inflammation.However,excessive ROS levels may exceed the cellular oxidative capacity and cause irreversible damage.Organisms are often inadvertently exposed to nanomaterials(NMs).Therefore,elucidating the specific routes of ROS generation induced by NMs is crucial for comprehending the toxicity mechanisms of NMs and regulating their potential applications.This paper provides a comprehensive review of the toxicity mechanisms and applications of NMs from three perspectives:(1)Organelle perspective.Investigating the impact of NMmediated ROS onmitochondria,unravelingmechanisms at the organelle level.(2)NMs’perspective.Exploring the broad applications and biosafety considerations of Nanozymes,a unique class of NMs.(3)Cellular system.Examining the toxic effects and mechanisms of NMs in cells at a holistic cellular level.Expanding on these perspectives,the paper scrutinizes the regulation of Fenton reactions by NMs in organisms.Furthermore,it introduces diseases resulting fromNM-mediated ROS at the organism level.This comprehensive review aims to provide valuable insights for studying NM-mediated mechanisms at both cellular and organism levels,offering considerations for the safe design of nanomaterials.
基金supported by National Natural Science Foundation of China (32172747 and 32425052)
文摘Background Early embryo development plays a pivotal role in determining pregnancy outcomes,postnatal development,and lifelong health.Therefore,the strategic selection of functional nutrients to enhance embryo development is of paramount importance.In this study,we established a stable porcine trophectoderm cell line expressing dual fluorescent reporter genes driven by the CDX2 and TEAD4 gene promoter segments using lentiviral transfection.Results Three amino acid metabolites—kynurenic acid,taurine,and tryptamine—met the minimum z-score criteria of 2.0 for both luciferase and Renilla luciferase activities and were initially identified as potential metabolites for embryo development,with their beneficial effects validated by qPCR.Given that the identified metabolites are closely related to methionine,arginine,and tryptophan,we selected these three amino acids,using lysine as a standard,and employed response surface methodology combined with our high-throughput screening cell model to efficiently screen and optimize amino acid combination conducive to early embryo development.The optimized candidate amino acid system included lysine(1.87 mmol/L),methionine(0.82 mmol/L),tryptophan(0.23 mmol/L),and arginine(3 mmol/L),with the ratio of 1:0.43:0.12:1.60.In vitro experiments confirmed that this amino acid system enhances the expression of key genes involved in early embryonic development and improves in vitro embryo adhesion.Transcriptomic analysis of blastocysts suggested that candidate amino acid system enhances early embryo development by regulating early embryonic cell cycle and differentiation,as well as improving nutrient absorption.Furthermore,based on response surface methodology,400 sows were used to verify this amino acid system,substituting arginine with the more cost-effective N-carbamoyl glutamate(NCG),a precursor of arginine.The optimal dietary amino acid requirement was predicted to be 0.71%lysine,0.32%methionine,0.22%tryptophan,and 0.10%NCG for sows during early gestation.The optimized amino acid system ratio of the feed,derived from the peripheral release of essential amino acids,was found to be 1:0.45:0.13,which is largely consistent with the results obtained from the cell model optimization.Subsequently,we furtherly verified that this optimal dietary amino acid system significantly increased total litter size,live litter size and litter weight in sows.Conclusions In summary,we successfully established a dual-fluorescent high-throughput screening cell model for the efficient identification of potential nutrients that would promote embryo development and implantation.This innovative approach overcomes the limitations of traditional amino acid nutrition studies in sows,providing a more effective model for enhancing reproductive outcomes.
基金National Key Research and Development Program of China(2022YFC3502302)Graduate Research Innovation Program of Jiangsu Province(KYCX25_2269)。
文摘Objective To develop a facial image generation method based on a facial color-preserving generative adversarial network(FCP-GAN)that effectively decouples identity features from diagnostic facial complexion characteristics in traditional Chinese medicine(TCM)inspection,thereby addressing the critical challenge of privacy preservation in medical image analysis.Methods A facial image dataset was constructed from participants at Nanjing University of Chinese Medicine between April 23 and June 10,2023,using a TCM full-body inspection data acquisition equipment under controlled illumination.The proposed FCP-GAN model was designed to achieve the dual objectives of removing identity features and preserving colors through three key components:(i)a multi-space combination module that comprehensively extracts color attributes from red,green,blue(RGB),hue,saturation,value(HSV),and Lab spaces;(ii)a generator incorporating efficient channel attention(ECA)mechanism to enhance the representation of diagnostically critical color channels;and(iii)a dual-loss function that combines adversarial loss for de-identification with a dedicated color preservation loss.The model was trained and evaluated using a stratified 5-fold cross-validation strategy and evaluated against four baseline generative models:conditional GAN(CGAN),deep convolutional GAN(DCGAN),dual discriminator CGAN(DDCGAN),and medical GAN(MedGAN).Performance was assessed in terms of image quality[peak signal-to-noise ratio(PSNR)and structural similarity(SSIM)],distribution similarity[Fréchet inception distance(FID)],privacy protection(face recognition accuracy),and diagnostic consistency[mean squared error(MSE)and Pearson correlation coefficient(PCC)].Results The final analysis included facial images from 216 participants.Compared with baseline models,FCP-GAN achieved superior performance,with PSNR=31.02 dB and SSIM=0.908,representing an improvement of 1.21 dB and 0.034 in SSIM over the strongest baseline(MedGAN).The FID value(23.45)was also the lowest among all models,indicating superior distributional similarity to real images.The multi-space feature fusion and the ECA mechanism contributed significantly to these performance gains,as evidenced by ablation studies.The stratified 5-fold cross-validation confirmed the model’s robustness,with results reported as mean±standard deviation(SD)across all folds.The model effectively protected privacy by reducing face recognition accuracy from 95.2%(original images)to 60.1%(generated images).Critically,it maintained high diagnostic fidelity,as evidenced by a low MSE(<0.051)and a high PCC(>0.98)for key TCM facial features between original and generated images.Conclusion The FCP-GAN model provides an effective technical solution for ensuring privacy in TCM diagnostic imaging,successfully having removed identity features while preserving clinically vital facial color features.This study offers significant value for developing intelligent and secure TCM telemedicine systems.
基金the National Natural Science Foundation of China(22075114,32371434,82301630)the Natural Science Foundation of Jiangsu Province(BK20211034)the financial support from Jiangsu Provincial Medical Key Laboratory(Key Laboratory of Nuclear Medicine).
文摘Nitric oxide(NO)modulates several cancer-related physiological processes and has advanced the development of green methods for cancer treatment and integrated platforms for combination or synergistic therapies.Although a nanoengineering strategy has been proposed to overcome deficiencies of NO gas or small NO donor molecules,such as short half-life,lipophilicity,non-selectivity,and poor stability,it remains challenging to prepare NO nanomedicines with simple composition,multiple functions and enhanced therapeutic efficacy.Herein,we build a liquid metal nanodroplet(LMND)-based NO nanogenerator(LMND@HSG)that is stabilized by a bioreducible guanylated hyperbranched poly(amido amine)(HSG)ligand.Mechanically,the tumor microenvironment specifically triggers a cascade process of glutathione elimination,reactive oxygen species(ROS)generation,and NO release.According to actual demand,the ROS and NO concentrations could be readily controlled by tuning the LMND and HSG feed amounts.Along with the intrinsic anticancer property of LMND(ROS-mediated apoptosis and anti-angiogenesis),LMND@HSG administration could further enhance tumor growth suppression compared with LMND and HSG alone.Fromthis study,leveraging LMND for NO gas therapy provides more possibilities for the prospect of LMND-based anticancer nanomedicines.
基金supported by the National Natural Science Foundation of China(Nos.52100087,52170079,U20A20322)Science and Technology Development Program of Jilin Province,China(Nos.20220508100RC,20230402035GH).
文摘Rational tuning of crystallographic surface and metal doping were effective to enhance the catalytic performance of metal organic frameworks,but limited work has been explored for achieving modulation of crystal facets and metal doping in a single system.MIL-68(In)was promising for photocatalytic applications due to its low toxicity and excellent photoresponsivity.However,its catalytic activity was constrained by severe carrier recombination and a lack of active sites.Herein,increased(001)facet ratio and active sites exposure were simultaneously realized by cobalt doping in MIL-68(In)through a one-pot solvothermal strategy.Optimized MIL-68(In/Co)-2.5 exhibited remarkable catalytic performance in comparison with pristine MIL-68(In)and other MIL-68(In/Co).The reaction kinetic constant and degradation efficiency of MIL-68(In/Co)were approximately twice and 17%higher than the pristine MIL-68(In)in 36 min reaction,respectively.Density functional theory calculations revealed that Co dopant could modulate the orientation of MIL-68(In)facets,facilitate the exchange of electrons and reduce the adsorption energy of peroxymonosulfate(PMS).This work provides a novel pathway for improvement of In-based MOFs in PMS/vis system,it also promotes the profound comprehension of the correlation between crystal facet regulation and catalytic activation in the PMS/vis system.
基金financial support from the National Natural Science Foundation of China(Nos.52203244,22101267)the Key Scientific and Technological Project of Henan Province(No.222102310683)+1 种基金the China Postdoctoral Science Foundation(Nos.2021M692905,2024T170832)Natural Science Foundation of Henan Province(Nos.242300421068,242300421123)。
文摘Since the discovery of carbonized polymer dots(CPDs)two decades ago,this emerging family of carbonbased nanomaterials has rapidly risen to prominence.CPDs have found widespread applications in sensing,catalysis,energy,and biomedicine due to their flexible precursors and synthesis methods,tunable photoluminescence(PL)properties,and excellent biocompatibility.This report presents the advancements made in the realm of CPD precursors,elucidates their luminescence properties and underlying mechanisms,and explores the diverse applications of CPD-based materials.It comprehensively addresses key issues by delving into several interconnected chapters:Initially exploring the intriguing fluorescence and afterglow properties exhibited by CPDs,subsequently unraveling the complex luminescence mechanisms that underlie these phenomena,emphasizing the crucial aspect of controllable synthesis of CPDs,and ultimately culminating in the precise construction of composite materials tailored for applications in laser and electroluminescent devices.Furthermore,this report aims to provide communication and assistance for the controlled synthesis and expanded applications of CPDs.
基金supported by Youth Fund of National Natural Science Foundation of China(NO.22108175)Basic scientific research Project of colleges and universities of Liaoning Provincial Department of Educa-tion(No.LJKMZ20220798)+1 种基金National Natural Science Foundation of China(No.U1903130)Natural Science Foundation of Liaoning province(No.2021-NLTS-12-09),China,and JST Grant Number JPMJPF2104,Japan.
文摘Gasification is a highly effective technology for converting biomass into fuel gas or syngas.While various gas-ifiers have been commercialized for fuel gas production,mitigating tar formation in gasifiers remains chal-lenging.This review is devoted to summarizing the general strategies adopted in various gasifiers to reduce tar formation for high-efficiency clean gasification.For single-bed and staged-gasification processes,their low-tar strategies are typically different.In the single-bed processes,the low-tar strategies involve in-bed intensifica-tion achieved by controlling flow directions of gas and particles inside the gasifier.During the gasification,these two components often have different temperatures to facilitate thermochemical interactions between them.Meanwhile,the two-stage gasifiers are generally designed to decouple pyrolysis,gasification and tar cracking reactions for maximizing the benefits(such as yield and efficiency)realized from the interactions among these reactions.In addition to minimizing tar formation,the approach of reaction decoupling can also raise the calorific value of product gas,even without use of oxygen,and/or improve the adaptability of gasification technology to the feedstocks with various moisture contents and particle sizes.The reanalysis based on those essential low-tar strategies is expected to gain alternative insights into the reaction principles implicated in most advanced biomass gasification technologies.
基金supported by Science&Technology Department of Sichuan Province(No.2023YFS0389)Chengdu Technology Innovation Research and Development Project of Chengdu Science and Technology Bureau(No.2022-YF05-00307-SN).
文摘Nanoplastics exhibit greater environmental biotoxicity than microplastics and can be ingested by humans through major routes such as tap water,bottled water and other drinking water.Nanoplastics present a challenge for air flotation due to their minute particle size,negative surface potential,and similar density to water.This study employed dodecyltrimethylammonium chloride(DTAC)as a modifier to improve conventional air flotation,which significantly enhanced the removal of polystyrene nanoplastics(PSNPs).Conventional air flotation removed only 3.09%of PSNPs,while air flotation modified by dodecyltrimethylammonium chloride(DTAC-modified air flotation)increased the removal of PSNPs to 98.05%.The analysis of the DTAC-modified air flotation mechanism was conducted using a combination of instruments,including a zeta potential analyzer,contact angle meter,laser particle size meter,high definition camera,scanning electron microscope(SEM),energy dispersive spectrometer(EDS)and Fourier transform infrared spectrometer(FTIR).The results indicated that the incorporation of DTAC reversed the electrostatic repulsion between bubbles and PSNPs to electrostatic attraction,significantly enhancing the hydrophobic force in the system.This,in turn,improved the collision adhesion effect between bubbles and PSNPs.The experimental results indicated that even when the flotation time was reduced to 7min,the DTACmodified air flotation still achieved a high removal rate of 96.26%.Furthermore,changes in aeration,pH,and ionic strength did not significantly affect the performance of the modified air flotation for the removal of PSNPs.The removal rate of PSNPs in all three water bodies exceeded 95%.The DTAC-modified air flotation has excellent resistance to interference from complex conditions and shows great potential for practical application.
