The early developmental period is a critical window during which brain cells mature and contribute to both brain development and later life functions.Gamma-aminobutyric acid(GABA),recognized as a major neurotransmitte...The early developmental period is a critical window during which brain cells mature and contribute to both brain development and later life functions.Gamma-aminobutyric acid(GABA),recognized as a major neurotransmitter,plays a crucial role in coordinating synapse formation,neuronal proliferation,and migration during this time.展开更多
Contrary to the adult central nervous system,the peripheral nervous system has an intrinsic ability to regenerate that relies on the expression of regenerationassociated genes,such as some kinesin family members.Kines...Contrary to the adult central nervous system,the peripheral nervous system has an intrinsic ability to regenerate that relies on the expression of regenerationassociated genes,such as some kinesin family members.Kinesins contribute to nerve regeneration through the transport of specific cargo,such as proteins and membrane components,from the cell body towards the axon periphery.We show here that KIF4A,associated with neurodevelopmental disorders and previously believed to be only expressed during development,is also expressed in the adult vertebrate nervous system and up-regulated in injured peripheral nervous system cells.KIF4A is detected both in the cell bodies and regrowing axons of injured neurons,consistent with its function as an axonal transporter of cargoes such asβ1-integrin and L1CAM.Our study further demonstrates that KIF4A levels are greatly increased in Schwann cells from injured distal nerve stumps,particularly at a time when they are reprogrammed into an essential proliferative repair phenotype.Moreover,Kif4a m RNA levels were approximately~6-fold higher in proliferative cultured Schwann cells compared with non-proliferative ones.A hypothesized function for Kif4a in Schwann cell proliferation was further confirmed by Kif4a knockdown,as this significantly reduced Schwann cell proliferation in vitro.Our findings show that KIF4A is expressed in adult vertebrate nervous systems and is up-regulated following peripheral injury.The timing of KIF4A up-regulation,its location during regeneration,and its proliferative role,all suggest a dual role for this protein in neuroregeneration that is worth exploring in the future.展开更多
Influenza,a highly contagious respiratory infectious disease caused by an influenza virus,is a threat to public health worldwide.Avian influenza viruses(AIVs)have the potential to cause the next pandemic by crossing t...Influenza,a highly contagious respiratory infectious disease caused by an influenza virus,is a threat to public health worldwide.Avian influenza viruses(AIVs)have the potential to cause the next pandemic by crossing the species barrier through mutation of viral genome.Here,we investigated the pathogenicity of AIVs obtained from South Korea and Mongolia during 2018–2019 by measuring viral titers in the lungs and extrapulmonary organs of mouse models.In addition,we assessed the pathogenicity of AIVs in ferret models.Moreover,we compared the ability of viruses to replicate in mammalian cells,as well as the receptor-binding preferences of AIV isolates.Genetic analyses were finally performed to identify the genetic relationships and amino acid substitutions between viral proteins during mammalian adaptation.Of the 24 AIV isolates tested,A/Mallard/South Korea/KNU2019-34/2019(KNU19-34;H1N1)caused severe bodyweight loss and high mortality in mice.The virus replicated in the lungs,kidneys,and heart.Importantly,KNU19-34-infected ferrets showed high viral loads in both nasal washes and lungs.KNU19-34 replicated rapidly in A549 and bound preferentially to human likeα2,6-linked sialic acids rather than to avian-likeα2,3-linked sialic acids,similar to the pandemic A/California/04/2009(H1N1)strain.Gene segments of KNU19-34 were distributed in Egypt and Asia lineages from 2015 to 2018,and the virus had several amino acid substitutions compared to H1N1 AIV isolates that were non-pathogenic in mice.Collectively,the data suggest that KNU19-34 has zoonotic potential and the possibility of new mutations responsible for mammalian adaptation.展开更多
The experiment addressed the effects of preharvest KH_(2)PO_(4)foliar spraying(20 mmol·L^(-1))on fruit quality and composition(including volatile organic compounds,VOCs)of cherry tomatoes(‘Caravaggio’,‘Sugarl...The experiment addressed the effects of preharvest KH_(2)PO_(4)foliar spraying(20 mmol·L^(-1))on fruit quality and composition(including volatile organic compounds,VOCs)of cherry tomatoes(‘Caravaggio’,‘Sugarland’and‘Top Stellina’)after 0(S0),7(S7)and 14 days(S14)of storage at 8.0°C.On the average of the 3 genotypes,the KH_(2)PO_(4)treatment improved fruit pressure firmness,total soluble solids(TSS),titratable acidity(TA),total phenols and carotenoids concentrations,along with the fruits'antioxidant capacity(by up to 17%for FRAP assay).Within the S7–S14 period,control fruits showed the highest reductions in TSS,TSS/TA ratio and total carotenoids(-17,-12 and-45,respectively),whereas treated fruits proved the strongest increase in DPPH(+12%).Sixteen out of 32 VOCs were promoted following KH_(2)PO_(4)application,including the aldehydes hexanal,(E)-2-hexenal and(Z)-3-hexenal and the apocarotenoids(E)-citral,(E)-β-ionone,geranylacetone and 6-methyl-5-hepten-2-one.Proceeding from S0 to S14,several VOCs decreased more strongly in control fruits,as for hexanal(-48%)and total aldehydes(-42%,whereas at S14 treated fruits had higher concentrations of linalool,geranylacetone and 6-methyl-5-hepten-2-one(1.06,52.50 and 79.27μg·kg^(-1),respectively).‘Caravaggio’demonstrated the strongest apocarotenoid reduction at S14,whereas‘Top Stellina’was more responsive to KH_(2)PO_(4)(mainly forβ-cyclocitral,geranylacetone and total terpenes/terpenoids),thus highlighting the central role of the genotype in responding to other experimental factors.Nonetheless,these results suggest that proper preharvest KH_(2)PO_(4)applications can preserve specific commercial,nutritional and quality traits of cold-stored cherry tomatoes.展开更多
The gut-skin axis(GSA)embodies a complex,bidirectional interaction between the gastrointestinal(GI)system and skin,driven by immune modulation,systemic inflammation,and gut microbiota dynamics.Disruptions in gut homeo...The gut-skin axis(GSA)embodies a complex,bidirectional interaction between the gastrointestinal(GI)system and skin,driven by immune modulation,systemic inflammation,and gut microbiota dynamics.Disruptions in gut homeostasis,including dysbiosis and increased intestinal permeability,are increasingly recognized as contributing factors to dermatological conditions such as acne,psoriasis,and atopic dermatitis.For gastroenterologists,appreciating this interplay is essential,as diseases and their treatments frequently present with cutaneous manifestations,offering diagnostic and therapeutic insights.This review explores the underlying mechanisms of the GSA,focusing on the microbiome and its metabolites as key regulators of inflammation and immunity.It underscores the clinical importance of microbiome-targeted therapies,such as probiotics,prebiotics,and dietary modifications,in addressing both GI and dermatological disorders.Furthermore,the review examines the influence of GI conditions,including inflammatory bowel disease and celiac disease on skin health.This article seeks to equip gastroenterologists with practical insights for identifying,diagnosing,and managing skin conditions associated with GI health.The article also highlights the current limitations in knowledge regarding the GSA.The GSA represents a promising avenue for therapeutic advancements,encouraging interdisciplinary collaboration between gastroenterology and dermatology to optimize patient care.展开更多
Prosthetic devices designed to assist individuals with damaged or missing body parts have made significant strides,particularly with advancements in machine intelligence and bioengineering.Initially focused on movemen...Prosthetic devices designed to assist individuals with damaged or missing body parts have made significant strides,particularly with advancements in machine intelligence and bioengineering.Initially focused on movement assistance,the field has shifted towards developing prosthetics that function as seamless extensions of the human body.During this progress,a key challenge remains the reduction of interface artifacts between prosthetic components and biological tissues.Soft electronics offer a promising solution due to their structural flexibility and enhanced tissue adaptability.However,achieving full integration of prosthetics with the human body requires both artificial perception and efficient transmission of physical signals.In this context,synaptic devices have garnered attention as next-generation neuromorphic computing elements because of their low power consumption,ability to enable hardware-based learning,and high compatibility with sensing units.These devices have the potential to create artificial pathways for sensory recognition and motor responses,forming a“sensory-neuromorphic system”that emulates synaptic junctions in biological neurons,thereby connecting with impaired biological tissues.Here,we discuss recent developments in prosthetic components and neuromorphic applications with a focus on sensory perception and sensorimotor actuation.Initially,we explore a prosthetic system with advanced sensory units,mechanical softness,and artificial intelligence,followed by the hardware implementation of memory devices that combine calculation and learning functions.We then highlight the importance and mechanisms of soft-form synaptic devices that are compatible with sensing units.Furthermore,we review an artificial sensory-neuromorphic perception system that replicates various biological senses and facilitates sensorimotor loops from sensory receptors,the spinal cord,and motor neurons.Finally,we propose insights into the future of closed-loop neuroprosthetics through the technical integration of soft electronics,including bio-integrated sensors and synaptic devices,into prosthetic systems.展开更多
We study the production of the X(6900)in the ultra-peripheral heavy ion collisions at the LHC energy region.The potential quantum numbers of X(6900)could be 0^(±+)and 2^(±+).We find that the transverse momen...We study the production of the X(6900)in the ultra-peripheral heavy ion collisions at the LHC energy region.The potential quantum numbers of X(6900)could be 0^(±+)and 2^(±+).We find that the transverse momentum and the polar angle distributions of X(6900)can be used to distinguish these four potential quantum numbers.These characteristic distributions originate from linearly polarized photons emitted by relativistic nuclei and can be measured by further LHC experiments.展开更多
Aqueous batteries,renowned for their cost-effectiveness and non-flammability,have attracted considerable attention in the realm of batteries featuring Zn-based and Sn-based configurations.These configurations employ Z...Aqueous batteries,renowned for their cost-effectiveness and non-flammability,have attracted considerable attention in the realm of batteries featuring Zn-based and Sn-based configurations.These configurations employ Zn and Sn metal anodes,respectively.While the growth patterns of Zn under various current densities have been extensively studied,there has been a scarcity of research on Sn dendrite growth.Our operando imaging analysis reveals that,unlike Zn,Sn forms sharp dendrites at high current density emphasizing the crucial necessity for implementing strategies to suppress the dendrites formation.To address this issue,we introduced a carbon nanotube(CNT)layer on copper foil,effectively preventing the formation of Sn dendrites under high current density,thus enabling the high-current operation of Sn metal batteries.We believe that our work highlights the importance of suppressing dendrite formation in aqueous Sn metal batteries operating at high current density and introduces a fresh perspective on mitigating Sn dendrite formation.展开更多
Two-dimensional(2D)nitride MXenes are predicted to exhibit exceptional metallic properties and high polarity;however,their synthesis remains challenging.Research has relied on traditional molten salt etching,highlight...Two-dimensional(2D)nitride MXenes are predicted to exhibit exceptional metallic properties and high polarity;however,their synthesis remains challenging.Research has relied on traditional molten salt etching,highlighting the need for a scalable,high-purity approach.Here,we present the first solution-based synthesis of Ti_(4)N_(3)T_(x)MXene via a novel saturated salt solution(S^(3))etching technique employing alkali metal salts.By optimizing the sintering process for high-purity Ti_(4)AlN_(3)MAX and refining the S^(3)etching route,we significantly reduced the etch pit density to 1.2×10^(6)cm^(-2)and lowered the etch pit formation rate to 4%,yielding high-quality,phasepure Ti_(4)N_(3)T_(x)MXene.Our study highlights the critical role of alkali metal ions in selective A-layer removal and demonstrates the impressive electrical conductivity and electromagnetic interference shielding performance of 2D nitride MXene,setting a new benchmark for this underexplored material.These findings pave the way for advancing 2D nitride MXenes and their diverse applications.展开更多
Fabricating a durable electrocatalyst with performance comparable to noble metals for the alkaline hydrogen evolution reaction(HER)remains a significant challenge.In this work,we introduce a highly efficient and robus...Fabricating a durable electrocatalyst with performance comparable to noble metals for the alkaline hydrogen evolution reaction(HER)remains a significant challenge.In this work,we introduce a highly efficient and robust electrocatalyst by incorporating rhenium(Re)atoms into CoS nanoflakes(Re-CoS)for alkaline HER.The incorporation of Re atoms into the CoS lattice enhances the hybridization of Co 3d and S 2p orbitals,resulting in an optimized electronic structure that accelerates water dissociation on Co sites and optimizes hydrogen adsorptiondesorption on S sites,thereby boosting the HER rate.The optimal Re-CoS catalyst demonstrates a low overpotential of 72 mV at 10 mA cm^(-2)in 1 M KOH,along with excellent long-term stability,maintaining its catalytic activity over 200 h without significant degradation.These results suggest that the incorporation of Re atoms into CoS effectively couples the water dissociation and hydrogen addesorption steps of alkaline HER,offering a promising strategy for the development of noble metal-like electrocatalysts.展开更多
Understanding the degradation phenomenon of proton exchange membrane fuel cells under electrochemical cycling requires an analysis of the porous carbon support structure.Key factors contributing to this phenomenon inc...Understanding the degradation phenomenon of proton exchange membrane fuel cells under electrochemical cycling requires an analysis of the porous carbon support structure.Key factors contributing to this phenomenon include changes in the total porosity and viable surface area for electrochemical reactions.Electron tomography-based serial section imaging using focused ion beam-scanning electron microscopy(FIB-SEM)can elucidate this phenomenon at a nanoscale resolution.However,this highresolution tomographic analysis requires a huge image dataset and manual inputs in rule-based workflows;these requirements are time-consuming and often cause experimental difficulties and unreliable interpretations.We propose a deep learning-empowered approach comprising a two-step automated process for image interpolation and semantic segmentation to address the practical issues encountered in FIB-SEM electron tomography.An optimally trained interpolation model can reduce the image data requirement by more than 95%to analyze the structural degradation of carbon supports after electrochemical cycling while maintaining the reliability obtained in conventional tomographic analysis with several hundred images.Because the subsequent image segmentation model excludes a complicated manual filtering process,the relevant structural parameters can be reliably measured without human bias.Our sparse-section imaging-based deep learning process can allow cost-efficient analysis and reliable measurement of the degree of cycling-induced carbon corrosion.展开更多
The exploration of heterostructures composed of two-dimensional(2D)transition metal dichalcogenide(TMDc)materials has garnered significant research attention due to the distinctive properties of each individual compon...The exploration of heterostructures composed of two-dimensional(2D)transition metal dichalcogenide(TMDc)materials has garnered significant research attention due to the distinctive properties of each individual component and their phase-dependent unique properties.Using the plasma-enhanced chemical vapor deposition(PECVD)method,we analyze the fabrication of heterostructures consisting of two phases of molybdenum disulfide(MoS_(2))in four different cases.The initial hydrogen evolution reaction(HER)polarization curve indicates that the activity of the heterostructure MoS_(2)is consistent with that of the underlying MoS_(2),rather than the surface activity of the upper MoS_(2).This behavior can be attributed to the presence of Schottky barriers,which include contact resistance,which significantly hampers the efficient charge transfer at junctions between the two different phases of MoS_(2)layers and is mediated by van der Waals bonds.Remarkably,the energy barrier at the junction dissipates upon reaching a certain electrochemical potential,indicating surface activation from the top phase of MoS_(2)in the heterostructure.Notably,the 1T/2H MoS_(2)heterostructure demonstrates enhanced electrochemical stability compared to its metastable 1T-MoS_(2).This fundamental understanding paves the way for the creation of phase-controllable heterostructures through an experimentally viable PECVD,offering significant promise for a wide range of applications.展开更多
Trees,mammals,and microbes relate to soil carbon(C)cycle.Trees capture C,and mammals consume plants and other animals,both contributing to organic remains that are then degraded by soil microbes.This organic C can be ...Trees,mammals,and microbes relate to soil carbon(C)cycle.Trees capture C,and mammals consume plants and other animals,both contributing to organic remains that are then degraded by soil microbes.This organic C can be stored in soils or released into the atmosphere through microbial mineralization.Yet,the simultaneous effects of mammals and trees on C consumption by soil microbes have not been investigated.For 30 sampling sites in a mixed forest-savanna environment in southern Guyana,we jointly analyzed observational data of mammal and tree communities along with soil organic matter(SOM)composition(using Fourier transform infrared spectroscopy combined with attenuated total reflectance,energy dispersive X-ray fluorescence spectrometry,and CNH elemental analyzer)and soil microbial C consumption(using Biolog EcoPlates).It was found that higher mammal functional richness(FRic)and functional evenness(FEve)were related to reduced overall C consumption by soil microbes(for FRic:regression coefficient(β)=-0.010,standard error(SE)=0.005,P=0.034;for FEve:β=-0.012,SE=0.005,P=0.010)with the coefficient of determination(R^(2))value of 0.359,explaining 36%of the variance in average well color development values,whereas a higher tree richness was associated with a reduced diversity of C sources consumed by soil microbial communities(β=-0.353,SE=0.172,P=0.041)with the R2 value of 0.290,explaining 29%of the variance in Shannon diversity index values.Our results indicate that mammal and tree communities have complementary effects on soil microbial C consumption,improving our understanding of the functioning of C cycle in the high-diversity Amazon biome.These findings are crucial in elucidating the intricate connections between above-and belowground biodiversity that influence the accumulation and stabilization of soil organic C.展开更多
Background:Mammalian cells possess molecular clocks,the adequate functioning of which is decisive for metabolic health.Exercise is known to modulate these clocks,potentially having distinct effects on metabolism depen...Background:Mammalian cells possess molecular clocks,the adequate functioning of which is decisive for metabolic health.Exercise is known to modulate these clocks,potentially having distinct effects on metabolism depending on the time of day.This study aimed to investigate the impact of morning vs.evening moderate-intensity aerobic exercise on glucose regulation and energy metabolism in healthy men and women.It also aimed to elucidate molecular mechanisms within skeletal muscle.Methods:Using a randomized crossover design,healthy men(n=18)and women(n=17)performed a 60-min bout of moderate-intensity aerobic exercise in the morning and evening.Glucose regulation was continuously monitored starting 24 h prior to the exercise day and continuing until 48 h post-exercise for each experimental condition.Energy expenditure and substrate oxidation were measured by indirect calorimetry during exercise and at rest before and after exercise for 30 min.Skeletal muscle biopsies were collected immediately before and after exercise to assess mitochondrial function,transcriptome,and mitochondrial proteome.Results:Results indicated similar systemic glucose,energy expenditure,and substrate oxidation during and after exercise in both sexes.Notably,transcriptional analysis,mitochondrial function,and mitochondrial proteomics revealed marked sexual dimorphism and time of day variations.Conclusion:The sexual dimorphism and time of day variations observed in the skeletal muscle in response to exercise may translate into observable systemic effects with higher exercise-intensity or chronic exercise interventions.This study provides a foundational molecular framework for precise exercise prescription in the clinical setting.展开更多
Background There is insufficient evidence to provide recommendations for leisure-time physical activity among workers across various occupational physical activity levels.This study aimed to assess the association of ...Background There is insufficient evidence to provide recommendations for leisure-time physical activity among workers across various occupational physical activity levels.This study aimed to assess the association of leisure-time physical activity with cardiovascular and all-cause mortality across occupational physical activity levels.Methods This study utilized individual participant data from 21 cohort studies,comprising both published and unpublished data.Eligibility criteria included individual-level data on leisure-time and occupational physical activity(categorized as sedentary,low,moderate,and high)along with data on all-cause and/or cardiovascular mortality.A 2-stage individual participant data meta-analysis was conducted,with separate analysis of each study using Cox proportional hazards models(Stage 1).These results were combined using random-effects models(Stage 2).Results Higher leisure-time physical activity levels were associated with lower all-cause and cardiovascular mortality risk across most occupational physical activity levels,for both males and females.Among males with sedentary work,high compared to sedentary leisure-time physical activity was associated with lower all-cause(hazard ratios(HR)=0.77,95%confidence interval(95%CI):0.70-0.85)and cardiovascular mortality(HR=0.76,95%CI:0.66-0.87)risk.Among males with high levels of occupational physical activity,high compared to sedentary leisure-time physical activity was associated with lower all-cause(HR=0.84,95%CI:0.74-0.97)and cardiovascular mortality(HR=0.79,95%CI:0.60-1.04)risk,while HRs for low and moderate levels of leisure-time physical activity ranged between 0.87 and 0.97 and were not statistically significant.Among females,most effects were similar but more imprecise,especially in the higher occupational physical activity levels.Conclusion Higher levels of leisure-time physical activity were generally associated with lower mortality risks.However,results for workers with moderate and high occupational physical activity levels,especially women,were more imprecise.Our findings suggests that workers may benefit from engaging in high levels of leisure-time physical activity,irrespective of their level of occupational physical activity.展开更多
基金supported by the Center for Cognition and Sociality,Institute for Basic Science(IBS)(IBS-R001-D2)(to WK).
文摘The early developmental period is a critical window during which brain cells mature and contribute to both brain development and later life functions.Gamma-aminobutyric acid(GABA),recognized as a major neurotransmitter,plays a crucial role in coordinating synapse formation,neuronal proliferation,and migration during this time.
基金supported by the Portuguese Foundation for Science and Technology(FCT),Centro 2020 and Portugol2020 and the EU FEDER program,via the project GoBack to SIV(PTDC/CVT-CVT/32261/2017,CENTRO-01-0145-FEDER-032261)the doctoral grants of PDC(SFRH/BD/139974/2018)and BMS(2020.06525.BD and DOI 10.54499/2020.06525.BD)+5 种基金the post-doctoral grant to JPF(SFRH/BPD/113359/2015-program-contract described in paragraphs 4,5,6 of art.23 of Law no.100157/2016,of August 29,as amended by Law no.57/2017 of July 2019),the project PTDC/MED-NEU/1677/2021 to JBRthe Institute of Biomedicine iBiMED(UIDB/04501/2020 and DOI 10.54499/UIDB/04501/2020,UIDP/04501/2020 and DOI 10.54499/UIDP/04501/2020)its LiM Bioimaging Facility-a PPBI node(POCI-01-0145-FEDER-022122)supported by the Research Commission of the Medical Faculty of the Heinrich-Heine-University(HHU)Düsseldorf,of the Biologisch-Medizinisches Forschungszentrum(BMFZ)of HHUfinanced by the Spanish"Plan Nacional de Investigacion Cientifica,Desarrollo e Innovacion Tecnologica,Ministerio de Economia y Competitividad(Instituto de Salud CarlosⅢ)",co-financed by the European Union(FEDER program),(grant FIS P/20/00318 and FIS P23/00337 to VC)grant CPP2021-009070 to VC by the"Proyectos de colaboracion publico-privada,Plan de Investigacion Cientifica,Tecnica y de inovacion 2021-2023,Ministerio de Ciencia e Innovacion,Union Europea,Agencia Estatal de Investigacion,Espana"。
文摘Contrary to the adult central nervous system,the peripheral nervous system has an intrinsic ability to regenerate that relies on the expression of regenerationassociated genes,such as some kinesin family members.Kinesins contribute to nerve regeneration through the transport of specific cargo,such as proteins and membrane components,from the cell body towards the axon periphery.We show here that KIF4A,associated with neurodevelopmental disorders and previously believed to be only expressed during development,is also expressed in the adult vertebrate nervous system and up-regulated in injured peripheral nervous system cells.KIF4A is detected both in the cell bodies and regrowing axons of injured neurons,consistent with its function as an axonal transporter of cargoes such asβ1-integrin and L1CAM.Our study further demonstrates that KIF4A levels are greatly increased in Schwann cells from injured distal nerve stumps,particularly at a time when they are reprogrammed into an essential proliferative repair phenotype.Moreover,Kif4a m RNA levels were approximately~6-fold higher in proliferative cultured Schwann cells compared with non-proliferative ones.A hypothesized function for Kif4a in Schwann cell proliferation was further confirmed by Kif4a knockdown,as this significantly reduced Schwann cell proliferation in vitro.Our findings show that KIF4A is expressed in adult vertebrate nervous systems and is up-regulated following peripheral injury.The timing of KIF4A up-regulation,its location during regeneration,and its proliferative role,all suggest a dual role for this protein in neuroregeneration that is worth exploring in the future.
基金funded by grants from the National Research Foundation of Korea(NRF)grant funded by the Korea government(2018M3A9H4055203 and 2023R1A2C2003679)from the Korea Health Technology R&D Project through the Korea Health Industry Development Institute(KHIDI),funded by the Ministry of Health&Welfare,Republic of Korea(HV23C1857)from KRIBB Research Initiative Program(KGM9942421).
文摘Influenza,a highly contagious respiratory infectious disease caused by an influenza virus,is a threat to public health worldwide.Avian influenza viruses(AIVs)have the potential to cause the next pandemic by crossing the species barrier through mutation of viral genome.Here,we investigated the pathogenicity of AIVs obtained from South Korea and Mongolia during 2018–2019 by measuring viral titers in the lungs and extrapulmonary organs of mouse models.In addition,we assessed the pathogenicity of AIVs in ferret models.Moreover,we compared the ability of viruses to replicate in mammalian cells,as well as the receptor-binding preferences of AIV isolates.Genetic analyses were finally performed to identify the genetic relationships and amino acid substitutions between viral proteins during mammalian adaptation.Of the 24 AIV isolates tested,A/Mallard/South Korea/KNU2019-34/2019(KNU19-34;H1N1)caused severe bodyweight loss and high mortality in mice.The virus replicated in the lungs,kidneys,and heart.Importantly,KNU19-34-infected ferrets showed high viral loads in both nasal washes and lungs.KNU19-34 replicated rapidly in A549 and bound preferentially to human likeα2,6-linked sialic acids rather than to avian-likeα2,3-linked sialic acids,similar to the pandemic A/California/04/2009(H1N1)strain.Gene segments of KNU19-34 were distributed in Egypt and Asia lineages from 2015 to 2018,and the virus had several amino acid substitutions compared to H1N1 AIV isolates that were non-pathogenic in mice.Collectively,the data suggest that KNU19-34 has zoonotic potential and the possibility of new mutations responsible for mammalian adaptation.
基金funded by the National Recovery and Resilience Plan(NRRP),Mission 4 Component 2 Investment 1.3—Call for proposals No.341 of 15 March 2022 of Italian Ministry of University and Research funded by the European Union—NextGenerationEU,Award Number:Project code PE00000003Concession Decree No.1550 of 11 October 2022 adopted by the Italian Ministry of University and Research,CUP E63C22002060006+1 种基金Project title“ON Foods—Research and innovation network on food and nutrition Sustainability,Safety and Security—Working ON Foodsfunded by the Italian Ministry of University and Research(MUR)under the project“Conservabilità,qualitàe sicurezza dei prodotti ortofrutticoli ad alto contenuto di servizio-ARS01_00640–POFACS”(Grant Nos.D.D.1211/2020 and 1104/2021).
文摘The experiment addressed the effects of preharvest KH_(2)PO_(4)foliar spraying(20 mmol·L^(-1))on fruit quality and composition(including volatile organic compounds,VOCs)of cherry tomatoes(‘Caravaggio’,‘Sugarland’and‘Top Stellina’)after 0(S0),7(S7)and 14 days(S14)of storage at 8.0°C.On the average of the 3 genotypes,the KH_(2)PO_(4)treatment improved fruit pressure firmness,total soluble solids(TSS),titratable acidity(TA),total phenols and carotenoids concentrations,along with the fruits'antioxidant capacity(by up to 17%for FRAP assay).Within the S7–S14 period,control fruits showed the highest reductions in TSS,TSS/TA ratio and total carotenoids(-17,-12 and-45,respectively),whereas treated fruits proved the strongest increase in DPPH(+12%).Sixteen out of 32 VOCs were promoted following KH_(2)PO_(4)application,including the aldehydes hexanal,(E)-2-hexenal and(Z)-3-hexenal and the apocarotenoids(E)-citral,(E)-β-ionone,geranylacetone and 6-methyl-5-hepten-2-one.Proceeding from S0 to S14,several VOCs decreased more strongly in control fruits,as for hexanal(-48%)and total aldehydes(-42%,whereas at S14 treated fruits had higher concentrations of linalool,geranylacetone and 6-methyl-5-hepten-2-one(1.06,52.50 and 79.27μg·kg^(-1),respectively).‘Caravaggio’demonstrated the strongest apocarotenoid reduction at S14,whereas‘Top Stellina’was more responsive to KH_(2)PO_(4)(mainly forβ-cyclocitral,geranylacetone and total terpenes/terpenoids),thus highlighting the central role of the genotype in responding to other experimental factors.Nonetheless,these results suggest that proper preharvest KH_(2)PO_(4)applications can preserve specific commercial,nutritional and quality traits of cold-stored cherry tomatoes.
文摘The gut-skin axis(GSA)embodies a complex,bidirectional interaction between the gastrointestinal(GI)system and skin,driven by immune modulation,systemic inflammation,and gut microbiota dynamics.Disruptions in gut homeostasis,including dysbiosis and increased intestinal permeability,are increasingly recognized as contributing factors to dermatological conditions such as acne,psoriasis,and atopic dermatitis.For gastroenterologists,appreciating this interplay is essential,as diseases and their treatments frequently present with cutaneous manifestations,offering diagnostic and therapeutic insights.This review explores the underlying mechanisms of the GSA,focusing on the microbiome and its metabolites as key regulators of inflammation and immunity.It underscores the clinical importance of microbiome-targeted therapies,such as probiotics,prebiotics,and dietary modifications,in addressing both GI and dermatological disorders.Furthermore,the review examines the influence of GI conditions,including inflammatory bowel disease and celiac disease on skin health.This article seeks to equip gastroenterologists with practical insights for identifying,diagnosing,and managing skin conditions associated with GI health.The article also highlights the current limitations in knowledge regarding the GSA.The GSA represents a promising avenue for therapeutic advancements,encouraging interdisciplinary collaboration between gastroenterology and dermatology to optimize patient care.
基金supported by the National Research Foundation of Korea(NRF)grant funded by the Korean government(MSIT)(No.2020R1C1C1005567)supported by the NAVER Digital Bio Innovation Research Fund,funded by NAVER Corporation(Grant No.[37-2023-0040])+3 种基金supported by Institute of Information&communications Technology Planning&Evaluation(IITP)grant funded by the Korea government(MSIT)(No.2020-0-00261,Development of low power/low delay/self-power suppliable RF simultaneous information and power transfer system and stretchable electronic epineurium for wireless nerve bypass implementation)supported by Institute for Basic Science(IBS-R015-D1,IBSR015-D2)supported by a grant of the Korea-US Collaborative Research Fund(KUCRF)funded by the Ministry of Science and ICT and Ministry of Health&Welfare,Republic of Korea(Grant Number.RS-2024-00467213)。
文摘Prosthetic devices designed to assist individuals with damaged or missing body parts have made significant strides,particularly with advancements in machine intelligence and bioengineering.Initially focused on movement assistance,the field has shifted towards developing prosthetics that function as seamless extensions of the human body.During this progress,a key challenge remains the reduction of interface artifacts between prosthetic components and biological tissues.Soft electronics offer a promising solution due to their structural flexibility and enhanced tissue adaptability.However,achieving full integration of prosthetics with the human body requires both artificial perception and efficient transmission of physical signals.In this context,synaptic devices have garnered attention as next-generation neuromorphic computing elements because of their low power consumption,ability to enable hardware-based learning,and high compatibility with sensing units.These devices have the potential to create artificial pathways for sensory recognition and motor responses,forming a“sensory-neuromorphic system”that emulates synaptic junctions in biological neurons,thereby connecting with impaired biological tissues.Here,we discuss recent developments in prosthetic components and neuromorphic applications with a focus on sensory perception and sensorimotor actuation.Initially,we explore a prosthetic system with advanced sensory units,mechanical softness,and artificial intelligence,followed by the hardware implementation of memory devices that combine calculation and learning functions.We then highlight the importance and mechanisms of soft-form synaptic devices that are compatible with sensing units.Furthermore,we review an artificial sensory-neuromorphic perception system that replicates various biological senses and facilitates sensorimotor loops from sensory receptors,the spinal cord,and motor neurons.Finally,we propose insights into the future of closed-loop neuroprosthetics through the technical integration of soft electronics,including bio-integrated sensors and synaptic devices,into prosthetic systems.
基金supported by the Guangdong Major Project of Basic and Applied Basic Research(Grant Nos.2020B0301030008 and 2023A1515010416)the National Natural Science Foundation of China(Grant Nos.12375073,12275091,12147128,and 12035007).
文摘We study the production of the X(6900)in the ultra-peripheral heavy ion collisions at the LHC energy region.The potential quantum numbers of X(6900)could be 0^(±+)and 2^(±+).We find that the transverse momentum and the polar angle distributions of X(6900)can be used to distinguish these four potential quantum numbers.These characteristic distributions originate from linearly polarized photons emitted by relativistic nuclei and can be measured by further LHC experiments.
基金supported by the Institute for Basic Science,south korea(IBS-R006-A2)supproted by the Basic Science Research Program through the National Research Foundation of Korea(NRF),south korea funded by the Ministry of Education(2018R1D1A3B05042787)+1 种基金supported by the National Research Foundation of Korea(NRF),south korea grant funded by the Korea Government(MSIT)(RS-2025-00518953)the National Research Foundation of Korea(NRF),south korea grant funded by the Korea Government(MSIT)(RS-202400422387)。
文摘Aqueous batteries,renowned for their cost-effectiveness and non-flammability,have attracted considerable attention in the realm of batteries featuring Zn-based and Sn-based configurations.These configurations employ Zn and Sn metal anodes,respectively.While the growth patterns of Zn under various current densities have been extensively studied,there has been a scarcity of research on Sn dendrite growth.Our operando imaging analysis reveals that,unlike Zn,Sn forms sharp dendrites at high current density emphasizing the crucial necessity for implementing strategies to suppress the dendrites formation.To address this issue,we introduced a carbon nanotube(CNT)layer on copper foil,effectively preventing the formation of Sn dendrites under high current density,thus enabling the high-current operation of Sn metal batteries.We believe that our work highlights the importance of suppressing dendrite formation in aqueous Sn metal batteries operating at high current density and introduces a fresh perspective on mitigating Sn dendrite formation.
基金supported by the Nano&Material Technology Development Program through the National Research Foundation of Korea(NRF)funded by Ministry of Science and ICT(Grant No.RS-2024-00408180)by Institute for Basic Science(No.IBS-R019-G1).
文摘Two-dimensional(2D)nitride MXenes are predicted to exhibit exceptional metallic properties and high polarity;however,their synthesis remains challenging.Research has relied on traditional molten salt etching,highlighting the need for a scalable,high-purity approach.Here,we present the first solution-based synthesis of Ti_(4)N_(3)T_(x)MXene via a novel saturated salt solution(S^(3))etching technique employing alkali metal salts.By optimizing the sintering process for high-purity Ti_(4)AlN_(3)MAX and refining the S^(3)etching route,we significantly reduced the etch pit density to 1.2×10^(6)cm^(-2)and lowered the etch pit formation rate to 4%,yielding high-quality,phasepure Ti_(4)N_(3)T_(x)MXene.Our study highlights the critical role of alkali metal ions in selective A-layer removal and demonstrates the impressive electrical conductivity and electromagnetic interference shielding performance of 2D nitride MXene,setting a new benchmark for this underexplored material.These findings pave the way for advancing 2D nitride MXenes and their diverse applications.
基金financially supported by the Institute for Basic Science of Korea(No.IBS-R011-D1)the National Research Foundation of Korea(NRF)(No.NRF-2022R1A2C2093415)+5 种基金the Korea Basic Science Institute(National Research Facilities and Equipment Center)grant funded by the Ministry of Education(No.2022R1A6C101A751)the National Natural Science Foundation of China(Nos.22209186 and 22479149)the Natural Science Foundation of Jiangxi Province(No.310306484080)the Key Research and Development Program of Jiangxi Province(Nos.20223BBG74004 and 20232BBG70003)the Youth Innovation Promotion Association,Chinese Academy of Sciences(No.2023343)the financial support from the National Research Foundation of Korea Grant funded by the Korean government(NRF-2021R1I1A1A01050068)
文摘Fabricating a durable electrocatalyst with performance comparable to noble metals for the alkaline hydrogen evolution reaction(HER)remains a significant challenge.In this work,we introduce a highly efficient and robust electrocatalyst by incorporating rhenium(Re)atoms into CoS nanoflakes(Re-CoS)for alkaline HER.The incorporation of Re atoms into the CoS lattice enhances the hybridization of Co 3d and S 2p orbitals,resulting in an optimized electronic structure that accelerates water dissociation on Co sites and optimizes hydrogen adsorptiondesorption on S sites,thereby boosting the HER rate.The optimal Re-CoS catalyst demonstrates a low overpotential of 72 mV at 10 mA cm^(-2)in 1 M KOH,along with excellent long-term stability,maintaining its catalytic activity over 200 h without significant degradation.These results suggest that the incorporation of Re atoms into CoS effectively couples the water dissociation and hydrogen addesorption steps of alkaline HER,offering a promising strategy for the development of noble metal-like electrocatalysts.
基金supported by the Technology Innovation Program(No.20011712)funded by the Ministry of Trade,Industry,and Energy(MOTIE,Korea)a National Research Foundation of Korea(NRF)grant funded by the Ministry of Science and ICT(MSIT)(No.2022M3J1A108538),Korea+2 种基金the support of the Nano&Material Technology Development Program through the National Research Foundation of Korea(NRF)funded by the Ministry of Science and ICT(RS-2024-00444986,50%)the Institute for Basic Science(IBS-R036-D1)。
文摘Understanding the degradation phenomenon of proton exchange membrane fuel cells under electrochemical cycling requires an analysis of the porous carbon support structure.Key factors contributing to this phenomenon include changes in the total porosity and viable surface area for electrochemical reactions.Electron tomography-based serial section imaging using focused ion beam-scanning electron microscopy(FIB-SEM)can elucidate this phenomenon at a nanoscale resolution.However,this highresolution tomographic analysis requires a huge image dataset and manual inputs in rule-based workflows;these requirements are time-consuming and often cause experimental difficulties and unreliable interpretations.We propose a deep learning-empowered approach comprising a two-step automated process for image interpolation and semantic segmentation to address the practical issues encountered in FIB-SEM electron tomography.An optimally trained interpolation model can reduce the image data requirement by more than 95%to analyze the structural degradation of carbon supports after electrochemical cycling while maintaining the reliability obtained in conventional tomographic analysis with several hundred images.Because the subsequent image segmentation model excludes a complicated manual filtering process,the relevant structural parameters can be reliably measured without human bias.Our sparse-section imaging-based deep learning process can allow cost-efficient analysis and reliable measurement of the degree of cycling-induced carbon corrosion.
基金supported by the Basic Science Research Program through the National Research Foundation of Korea(NRF),funded by the Ministry of Education(2022R1A3B1078163 and 2022R1A4A1031182)supported by the KIMM institutional program(NK248E)and NST/KIMM+3 种基金supported by the Technology Innovation Program(or Industrial Strategic Technology Development Program)(20024772),(RS-2023-00264860)funded by the Ministry of Trade,Industry&Energy(MOTIE,Korea)(1415187508)supported by the US Department of Energy,Office of Science,Office of Basic Energy Sciences,under grant no.DE-FG02-87ER13808by Northwestern University.
文摘The exploration of heterostructures composed of two-dimensional(2D)transition metal dichalcogenide(TMDc)materials has garnered significant research attention due to the distinctive properties of each individual component and their phase-dependent unique properties.Using the plasma-enhanced chemical vapor deposition(PECVD)method,we analyze the fabrication of heterostructures consisting of two phases of molybdenum disulfide(MoS_(2))in four different cases.The initial hydrogen evolution reaction(HER)polarization curve indicates that the activity of the heterostructure MoS_(2)is consistent with that of the underlying MoS_(2),rather than the surface activity of the upper MoS_(2).This behavior can be attributed to the presence of Schottky barriers,which include contact resistance,which significantly hampers the efficient charge transfer at junctions between the two different phases of MoS_(2)layers and is mediated by van der Waals bonds.Remarkably,the energy barrier at the junction dissipates upon reaching a certain electrochemical potential,indicating surface activation from the top phase of MoS_(2)in the heterostructure.Notably,the 1T/2H MoS_(2)heterostructure demonstrates enhanced electrochemical stability compared to its metastable 1T-MoS_(2).This fundamental understanding paves the way for the creation of phase-controllable heterostructures through an experimentally viable PECVD,offering significant promise for a wide range of applications.
文摘Trees,mammals,and microbes relate to soil carbon(C)cycle.Trees capture C,and mammals consume plants and other animals,both contributing to organic remains that are then degraded by soil microbes.This organic C can be stored in soils or released into the atmosphere through microbial mineralization.Yet,the simultaneous effects of mammals and trees on C consumption by soil microbes have not been investigated.For 30 sampling sites in a mixed forest-savanna environment in southern Guyana,we jointly analyzed observational data of mammal and tree communities along with soil organic matter(SOM)composition(using Fourier transform infrared spectroscopy combined with attenuated total reflectance,energy dispersive X-ray fluorescence spectrometry,and CNH elemental analyzer)and soil microbial C consumption(using Biolog EcoPlates).It was found that higher mammal functional richness(FRic)and functional evenness(FEve)were related to reduced overall C consumption by soil microbes(for FRic:regression coefficient(β)=-0.010,standard error(SE)=0.005,P=0.034;for FEve:β=-0.012,SE=0.005,P=0.010)with the coefficient of determination(R^(2))value of 0.359,explaining 36%of the variance in average well color development values,whereas a higher tree richness was associated with a reduced diversity of C sources consumed by soil microbial communities(β=-0.353,SE=0.172,P=0.041)with the R2 value of 0.290,explaining 29%of the variance in Shannon diversity index values.Our results indicate that mammal and tree communities have complementary effects on soil microbial C consumption,improving our understanding of the functioning of C cycle in the high-diversity Amazon biome.These findings are crucial in elucidating the intricate connections between above-and belowground biodiversity that influence the accumulation and stabilization of soil organic C.
基金funded by the Spanish Ministry of Culture and Sport,Consejo Superior de Deportes,Plan de Recuperación,Transformación y Resiliencia,Unión Europea,Next Generation EUAyudas Europeas a Proyectos de Investigaci on Aplicada a la Actividad Física Beneficiosa para la Salud y la Medicina Deportiva(EXP_77437)+9 种基金by the Spanish Ministry of Science and Innovation(PID2022-141506OB-I00)the European Regional Development Funds(ERDF)by the University of Granada Plan Propio de Investigación-Excellence actions:Unit of Excellence on Exercise Nutrition and Health(UCEENS)supported by the Spanish Ministry of Education,Culture and Sport(FPU19/03745 and FPU20/05530,respectively)supported by the Juan de la Cierva Formación Grant FJC2020-044453-I funded by Ministerio de Ciencia e Innovaci on/Agencia Estatal de Investigaci on MCIN/AEI/10.13039/501100011033European Union Next Generation,Plan de Recuperación,Transformación y Resilencia(EU/PRTR)“Ramón y Cajal fellowship 2013-2017”funded by MCIN/AEI/10.13039/501100011033 and“El Fondo Social Europeo invierte en tu futuro”partially supported by the Grant PID2020-114054RA-I001001100482funded by MCIN/AEI/10.13039/501100011033supported by a grant from the MCIN/AEI/10.13039/501100011033,Spain,and the ERDF(PID2021-126788OB-I00).
文摘Background:Mammalian cells possess molecular clocks,the adequate functioning of which is decisive for metabolic health.Exercise is known to modulate these clocks,potentially having distinct effects on metabolism depending on the time of day.This study aimed to investigate the impact of morning vs.evening moderate-intensity aerobic exercise on glucose regulation and energy metabolism in healthy men and women.It also aimed to elucidate molecular mechanisms within skeletal muscle.Methods:Using a randomized crossover design,healthy men(n=18)and women(n=17)performed a 60-min bout of moderate-intensity aerobic exercise in the morning and evening.Glucose regulation was continuously monitored starting 24 h prior to the exercise day and continuing until 48 h post-exercise for each experimental condition.Energy expenditure and substrate oxidation were measured by indirect calorimetry during exercise and at rest before and after exercise for 30 min.Skeletal muscle biopsies were collected immediately before and after exercise to assess mitochondrial function,transcriptome,and mitochondrial proteome.Results:Results indicated similar systemic glucose,energy expenditure,and substrate oxidation during and after exercise in both sexes.Notably,transcriptional analysis,mitochondrial function,and mitochondrial proteomics revealed marked sexual dimorphism and time of day variations.Conclusion:The sexual dimorphism and time of day variations observed in the skeletal muscle in response to exercise may translate into observable systemic effects with higher exercise-intensity or chronic exercise interventions.This study provides a foundational molecular framework for precise exercise prescription in the clinical setting.
基金The Trùndelag Health Study (HUNT) is a collaboration between HUNT Research Centre (Faculty of Medicine and Health Sciences, Norwegian University of Science and Technology), Trùndelag County Council, Central Norway Regional Health Authority, and the Norwegian Institute of Public HealthThe coordination of European Prospective Investigation into Cancer and Nutrition - Spain study (EPIC) is financially supported by the International Agency for Research on Cancer (IARC)+7 种基金by the Department of Epidemiology and Biostatistics, School of Public Health, Imperial College London, which has additional infrastructure support provided by the NIHR Imperial Biomedical Research Centre (BRC)supported by Health Research Fund (FIS) - Instituto de Salud Carlos III (ISCIII), Regional Governments of Andaluc 1a, Asturias, Basque Country, Murcia and Navarra, and the Catalan Institute of Oncology - ICO (Spain)funded by The Netherlands Organisation for Health Research and DevelopmentZon Mw (Grant No.: 531-00141-3)Funding for the SHIP study has been provided by the Federal Ministry for Education and Research (BMBFidentification codes 01 ZZ96030, 01 ZZ0103, and 01 ZZ0701)support from the Swedish Research Council (2018-02527 and 2019-00193)financed by the Helmholtz Zentrum München - German Research Center for Environmental Health, which is funded by the German Federal Ministry of Education and Research (BMBF) and by the State of Bavaria.
文摘Background There is insufficient evidence to provide recommendations for leisure-time physical activity among workers across various occupational physical activity levels.This study aimed to assess the association of leisure-time physical activity with cardiovascular and all-cause mortality across occupational physical activity levels.Methods This study utilized individual participant data from 21 cohort studies,comprising both published and unpublished data.Eligibility criteria included individual-level data on leisure-time and occupational physical activity(categorized as sedentary,low,moderate,and high)along with data on all-cause and/or cardiovascular mortality.A 2-stage individual participant data meta-analysis was conducted,with separate analysis of each study using Cox proportional hazards models(Stage 1).These results were combined using random-effects models(Stage 2).Results Higher leisure-time physical activity levels were associated with lower all-cause and cardiovascular mortality risk across most occupational physical activity levels,for both males and females.Among males with sedentary work,high compared to sedentary leisure-time physical activity was associated with lower all-cause(hazard ratios(HR)=0.77,95%confidence interval(95%CI):0.70-0.85)and cardiovascular mortality(HR=0.76,95%CI:0.66-0.87)risk.Among males with high levels of occupational physical activity,high compared to sedentary leisure-time physical activity was associated with lower all-cause(HR=0.84,95%CI:0.74-0.97)and cardiovascular mortality(HR=0.79,95%CI:0.60-1.04)risk,while HRs for low and moderate levels of leisure-time physical activity ranged between 0.87 and 0.97 and were not statistically significant.Among females,most effects were similar but more imprecise,especially in the higher occupational physical activity levels.Conclusion Higher levels of leisure-time physical activity were generally associated with lower mortality risks.However,results for workers with moderate and high occupational physical activity levels,especially women,were more imprecise.Our findings suggests that workers may benefit from engaging in high levels of leisure-time physical activity,irrespective of their level of occupational physical activity.
