In order to ensure food safety,controlling foodborne pathogen contamination is of utmost importance.Growing apprehensions regarding the safety of synthetic antimicrobials,due to their adverse health effects,have promp...In order to ensure food safety,controlling foodborne pathogen contamination is of utmost importance.Growing apprehensions regarding the safety of synthetic antimicrobials,due to their adverse health effects,have prompted a search for alternative options.Plant natural products(PNPs)with antimicrobial activity are being explored as a viable alternative.Among the various antimicrobial natural products studied,plant essential oils,plant flavonoids,plant polyphenols,plant polysaccharides,and plant antimicrobial peptides have been identified as potential candidates.PNPs demonstrate a diverse array of antimicrobial mechanisms,encompassing cell wall and membrane damage,interference with genetic replication,disruption of energy metabolism,and induction of oxidative stress at the single-cell level,as well as inhibition of biofilm formation and quorum sensing at the population level.Certain PNPs have been harnessed as natural antimicrobial agents for the food preservation.The utilization of encapsulation technology proves to be an effective strategy in protecting PNPs,thereby ensuring good antimicrobial efficacy,enhanced dispersibility,and controlled release within food products.The utilization of nanoemulsions,nanoliposomes,edible packaging,electrospun nanofibers,and microcapsules formed by encapsulation has enriched the ways in which PNPs can be applied in food preservation.Although PNPs have great potential in food preservation,their widespread application in the food industry is currently constrained by factors such as production costs,safety concerns,and legal considerations.Chemical synthesis and biosynthesis pathways offer viable strategies for reducing the cost of producing PNPs,and ongoing efforts to assess safety and improve regulatory frameworks are likely to facilitate the broader adoption of PNPs in food preservation practices.This article provides an overview of the main types of PNPs with antimicrobial activity and their properties,focusing on their mechanisms of action.Additionally,it summarizes the use of PNPs in food preservation and discusses the characteristics and applications of different encapsulation technologies.Lastly,the paper briefly analyzes current limitations and proposes potential future trends for this field.展开更多
Developing selective electrodes for lithium extraction from brines remains challenging.This work reports room-temperature synthesized cubic copper hexacyanoferrate(Cu HCF)nanoparticles for hybrid capacitive deionizati...Developing selective electrodes for lithium extraction from brines remains challenging.This work reports room-temperature synthesized cubic copper hexacyanoferrate(Cu HCF)nanoparticles for hybrid capacitive deionization(HCDI).The Cu HCF framework exhibits a high surface area(715.84 m^(2)·g^(-1)),dual redoxactive sites([Fe^(Ⅲ)(CN)_(6)]^(4-)/[Fe^(Ⅱ)(CN)_(6)]^(3-)and Cu^(+)/Cu^(2+)),and excellent cyclability(99.4%capacity retention after 1000 cycles).In HCDI system,the Cu HCF cathode demonstrates remarkable Li^(+)ions selectivity,achieving a 25.5 mg·g^(-1)adsorption capacity in 500 mg·L^(-1)Li Cl solution with 94%charge efficiency at1.2 V.Notably,in mixed Li^(+)/Mg^(2+)solutions(30:1 molar ratio),Cu HCF nanoparticles maintain a high separation coefficient of 3.1,attributed to the synergistic effects of ionic sieving and preferential redox interactions.Mechanistic studies confirm Li^(+)(de)intercalation via reversible[Fe^(Ⅲ)(CN)_(6)]^(4-)/[Fe^(Ⅱ)(CN)_(6)]^(3-)and Cu^(2+)/Cu^(+)transitions.Density functional theory calculations reveal Li^(+)exhibits lower adsorption energy than Mg^(2+)(-3.72 e V vs.-1.49 e V),which fundamentally explains the preferential extraction capability of Li^(+)ions over Mg^(2+)ions during the separation process.This study advances ion-selective pseudocapacitor design for sustainable lithium extraction from high-salinity resources.展开更多
Freshwater scarcity has emerged as a critical global environmental challenge.Flow-electrode capacitive deionization(FCDI)represents a promising technology for achieving efficient and low-energy seawater desalination.T...Freshwater scarcity has emerged as a critical global environmental challenge.Flow-electrode capacitive deionization(FCDI)represents a promising technology for achieving efficient and low-energy seawater desalination.This study presents a novel flow-electrode material,nitrogen-doped porous carbon(NPC),which is derived from biomass and demonstrates both cost-effectiveness and high performance.The NPC material is synthesized from bean shells through high-temperature pre-carbonization followed by activation with KHCO_(3),resulting in a rich porous structure,increased specific surface area,and high graphitization degree,which collectively confer superior capacitance performance compared to activated carbon(AC).Desalination experiments indicate that the FCDI performance of the NPC flow-electrode surpasses that of the AC flow-electrode.Specifically,at a voltage of 2.5 V in a 6 g·L^(-1)NaCl solution,the NPC system achieves an average salt removal rate(ASRR)of 104.9 μg·cm^(-2)·min^(-1),with a charge efficiency(CE)of 94.0%and an energy consumption(EC)of only 4.4 kJ·g^(-1).Furthermore,the NPC-based FCDI system exhibits commendable desalination cycling stability,maintaining relatively stable energy consumption and efficiency after prolonged continuous desalination cycles.This research holds significant implications for the advancement of environmentally friendly,low-cost,high-performance FCDI systems for large-scale applications.展开更多
Heterojunction engineering is considered as one of the most effective methods to improve the hydrogen production performance of photocatalysts.In this study,a green,simple and gentle method was used to deposit tiny Ni...Heterojunction engineering is considered as one of the most effective methods to improve the hydrogen production performance of photocatalysts.In this study,a green,simple and gentle method was used to deposit tiny Ni S onto CTF-ES_(200)under xenon lamp irradiation to form heterostructures.The experimental results show that the hydrogen production rate of the synthesized Ni S/CTF-ES_(200)is as high as 22.98mmol g^(-1)h^(-1),showing a higher photocatalytic hydrogen production rate compared to other Ni S-loaded nonmetallic semiconductor materials,which is also much higher than that of pure CTF-ES_(200).The interface electric field(IEF)in this p-n heterojunction leads to an accumulation of photoelectrons on the conduction band of CTF-ES_(200),which makes CTF-ES_(200)to keep a high reductiveness for the hydrogen evolution reaction(HER),and significantly improve the separation efficiency of photoelectrons and holes.Furthermore,XPS and EXAFS data show that an efficient electron transport channel is constructed through the formation of Ni-N bond,which further accelerates the interface carrier transport efficiency.This study provides an effective idea for the preparation of highly efficient heterojunction photocatalysts.展开更多
Flexible energy storage devices have been paid much attention and adapts to apply in various fields.Benefiting from the active sites of boron(B)and phosphorus(P)doping materials,co-doped carbon materials are widely us...Flexible energy storage devices have been paid much attention and adapts to apply in various fields.Benefiting from the active sites of boron(B)and phosphorus(P)doping materials,co-doped carbon materials are widely used in energy storage devices for the enhanced electrochemical performance.Herein,B and P co-doped flexible carbon nanofibers with nitrogen-rich(B-P/NC)are investigated with electro-spinning for sodium-ion battery.The flexible of binderless B-P/NC with annealing of 600℃(B-P/NC-600)exhibits the remarkable performance for the robust capacity of 200 mAh/g at 0.1 A/g after 500 cycles and a durable reversible capacity of 160 m Ah/g even at 1 A/g after 12,000 cycles,exhibiting the equally commendable stability of flexible B-P/NC-600.In addition,B-P/NC-600 delivers the reversible capacity of265 m Ah/g with the test temperature of 60℃.More importantly,the flexible B-P/NC-600 is fabricated as anode for the whole battery,delivering the capacity of 90 m Ah/g at 1 A/g after 200 cycles.Meanwhile,theoretical calculation further verified that boron and phosphorus co-doping can improve the adsorption capacity of nitrogen carbon materials.The favorable performance of flexible B-P/NC-600 can be ascribed to the nitrogen-rich carbon nanofibers with three-dimensional network matrix for the more active site of boron and phosphorus co-doping.Our work paves the way for the improvement of flexible anodes and wide-operating temperature of sodium-ion batteries by doping approach of much heteroatom.展开更多
Manmade debris and natural meteoroids, travelling in the Low Earth Orbit at a speed of several kilometers per second, pose a severe safety concern to the spacecraft in service through the HyperVelocity Impact(HVI). To...Manmade debris and natural meteoroids, travelling in the Low Earth Orbit at a speed of several kilometers per second, pose a severe safety concern to the spacecraft in service through the HyperVelocity Impact(HVI). To address this issue, an investigation of shock Acoustic Emission(AE) waves induced by HVI to a downscaled two-layer Whipple shielding structure is performed,to realize a quantitative damage evaluation. Firstly a hybrid numerical model integrating smoothparticle hydrodynamics and finite element is built to obtain the wave response. The projectiles, with various impact velocities and directions, are modelled to impact the shielding structure with different thicknesses. Then experimental validation is carried out with built-in miniaturized piezoelectric sensors to in situ sense the HVI-induced AE waves. A quantitative agreement is obtained between numerical and experimental results, demonstrating the correctness of the hybrid model and facilitating the explanation of obtained AE signals in experiment. Based on the understanding of HVI-induced wave components, assessment of the damage severity, i.e., whether the outer shielding layer is perforated or not, is performed using the energy ratio between the regions of ‘‘high frequency" and ‘‘low frequency" in the acquired AE signals. Lastly, the direct-arrival fundamentalsymmetric wave mode is isolated from each sensing signal to be input into an enhanced delay-andsum algorithm, which visualizes HVI spots accurately and instantaneously with different sensor network configuration. All these works demonstrate the potential of quantitative, in situ, and real time HVI monitoring using miniaturized piezoelectric sensor network.展开更多
The quality of planting materials is the foundation for productivity,longevity,and berry quality of perennial grapevines with a long lifespan.Manipulating the nursery light spectrum may speed up the production of heal...The quality of planting materials is the foundation for productivity,longevity,and berry quality of perennial grapevines with a long lifespan.Manipulating the nursery light spectrum may speed up the production of healthy and high-quality planting vines but the underlying mechanisms remain elusive.Herein,the effects of different monochromatic lights(green,blue,and red)on grapevine growth,leaf photosynthesis,whole-plant carbon allocation,and transcriptome reprograming were investigated with white light as control.Results showed that blue and red lights were favorable for plantlet growth in comparison with white light.Blue light repressed excessive growth,significantly increased the maximum net photosynthetic rate(Pn)of leaves by 39.58%and leaf specific weight by 38.29%.Red light increased the dry weight of the stem by 53.60%,the starch content of the leaf by 53.63%,and the sucrose content of the stem by 230%.Green light reduced all photosynthetic indexes of the grape plantlet.Photosynthetic photon flux density(PPFD)/Ci–Pn curves indicated that blue light affected photosynthetic rate depending on the light intensity and CO2 concentration.RNA-seq analysis of different organs(leaf,stem,and root)revealed a systematic transcriptome remodeling and VvCOP1(CONSTITUTIVELY PHOTOMORPHOGENIC 1),VvHY5(ELONGATED HYPOCOTYL5),VvHYH(HY5 HOMOLOG),VvELIP(early light-induced protein)and VvPIF3(PHYTOCHROME INTERACTING FACTOR 3)may play important roles in this shoot-to-root signaling.Furthermore,the correlation network between differential expression genes and physiological traits indicated that VvpsbS(photosystem II subunit S),Vvpsb28(photosystem II subunit 28),VvHYH,VvSUS4(sucrose synthase 4),and VvALDA(fructose-bisphosphate aldolase)were pertinent candidate genes in responses to different light qualities.Our results provide a foundation for optimizing the light recipe of grape plantlets and strengthen the understanding of light signaling and carbon metabolism under different monochromatic lights.展开更多
Background: Bacterial infection is one of the most common complications in burn, trauma, and chronic refractory wounds and is an impediment to healing. The frequent occurrence of antimicrobial-resistant bacteria due t...Background: Bacterial infection is one of the most common complications in burn, trauma, and chronic refractory wounds and is an impediment to healing. The frequent occurrence of antimicrobial-resistant bacteria due to irrational application of antibiotics increases treatment cost and mortality. Graphene oxide (GO) has been generally reported to possess high antimicrobial activity against a wide range of bacteria in vitro. In this study, a graphene oxide-quaternary ammonium salt (GO-QAS) nanocomposite was synthesized and thoroughly investigated for synergistic antibacterial activity, underlying antibacterial mechanisms and biocompatibility in vitro and in vivo. Methods: The GO-QAS nanocomposite was synthesized through amidation reactions of carboxylic group end-capped QAS polymers with primary amine-decorated GO to achieve high QAS loading ratios on nanosheets. Next, we investigated the antibacterial activity and biocompatibility of GO-QAS in vitro and in vivo. Results: GO-QAS exhibited synergistic antibacterial activity against bacteria through not only mechanical membrane perturbation, including wrapping, bacterial membrane insertion, and bacterial membrane perforation, but also oxidative stress induction. In addition, it was found that GO-QAS could eradicate multidrug-resistant bacteria more effectively than conventional antibiotics. The in vitro and in vivo toxicity tests indicated that GO-QAS did not exhibit obvious toxicity towards mammalian cel s or organs at low concentrations. Notably, GO-QAS topically applied on infected wounds maintained highly efficient antibacterial activity and promoted infected wound healing in vivo. Conclusions: The GO-QAS nanocomposite exhibits excellent synergistic antibacterial activity and good biocompatibility both in vitro and in vivo. The antibacterial mechanisms involve both mechanical membrane perturbation and oxidative stress induction. In addition, GO-QAS accelerated the healing process of infected wounds by promoting re-epithelialization and granulation tissue formation. Overall, the results indicated that the GO-QAS nanocomposite could be applied as a promising antimicrobial agent for infected wound management and antibacterial wound dressing synthesis.展开更多
基金supported by the National Natural Science Foundation of China(32060520)Science and Technology Talents and Platform Program of Yunnan Province(202105AF150049)University Key Laboratory of Food Microbial Resources and Utilization in Yunnan Province(Yunjiaofa[2018]No.135).
文摘In order to ensure food safety,controlling foodborne pathogen contamination is of utmost importance.Growing apprehensions regarding the safety of synthetic antimicrobials,due to their adverse health effects,have prompted a search for alternative options.Plant natural products(PNPs)with antimicrobial activity are being explored as a viable alternative.Among the various antimicrobial natural products studied,plant essential oils,plant flavonoids,plant polyphenols,plant polysaccharides,and plant antimicrobial peptides have been identified as potential candidates.PNPs demonstrate a diverse array of antimicrobial mechanisms,encompassing cell wall and membrane damage,interference with genetic replication,disruption of energy metabolism,and induction of oxidative stress at the single-cell level,as well as inhibition of biofilm formation and quorum sensing at the population level.Certain PNPs have been harnessed as natural antimicrobial agents for the food preservation.The utilization of encapsulation technology proves to be an effective strategy in protecting PNPs,thereby ensuring good antimicrobial efficacy,enhanced dispersibility,and controlled release within food products.The utilization of nanoemulsions,nanoliposomes,edible packaging,electrospun nanofibers,and microcapsules formed by encapsulation has enriched the ways in which PNPs can be applied in food preservation.Although PNPs have great potential in food preservation,their widespread application in the food industry is currently constrained by factors such as production costs,safety concerns,and legal considerations.Chemical synthesis and biosynthesis pathways offer viable strategies for reducing the cost of producing PNPs,and ongoing efforts to assess safety and improve regulatory frameworks are likely to facilitate the broader adoption of PNPs in food preservation practices.This article provides an overview of the main types of PNPs with antimicrobial activity and their properties,focusing on their mechanisms of action.Additionally,it summarizes the use of PNPs in food preservation and discusses the characteristics and applications of different encapsulation technologies.Lastly,the paper briefly analyzes current limitations and proposes potential future trends for this field.
基金supported by the National Natural Science Foundation of China(52202093)Postgraduate research&practice innovation program of Jiangsu province(SJCX25_2553)+1 种基金the China Postdoctoral Science Foundation(2023M731357)the open project of Anhui Province Key Laboratory of Efficient Conversion and Solid-State Storage of Hydrogen&Electricity(ECSSHE2024KF03)。
文摘Developing selective electrodes for lithium extraction from brines remains challenging.This work reports room-temperature synthesized cubic copper hexacyanoferrate(Cu HCF)nanoparticles for hybrid capacitive deionization(HCDI).The Cu HCF framework exhibits a high surface area(715.84 m^(2)·g^(-1)),dual redoxactive sites([Fe^(Ⅲ)(CN)_(6)]^(4-)/[Fe^(Ⅱ)(CN)_(6)]^(3-)and Cu^(+)/Cu^(2+)),and excellent cyclability(99.4%capacity retention after 1000 cycles).In HCDI system,the Cu HCF cathode demonstrates remarkable Li^(+)ions selectivity,achieving a 25.5 mg·g^(-1)adsorption capacity in 500 mg·L^(-1)Li Cl solution with 94%charge efficiency at1.2 V.Notably,in mixed Li^(+)/Mg^(2+)solutions(30:1 molar ratio),Cu HCF nanoparticles maintain a high separation coefficient of 3.1,attributed to the synergistic effects of ionic sieving and preferential redox interactions.Mechanistic studies confirm Li^(+)(de)intercalation via reversible[Fe^(Ⅲ)(CN)_(6)]^(4-)/[Fe^(Ⅱ)(CN)_(6)]^(3-)and Cu^(2+)/Cu^(+)transitions.Density functional theory calculations reveal Li^(+)exhibits lower adsorption energy than Mg^(2+)(-3.72 e V vs.-1.49 e V),which fundamentally explains the preferential extraction capability of Li^(+)ions over Mg^(2+)ions during the separation process.This study advances ion-selective pseudocapacitor design for sustainable lithium extraction from high-salinity resources.
基金supported by the National Natural Science Foundation of China(52202093)the National College Student Innovation and Entrepreneurship Training Program of Jiangsu University of Science and Technology(202410289005Z).
文摘Freshwater scarcity has emerged as a critical global environmental challenge.Flow-electrode capacitive deionization(FCDI)represents a promising technology for achieving efficient and low-energy seawater desalination.This study presents a novel flow-electrode material,nitrogen-doped porous carbon(NPC),which is derived from biomass and demonstrates both cost-effectiveness and high performance.The NPC material is synthesized from bean shells through high-temperature pre-carbonization followed by activation with KHCO_(3),resulting in a rich porous structure,increased specific surface area,and high graphitization degree,which collectively confer superior capacitance performance compared to activated carbon(AC).Desalination experiments indicate that the FCDI performance of the NPC flow-electrode surpasses that of the AC flow-electrode.Specifically,at a voltage of 2.5 V in a 6 g·L^(-1)NaCl solution,the NPC system achieves an average salt removal rate(ASRR)of 104.9 μg·cm^(-2)·min^(-1),with a charge efficiency(CE)of 94.0%and an energy consumption(EC)of only 4.4 kJ·g^(-1).Furthermore,the NPC-based FCDI system exhibits commendable desalination cycling stability,maintaining relatively stable energy consumption and efficiency after prolonged continuous desalination cycles.This research holds significant implications for the advancement of environmentally friendly,low-cost,high-performance FCDI systems for large-scale applications.
基金financially supported by the National Natural Science Foundation of China(No.22271022)the Science and Technology Development Planning of Jilin Province(No.YDZJ202201ZYTS342)supported by the China Scholarship Council(CSC,No.201802335014)。
文摘Heterojunction engineering is considered as one of the most effective methods to improve the hydrogen production performance of photocatalysts.In this study,a green,simple and gentle method was used to deposit tiny Ni S onto CTF-ES_(200)under xenon lamp irradiation to form heterostructures.The experimental results show that the hydrogen production rate of the synthesized Ni S/CTF-ES_(200)is as high as 22.98mmol g^(-1)h^(-1),showing a higher photocatalytic hydrogen production rate compared to other Ni S-loaded nonmetallic semiconductor materials,which is also much higher than that of pure CTF-ES_(200).The interface electric field(IEF)in this p-n heterojunction leads to an accumulation of photoelectrons on the conduction band of CTF-ES_(200),which makes CTF-ES_(200)to keep a high reductiveness for the hydrogen evolution reaction(HER),and significantly improve the separation efficiency of photoelectrons and holes.Furthermore,XPS and EXAFS data show that an efficient electron transport channel is constructed through the formation of Ni-N bond,which further accelerates the interface carrier transport efficiency.This study provides an effective idea for the preparation of highly efficient heterojunction photocatalysts.
基金supported by Natural Science Foundation of China(No.6230031623)the Natural Science Foundation of Hunan Province(No.2024JJ5127)+2 种基金the Education Department of Hunan Province(No.22B0580)the Scientific Research and Innovation Foundation of Hunan University of Technology(No.CX2317)the Innovation and Entrepreneurship Training Project for College Students(No.S202311535061)。
文摘Flexible energy storage devices have been paid much attention and adapts to apply in various fields.Benefiting from the active sites of boron(B)and phosphorus(P)doping materials,co-doped carbon materials are widely used in energy storage devices for the enhanced electrochemical performance.Herein,B and P co-doped flexible carbon nanofibers with nitrogen-rich(B-P/NC)are investigated with electro-spinning for sodium-ion battery.The flexible of binderless B-P/NC with annealing of 600℃(B-P/NC-600)exhibits the remarkable performance for the robust capacity of 200 mAh/g at 0.1 A/g after 500 cycles and a durable reversible capacity of 160 m Ah/g even at 1 A/g after 12,000 cycles,exhibiting the equally commendable stability of flexible B-P/NC-600.In addition,B-P/NC-600 delivers the reversible capacity of265 m Ah/g with the test temperature of 60℃.More importantly,the flexible B-P/NC-600 is fabricated as anode for the whole battery,delivering the capacity of 90 m Ah/g at 1 A/g after 200 cycles.Meanwhile,theoretical calculation further verified that boron and phosphorus co-doping can improve the adsorption capacity of nitrogen carbon materials.The favorable performance of flexible B-P/NC-600 can be ascribed to the nitrogen-rich carbon nanofibers with three-dimensional network matrix for the more active site of boron and phosphorus co-doping.Our work paves the way for the improvement of flexible anodes and wide-operating temperature of sodium-ion batteries by doping approach of much heteroatom.
基金the Hong Kong Research Grants Council via a General Research Fund(Nos.15201416 and 15212417)the National Natural Science Foundation of China(No.51635008)
文摘Manmade debris and natural meteoroids, travelling in the Low Earth Orbit at a speed of several kilometers per second, pose a severe safety concern to the spacecraft in service through the HyperVelocity Impact(HVI). To address this issue, an investigation of shock Acoustic Emission(AE) waves induced by HVI to a downscaled two-layer Whipple shielding structure is performed,to realize a quantitative damage evaluation. Firstly a hybrid numerical model integrating smoothparticle hydrodynamics and finite element is built to obtain the wave response. The projectiles, with various impact velocities and directions, are modelled to impact the shielding structure with different thicknesses. Then experimental validation is carried out with built-in miniaturized piezoelectric sensors to in situ sense the HVI-induced AE waves. A quantitative agreement is obtained between numerical and experimental results, demonstrating the correctness of the hybrid model and facilitating the explanation of obtained AE signals in experiment. Based on the understanding of HVI-induced wave components, assessment of the damage severity, i.e., whether the outer shielding layer is perforated or not, is performed using the energy ratio between the regions of ‘‘high frequency" and ‘‘low frequency" in the acquired AE signals. Lastly, the direct-arrival fundamentalsymmetric wave mode is isolated from each sensing signal to be input into an enhanced delay-andsum algorithm, which visualizes HVI spots accurately and instantaneously with different sensor network configuration. All these works demonstrate the potential of quantitative, in situ, and real time HVI monitoring using miniaturized piezoelectric sensor network.
基金supported by National Natural Science Foundation of China(U20A2041)the National Key R&D Program of China(2019YFD1000100,2021YFE0109500)+1 种基金the Agricultural Breeding Project of Ningxia Hui Autonomous Region(NXNYYZ202101)the CAS Youth Interdisciplinary Team(JCTD-2022-06).
文摘The quality of planting materials is the foundation for productivity,longevity,and berry quality of perennial grapevines with a long lifespan.Manipulating the nursery light spectrum may speed up the production of healthy and high-quality planting vines but the underlying mechanisms remain elusive.Herein,the effects of different monochromatic lights(green,blue,and red)on grapevine growth,leaf photosynthesis,whole-plant carbon allocation,and transcriptome reprograming were investigated with white light as control.Results showed that blue and red lights were favorable for plantlet growth in comparison with white light.Blue light repressed excessive growth,significantly increased the maximum net photosynthetic rate(Pn)of leaves by 39.58%and leaf specific weight by 38.29%.Red light increased the dry weight of the stem by 53.60%,the starch content of the leaf by 53.63%,and the sucrose content of the stem by 230%.Green light reduced all photosynthetic indexes of the grape plantlet.Photosynthetic photon flux density(PPFD)/Ci–Pn curves indicated that blue light affected photosynthetic rate depending on the light intensity and CO2 concentration.RNA-seq analysis of different organs(leaf,stem,and root)revealed a systematic transcriptome remodeling and VvCOP1(CONSTITUTIVELY PHOTOMORPHOGENIC 1),VvHY5(ELONGATED HYPOCOTYL5),VvHYH(HY5 HOMOLOG),VvELIP(early light-induced protein)and VvPIF3(PHYTOCHROME INTERACTING FACTOR 3)may play important roles in this shoot-to-root signaling.Furthermore,the correlation network between differential expression genes and physiological traits indicated that VvpsbS(photosystem II subunit S),Vvpsb28(photosystem II subunit 28),VvHYH,VvSUS4(sucrose synthase 4),and VvALDA(fructose-bisphosphate aldolase)were pertinent candidate genes in responses to different light qualities.Our results provide a foundation for optimizing the light recipe of grape plantlets and strengthen the understanding of light signaling and carbon metabolism under different monochromatic lights.
基金the Southwest Hospital Key Program(SWH2016ZDCX2014)National Natural Science Foundation of China(81372082)+1 种基金National Special Scientific Projects of Public Welfare Industry Funding of China(201502028)the State Key Laboratory Funding(SKLZZ201221).
文摘Background: Bacterial infection is one of the most common complications in burn, trauma, and chronic refractory wounds and is an impediment to healing. The frequent occurrence of antimicrobial-resistant bacteria due to irrational application of antibiotics increases treatment cost and mortality. Graphene oxide (GO) has been generally reported to possess high antimicrobial activity against a wide range of bacteria in vitro. In this study, a graphene oxide-quaternary ammonium salt (GO-QAS) nanocomposite was synthesized and thoroughly investigated for synergistic antibacterial activity, underlying antibacterial mechanisms and biocompatibility in vitro and in vivo. Methods: The GO-QAS nanocomposite was synthesized through amidation reactions of carboxylic group end-capped QAS polymers with primary amine-decorated GO to achieve high QAS loading ratios on nanosheets. Next, we investigated the antibacterial activity and biocompatibility of GO-QAS in vitro and in vivo. Results: GO-QAS exhibited synergistic antibacterial activity against bacteria through not only mechanical membrane perturbation, including wrapping, bacterial membrane insertion, and bacterial membrane perforation, but also oxidative stress induction. In addition, it was found that GO-QAS could eradicate multidrug-resistant bacteria more effectively than conventional antibiotics. The in vitro and in vivo toxicity tests indicated that GO-QAS did not exhibit obvious toxicity towards mammalian cel s or organs at low concentrations. Notably, GO-QAS topically applied on infected wounds maintained highly efficient antibacterial activity and promoted infected wound healing in vivo. Conclusions: The GO-QAS nanocomposite exhibits excellent synergistic antibacterial activity and good biocompatibility both in vitro and in vivo. The antibacterial mechanisms involve both mechanical membrane perturbation and oxidative stress induction. In addition, GO-QAS accelerated the healing process of infected wounds by promoting re-epithelialization and granulation tissue formation. Overall, the results indicated that the GO-QAS nanocomposite could be applied as a promising antimicrobial agent for infected wound management and antibacterial wound dressing synthesis.
