Background:Promoting cardiac lymphangiogenesis exerts beneficial effects for the heart.Exercise can induce physiological cardiac growth with cardiomyocyte hypertrophy and increased proliferation markers in cardiomyocy...Background:Promoting cardiac lymphangiogenesis exerts beneficial effects for the heart.Exercise can induce physiological cardiac growth with cardiomyocyte hypertrophy and increased proliferation markers in cardiomyocytes.However,it remains unclear whether and how lymphangiogenesis contributes to exercise-induced physiological cardiac growth.We aimed to investigate the role and mechanism of lymphangiogenesis in exercise-induced physiological cardiac growth.Methods:Adult C57 BL6/J mice were subjected to 3 weeks of swimming exercise to induce physiological cardiac growth.Oral treatment with vascular endothelial growth factor receptor 3(VEGFR3) inhibitor SAR1 3 1 675 was used to investigate whether cardiac lymphangiogenesis was required for exercise-induced physiological cardiac growth by VEGFR3 activation.Furthermore,human dermal lymphatic endothelial cell(LEC)-conditioned medium was collected to culture isolated neonatal rat cardiomyocytes to determine whether and how LECs could influence cardiomyocyte proliferation and hypertrophy.Results:Swimming exercise induced physiological cardiac growth accompanied by a remarkable increase of cardiac lymphangiogenesis as evidenced by increased density of lymphatic vessel endothelial hyaluronic acid receptor 1-positive lymphatic vessels in the heart and upregulated LYVE-1 and Podoplanin expressions levels.VEGFR3 was upregulated in the exercised heart,while VEGFR3 inhibitor SAR131675 attenuated exercise-induced physiological cardiac growth as evidenced by blunted myocardial hypertrophy and reduced proliferation marker Ki67 in cardiomyocytes,which was correlated with reduced lymphatic vessel density and downregulated LYVE-1 and Podoplanin in the heart upon exercise.Furthermore,LEC-conditioned medium promoted both hypertrophy and proliferation of cardiomyocytes and contained higher levels of insulinlike growth factor-1 and the extracellular protein Reelin,while LEC-conditioned medium from LECs treated with SAR131675 blocked these effects.Functional rescue assays further demonstrated that protein kinase B(AKT) activation,as well as reduced CCAAT enhancer-binding protein beta(C/EBPβ) and increased CBP/p300-interacting transactivators with E(glutamic acid)/D(aspartic acid)-rich-carboxylterminal domain 4(CITED4),contributed to the promotive effect of LEC-conditioned medium on cardiomyocyte hypertrophy and proliferation.Conclusion:Our findings reveal that cardiac lymphangiogenesis is required for exercise-induced physiological cardiac growth by VEGFR3 activation,and they indicate that LEC-conditioned medium promotes both physiological hypertrophy and proliferation of cardiomyocytes through AKT activation and the C/EBPβ-CITED4 axis.These results highlight the essential roles of cardiac lymphangiogenesis in exercise-induced physiological cardiac growth.展开更多
Membrane distillation(MD)is a promising membrane separation technique used to treat industrial wastewater.When coupled with cheap heat sources,MD has significant economic advantages.Therefore,MD can be combined with s...Membrane distillation(MD)is a promising membrane separation technique used to treat industrial wastewater.When coupled with cheap heat sources,MD has significant economic advantages.Therefore,MD can be combined with solar energy to realize the large-scale and low-cost treatment of highly mineralized mine water in the western coalproducing region of China.In this study,highly mineralized mine water from the Ningdong area of China was subjected to vacuum MD(VMD)using polyvinylidene fluoride hollow-fiber membranes.The optimal operation parameters of VMD were determined by response surface optimization.Subsequently,the feasibility of VMD for treating highly mineralized mine water was explored.The fouling behavior observed during VMD was further investigated by scanning electron microscopy with energy-dispersive X-ray spectroscopy(SEM-EDS).Under the optimal parameters(pressure=-0.08 MPa,temperature=70℃,and feed flow rate=1.5 L/min),the maximum membrane flux was 8.85 kg/(m^(2) h),and the desalination rate was 99.7%.Membrane fouling could be divided into three stages:membrane wetting,crystallization,and fouling layer formation.Physical cleaning restored the flux and salt rejection rate to 94%and 97%of the initial values,respectively;however,the cleaning interval and cleaning efficiency decreased as the VMD run time increased.SEM-EDS analysis revealed that the reduction in flux was caused by the precipitation of CaCO_(3).The findings also demonstrated that the membrane wetting could be attributed to the formation of NaCl on the cross section and outer surface of the membrane.Overall,the results confirm the feasibility of MD for treating mine water and provide meaningful guidance for the industrial application of MD.展开更多
Rechargeable all-solid-state batteries(ASSBs)are considered to be the next generation of devices for electrochemical energy storage.The development of solid-state electrolytes(SSEs)is one of the most crucial subjects ...Rechargeable all-solid-state batteries(ASSBs)are considered to be the next generation of devices for electrochemical energy storage.The development of solid-state electrolytes(SSEs)is one of the most crucial subjects in the field of energy storage chemistry.The newly emerging halide SSEs have recently been intensively studied for application in ASSBs due to their favorable combination of high ionic conductivity,exceptional chemical and electrochemical stability,and superior mechanical deformability.In this review,a critical overview of the development,synthesis,chemical stability and remaining challenges of halide SSEs is given.The design strategies for optimizing the ionic conductivity of halide SSEs,such as element substitution and crystal structure design,are summarized in detail.Moreover,the associated chemical stability issues in terms of solvent compatibility,humid air stability and corresponding degradation mechanisms are discussed.In particular,advanced in situ/operando characterization techniques applied to halide-based ASSBs are highlighted.In addition,a comprehensive understanding of the interface issues,cost issues,and scalable processing challenges faced by halide-based ASSBs for practical application is provided.Finally,future perspectives on how to design high-performance electrode/electrolyte materials are given,which are instructive for guiding the development of halide-based ASSBs for energy conversion and storage.展开更多
Multi-walled carbon nanotubes(MWCNTs)/TiO_(2)composite photocatalysts with high photoactivity were prepared by sol-gel process and further characterized by X-ray diffraction(XRD),scanning electron microscopy(SEM),Four...Multi-walled carbon nanotubes(MWCNTs)/TiO_(2)composite photocatalysts with high photoactivity were prepared by sol-gel process and further characterized by X-ray diffraction(XRD),scanning electron microscopy(SEM),Fourier transform infrared(FT-IR),and UV-vis absorption spectra.Compared to pure TiO_(2),the combination of MWCNTs with titania could cause a significant absorption shift toward the visible region.The photocatalytic performances of the MWCNTs/TiO_(2)composite catalysts were evaluated for the decomposition of Reactive light yellow K-6G(K-6G)and Mordant black 7(MB 7)azo dyes solution under solar light irradiation.The results showed that the addition of MWCNTs enhanced the adsorption and photocatalytic activity of TiO_(2)for the degradation of azo dyes K-6G and MB 7.The effect of MWCNTs content,catalyst dosage,pH,and initial dye concentration were examined as operational parameters.The kinetics of photocatalytic degradation of two dyes was found to follow a pseudo-first-order rate law.The photocatalyst was used for seven cycles with photocatalytic degradation efficiency still higher than 98%.A plausible mechanism is also proposed and discussed on the basis of experimental results.展开更多
Incomplete separation and recycling of nanoparticles are causing undesirable nanopollution and thus raising great concerns with regard to nanosafety.Since microorganisms are important regulator of physiological proces...Incomplete separation and recycling of nanoparticles are causing undesirable nanopollution and thus raising great concerns with regard to nanosafety.Since microorganisms are important regulator of physiological processes in many organisms,the interaction between nanopollution and microbial metabolomics and the resultant impact on the host’s health are important but unclear.To investigate how typical nanopollution perturbs microbial growth and metabolism,Escherichia coli(E.coli)in vitro was treated with six water-dispersible nanomaterials(nanoplastic,nanosilver,nano-TiO 2,nano-ZnO,semiconductor quantum dots(QDs),carbon dots(CDs))at human-/environment-relevant concentration levels.The nanomaterials exhibited type-specific toxic effects on E.coli growth.Global metabolite profiling was used to characterize metabolic disruption patterns in the model microorganism exposed to different nanopollutants.The percentage of significant metabolites(p<0.05,VIP>1)accounted for 6%–38%of the total 293 identified metabolites in each of the nanomaterial-contaminated bacterial groups.Metabolic results also exhibited significant differences between different nanopollutants and dose levels,revealing type-specific and untypical concentration-dependent metabolic responses.Key metabolites responsive to nanopollution exposures were mainly involved in amino acid and purine metabolisms,where 5,4,and 7 significant metabolic features were included in arginine and proline metabolism,phenylalanine metabolism,and purine metabolism,respectively.In conclusion,this study horizontally compared and demonstrated how typical nanopollution perturbs microbial growth and metabolomics in a type-specific manner,which broadens our understanding of the ecotoxicity of nanopollutants on microorganisms.展开更多
基金supported by the grants from National Key Research and Development Project(2018YFE0113500 to JX)National Natural Science Foundation of China(82020108002 and 81911540486 to JX,81970335 and 82170285 to YB)+4 种基金Innovation Program of Shanghai Municipal Education Commission(2017-01-07-00-09-E00042 to JX)Science and Technology Commission of Shanghai Municipality(20DZ2255400 and 18410722200 to JX)the“Dawn”Program of Shanghai Education Commission(19SG34 to JX)the Shanghai Rising-Star Program(19QA1403900 to YB)the Science and Technology Commission of Shanghai Municipality(21SQBS00100 to YB).
文摘Background:Promoting cardiac lymphangiogenesis exerts beneficial effects for the heart.Exercise can induce physiological cardiac growth with cardiomyocyte hypertrophy and increased proliferation markers in cardiomyocytes.However,it remains unclear whether and how lymphangiogenesis contributes to exercise-induced physiological cardiac growth.We aimed to investigate the role and mechanism of lymphangiogenesis in exercise-induced physiological cardiac growth.Methods:Adult C57 BL6/J mice were subjected to 3 weeks of swimming exercise to induce physiological cardiac growth.Oral treatment with vascular endothelial growth factor receptor 3(VEGFR3) inhibitor SAR1 3 1 675 was used to investigate whether cardiac lymphangiogenesis was required for exercise-induced physiological cardiac growth by VEGFR3 activation.Furthermore,human dermal lymphatic endothelial cell(LEC)-conditioned medium was collected to culture isolated neonatal rat cardiomyocytes to determine whether and how LECs could influence cardiomyocyte proliferation and hypertrophy.Results:Swimming exercise induced physiological cardiac growth accompanied by a remarkable increase of cardiac lymphangiogenesis as evidenced by increased density of lymphatic vessel endothelial hyaluronic acid receptor 1-positive lymphatic vessels in the heart and upregulated LYVE-1 and Podoplanin expressions levels.VEGFR3 was upregulated in the exercised heart,while VEGFR3 inhibitor SAR131675 attenuated exercise-induced physiological cardiac growth as evidenced by blunted myocardial hypertrophy and reduced proliferation marker Ki67 in cardiomyocytes,which was correlated with reduced lymphatic vessel density and downregulated LYVE-1 and Podoplanin in the heart upon exercise.Furthermore,LEC-conditioned medium promoted both hypertrophy and proliferation of cardiomyocytes and contained higher levels of insulinlike growth factor-1 and the extracellular protein Reelin,while LEC-conditioned medium from LECs treated with SAR131675 blocked these effects.Functional rescue assays further demonstrated that protein kinase B(AKT) activation,as well as reduced CCAAT enhancer-binding protein beta(C/EBPβ) and increased CBP/p300-interacting transactivators with E(glutamic acid)/D(aspartic acid)-rich-carboxylterminal domain 4(CITED4),contributed to the promotive effect of LEC-conditioned medium on cardiomyocyte hypertrophy and proliferation.Conclusion:Our findings reveal that cardiac lymphangiogenesis is required for exercise-induced physiological cardiac growth by VEGFR3 activation,and they indicate that LEC-conditioned medium promotes both physiological hypertrophy and proliferation of cardiomyocytes through AKT activation and the C/EBPβ-CITED4 axis.These results highlight the essential roles of cardiac lymphangiogenesis in exercise-induced physiological cardiac growth.
基金This research was supported by the Open Fund Project of the State Key Laboratory of Water Resources Protection and Utilization in Coal Mining(GJNY-18-73.13).
文摘Membrane distillation(MD)is a promising membrane separation technique used to treat industrial wastewater.When coupled with cheap heat sources,MD has significant economic advantages.Therefore,MD can be combined with solar energy to realize the large-scale and low-cost treatment of highly mineralized mine water in the western coalproducing region of China.In this study,highly mineralized mine water from the Ningdong area of China was subjected to vacuum MD(VMD)using polyvinylidene fluoride hollow-fiber membranes.The optimal operation parameters of VMD were determined by response surface optimization.Subsequently,the feasibility of VMD for treating highly mineralized mine water was explored.The fouling behavior observed during VMD was further investigated by scanning electron microscopy with energy-dispersive X-ray spectroscopy(SEM-EDS).Under the optimal parameters(pressure=-0.08 MPa,temperature=70℃,and feed flow rate=1.5 L/min),the maximum membrane flux was 8.85 kg/(m^(2) h),and the desalination rate was 99.7%.Membrane fouling could be divided into three stages:membrane wetting,crystallization,and fouling layer formation.Physical cleaning restored the flux and salt rejection rate to 94%and 97%of the initial values,respectively;however,the cleaning interval and cleaning efficiency decreased as the VMD run time increased.SEM-EDS analysis revealed that the reduction in flux was caused by the precipitation of CaCO_(3).The findings also demonstrated that the membrane wetting could be attributed to the formation of NaCl on the cross section and outer surface of the membrane.Overall,the results confirm the feasibility of MD for treating mine water and provide meaningful guidance for the industrial application of MD.
基金the financial support of the Beijing National Laboratory for Condensed Matter Physics,21C Innovation Laboratory,Contemporary Amperex Technology Ltd.through project No.21C-OP-202212the Foundation of Key Laboratory of Advanced Energy Materials Chemistry(Ministry of Education),Nankai University+1 种基金the Foundation of State Key Laboratory of High-Efficiency Utilization of Coal and Green Chemical Engineering(Grant No.2022-K15),China University of Mining&Technology(Beijing)the National Natural Science Foundation of China(Nos.51672029,51372271).
文摘Rechargeable all-solid-state batteries(ASSBs)are considered to be the next generation of devices for electrochemical energy storage.The development of solid-state electrolytes(SSEs)is one of the most crucial subjects in the field of energy storage chemistry.The newly emerging halide SSEs have recently been intensively studied for application in ASSBs due to their favorable combination of high ionic conductivity,exceptional chemical and electrochemical stability,and superior mechanical deformability.In this review,a critical overview of the development,synthesis,chemical stability and remaining challenges of halide SSEs is given.The design strategies for optimizing the ionic conductivity of halide SSEs,such as element substitution and crystal structure design,are summarized in detail.Moreover,the associated chemical stability issues in terms of solvent compatibility,humid air stability and corresponding degradation mechanisms are discussed.In particular,advanced in situ/operando characterization techniques applied to halide-based ASSBs are highlighted.In addition,a comprehensive understanding of the interface issues,cost issues,and scalable processing challenges faced by halide-based ASSBs for practical application is provided.Finally,future perspectives on how to design high-performance electrode/electrolyte materials are given,which are instructive for guiding the development of halide-based ASSBs for energy conversion and storage.
基金the National Natural Science Foundation of China(Grant No.20977013).
文摘Multi-walled carbon nanotubes(MWCNTs)/TiO_(2)composite photocatalysts with high photoactivity were prepared by sol-gel process and further characterized by X-ray diffraction(XRD),scanning electron microscopy(SEM),Fourier transform infrared(FT-IR),and UV-vis absorption spectra.Compared to pure TiO_(2),the combination of MWCNTs with titania could cause a significant absorption shift toward the visible region.The photocatalytic performances of the MWCNTs/TiO_(2)composite catalysts were evaluated for the decomposition of Reactive light yellow K-6G(K-6G)and Mordant black 7(MB 7)azo dyes solution under solar light irradiation.The results showed that the addition of MWCNTs enhanced the adsorption and photocatalytic activity of TiO_(2)for the degradation of azo dyes K-6G and MB 7.The effect of MWCNTs content,catalyst dosage,pH,and initial dye concentration were examined as operational parameters.The kinetics of photocatalytic degradation of two dyes was found to follow a pseudo-first-order rate law.The photocatalyst was used for seven cycles with photocatalytic degradation efficiency still higher than 98%.A plausible mechanism is also proposed and discussed on the basis of experimental results.
基金support from the projects of the National Natural Science Foundation of China(Nos.22006143,21806189)the Science and Technology Program of Guangzhou(China)(No.202102020601)+2 种基金the Natural Science Foundation of Guangdong Province(China)(No.2021A1515012336)the Guangdong Provincial Key R&D Programme(China)(No.2020B1111350002)the special project of Guangdong Enterprise Science and Technology Commissioner(China)(No.GDKTP2021011600).
文摘Incomplete separation and recycling of nanoparticles are causing undesirable nanopollution and thus raising great concerns with regard to nanosafety.Since microorganisms are important regulator of physiological processes in many organisms,the interaction between nanopollution and microbial metabolomics and the resultant impact on the host’s health are important but unclear.To investigate how typical nanopollution perturbs microbial growth and metabolism,Escherichia coli(E.coli)in vitro was treated with six water-dispersible nanomaterials(nanoplastic,nanosilver,nano-TiO 2,nano-ZnO,semiconductor quantum dots(QDs),carbon dots(CDs))at human-/environment-relevant concentration levels.The nanomaterials exhibited type-specific toxic effects on E.coli growth.Global metabolite profiling was used to characterize metabolic disruption patterns in the model microorganism exposed to different nanopollutants.The percentage of significant metabolites(p<0.05,VIP>1)accounted for 6%–38%of the total 293 identified metabolites in each of the nanomaterial-contaminated bacterial groups.Metabolic results also exhibited significant differences between different nanopollutants and dose levels,revealing type-specific and untypical concentration-dependent metabolic responses.Key metabolites responsive to nanopollution exposures were mainly involved in amino acid and purine metabolisms,where 5,4,and 7 significant metabolic features were included in arginine and proline metabolism,phenylalanine metabolism,and purine metabolism,respectively.In conclusion,this study horizontally compared and demonstrated how typical nanopollution perturbs microbial growth and metabolomics in a type-specific manner,which broadens our understanding of the ecotoxicity of nanopollutants on microorganisms.
