Ammonia is one of the most important chemical raw materials in both manufacture and life of human.Traditionally Haber-Bosch method for ammonia synthesis involves high temperature and high pressure conditions,leading t...Ammonia is one of the most important chemical raw materials in both manufacture and life of human.Traditionally Haber-Bosch method for ammonia synthesis involves high temperature and high pressure conditions,leading to significant energy consumption and environmental pollution.Non-thermal plasma(NTP) is a promising alternative approach to ammonia synthesis at low temperature and atmospheric pressure.In this study,the synergistic effect of nanosecond pulsed dielectric barrier discharge(np-DBD) and Ni-MOF-74 catalyst was investigated in ammonia synthesis by utilizing nitrogen and hydrogen as feedstock.The results demonstrated that the plasma catalytic-synthesis process parameters play a crucial role in the synthesis process of ammonia.The highest ammonia synthesis rate of 5145.16 μmol·g^(-1)·h^(-1)with an energy efficiency of 1.27 g·kWh^(-1)was observed in the presence of the Ni-MOF-74 catalyst,which was3.7 times higher than that without Ni-MOF-74 catalyst.The synergistic effect of Ni-MOF-74catalyst and nanosecond pulsed plasma was explored by in-situ plasma discharge diagnostics.展开更多
In recent years,various particulate materials have played important roles in medical applications.However,nano-and micron-sized particles of the same material could exhibit distinct properties due to different particl...In recent years,various particulate materials have played important roles in medical applications.However,nano-and micron-sized particles of the same material could exhibit distinct properties due to different particle sizes.This finding provided a simple and effective way to improve the biological applications of particulate materials.Therefore,as a highly promising member,the effect of the particle size change of the magnesium metal organic framework-74(Mg-MOF74)was well worth evaluating.Here we firsth assessed the in vitro and in vivo toxicity of micron/nanoscale Mg-MOF74(m-Mg-MOF74/n-Mg-MOF74)in detail.Our in vitro study revealed that compared to micron-sized subjects,n-Mg-MOF74 provided a wider range of safe concentrations.Furthermore,both micron/nanoscale Mg-MOF74 showed good biocompatibility and allowed all the rats under the treatment to survive through the expected experimental periods,with n-Mg-MOF74 still showing lower cardiotoxicity.These advantages of nanoscale Mg-MOF74might benefit from its sustainable and balanced release of Ma^2+both inside and outside the cells.Based on the biosafety evaluation,advanced bio-functional assessments of m/n-Mg-MOF74 including early osteogenesis and angiogenesis were alsoperformed.Similarly,the suitable dose groups of n-Mg-MOF74 achieved optimal early osteogenic promotion and angiogenic stimulation effects.Overall,our combined data delineated the toxicity and biological behaviors of Ma-MOF74 of different scales,and sugqested nanoscale Mg-MOF74 as a better choice for future applications.This result revealed that particle size reductior might be a viable strategy to improve and expand medical applications of MOFs or other particulate materials.展开更多
Cluster of differentiation 74(CD74),also called as major histocompatibility complex class Ⅱ(MHCⅡ)invariant chain,is involved in trafficking MHCⅡ cell surface molecules on antigen-presenting cells and has been impli...Cluster of differentiation 74(CD74),also called as major histocompatibility complex class Ⅱ(MHCⅡ)invariant chain,is involved in trafficking MHCⅡ cell surface molecules on antigen-presenting cells and has been implicated in many signaling pathways.For example,the interaction between CD74 and macrophage migration inhibitory factor cyto kine(MIF) leads to the activation of a plethora of pathways such as extracellular regulated protein kinases,phosphoinositide 3-kinase.展开更多
基金the financial support from the Beijing Municipal Natural Science Foundation (No. 1242015)National Undergraduate Innovation and Entrepreneurship Training Program of China (No. 202310015019)Discipline Construction of Material Science and Engineering(Nos. 21090122014 and 21090123007)。
文摘Ammonia is one of the most important chemical raw materials in both manufacture and life of human.Traditionally Haber-Bosch method for ammonia synthesis involves high temperature and high pressure conditions,leading to significant energy consumption and environmental pollution.Non-thermal plasma(NTP) is a promising alternative approach to ammonia synthesis at low temperature and atmospheric pressure.In this study,the synergistic effect of nanosecond pulsed dielectric barrier discharge(np-DBD) and Ni-MOF-74 catalyst was investigated in ammonia synthesis by utilizing nitrogen and hydrogen as feedstock.The results demonstrated that the plasma catalytic-synthesis process parameters play a crucial role in the synthesis process of ammonia.The highest ammonia synthesis rate of 5145.16 μmol·g^(-1)·h^(-1)with an energy efficiency of 1.27 g·kWh^(-1)was observed in the presence of the Ni-MOF-74 catalyst,which was3.7 times higher than that without Ni-MOF-74 catalyst.The synergistic effect of Ni-MOF-74catalyst and nanosecond pulsed plasma was explored by in-situ plasma discharge diagnostics.
基金This study was supported by the National Natural Science Foundation of China(Nos.81601613,81771122,81970985,and 81970984)Key research program of Sichuan Science and technology Department(No.2018SZ0037).
文摘In recent years,various particulate materials have played important roles in medical applications.However,nano-and micron-sized particles of the same material could exhibit distinct properties due to different particle sizes.This finding provided a simple and effective way to improve the biological applications of particulate materials.Therefore,as a highly promising member,the effect of the particle size change of the magnesium metal organic framework-74(Mg-MOF74)was well worth evaluating.Here we firsth assessed the in vitro and in vivo toxicity of micron/nanoscale Mg-MOF74(m-Mg-MOF74/n-Mg-MOF74)in detail.Our in vitro study revealed that compared to micron-sized subjects,n-Mg-MOF74 provided a wider range of safe concentrations.Furthermore,both micron/nanoscale Mg-MOF74 showed good biocompatibility and allowed all the rats under the treatment to survive through the expected experimental periods,with n-Mg-MOF74 still showing lower cardiotoxicity.These advantages of nanoscale Mg-MOF74might benefit from its sustainable and balanced release of Ma^2+both inside and outside the cells.Based on the biosafety evaluation,advanced bio-functional assessments of m/n-Mg-MOF74 including early osteogenesis and angiogenesis were alsoperformed.Similarly,the suitable dose groups of n-Mg-MOF74 achieved optimal early osteogenic promotion and angiogenic stimulation effects.Overall,our combined data delineated the toxicity and biological behaviors of Ma-MOF74 of different scales,and sugqested nanoscale Mg-MOF74 as a better choice for future applications.This result revealed that particle size reductior might be a viable strategy to improve and expand medical applications of MOFs or other particulate materials.
文摘Cluster of differentiation 74(CD74),also called as major histocompatibility complex class Ⅱ(MHCⅡ)invariant chain,is involved in trafficking MHCⅡ cell surface molecules on antigen-presenting cells and has been implicated in many signaling pathways.For example,the interaction between CD74 and macrophage migration inhibitory factor cyto kine(MIF) leads to the activation of a plethora of pathways such as extracellular regulated protein kinases,phosphoinositide 3-kinase.