Investigation on the mechanism of Qiangxinhuoli prescription in the treatment of chronic heart failure based on p38-MAPK signaling pathway

Background:The aim of this study is to investigate the mechanism of action underlying the therapeutic effects of the national patent Chinese medicine compound“Qiangxinhuoli prescription(QXHLF)”on chronic heart failure(CHF).Methods:In vitro,the H_(9)C_(2) cell model was induced by ANGII,and cell proliferation and related protein expression were detected by Cell Counting Kit-8 and Western blot.In vivo,A rat model of CHF was prepared by ligation of the left anterior descending coronary artery.The effects of QXHLF on cardiac function in CHF rats were evaluated by cardiac index,hemodynamic changes,enzyme-linked immunosorbent assay,hematoxylin-eosin staining,immunohistochemistry,Western blot and RT-PCR.The expression of pro-apoptotic factors and anti-apoptotic factors,as well as TGFβ1,p-p38,TAK 1 mRNA,and protein,were detected.Results:In vitro,QXHLF has a significant inhibitory effect on the proliferation of H_(9)C_(2) cells.QXHLF can reduce the expression levels of TAK 1,TGFβ1,p-p38,Caspase3 and BAX proteins in H_(9)C_(2) cells,and increase the expression level of BCL_(2) protein.In vivo,QXHLF has the potential to increase left ventricular systolic pressure,m aximum rate of change in left ventricular pressure while decreasing left ventricular end diastolic pressure,and inhibiting the serum levels of brain natriuretic peptide.Moreover,QXHLF exhibits significant improvements in the pathological alterations of myocardial cells and fibers in CHF rats,leading to enhanced myocardial tissue morphology and notable advantages in combating myocardial fibrosis.QXHLF can reduce the levels of BAX and Caspase3 and up-regulate the expression of BCL_(2),thereby inhibiting cardiomyocyte apoptosis.Furthermore,QXHLF demonstrates inhibitory effects on the mRNA and protein expression levels of TGFβ_(1),TAK_(1),and p-p38 in the heart tissue of the CHF rat model.Conclusion:These findings indicate that QXHLF has a therapeutic effect on CHF by inhibiting the p38-MAPK signaling pathway,reducing myocardial fibrosis,preventing apoptosis,inhibiting cell proliferation,and restoring myocardial injury.

C_(9)H_(10)O_(2):0.5ZnCl_(2)/SG as a High-Efficiency Catalyst for Desulfurization of Model Oil

A C_(9)H_(10)O_(2):0.5ZnCl_(2)/SG catalyst was synthesized using a one-step sol-gel method with silica gel(SG)as the carrier and C_(9)H_(10)O_(2):0.5ZnCl_(2)deep eutectic solvent(DES)as active component.The structure of the supported catalyst was characterized by FT-IR,XRD,SEM,and N2 adsorption-desorption,and the DES was found to have successfully permeated the SG through its pores.The removal of dibenzothiophene(DBT)in model diesel was studied using C_(9)H_(10)O_(2):0.5ZnCl_(2)/SG as a catalyst and H_(2)O_(2)as an oxidant.The influence of loading dose of DES,reaction temperature,catalyst dosage,O/S molar ratio,and sulfide type on the desulfurization rate was investigated.The removal rates of DBT,4,6-dimethyldibenzothiophene(4,6-DMDBT),and benzothiophene(BT)under optimal reaction conditions were 99.4%,96%,and 78.2%,respectively.C_(9)H_(10)O_(2):0.5ZnCl_(2)/SG catalyst could be recycled five times with a little decrease of oxidative desulfurization activity,and the adsorption-oxidation desulfurization mechanism was examined.

Synergetic enhancement of selectivity for electroreduction of CO_(2)to C_(2)H_(4)by crystal facet engineering and tandem catalysis over silver-incorporated-cuprous oxides

Electrochemical CO_(2)reduction to C_(2)H_(4)can provide a sustainable route to reduce globally accelerating CO_(2)emissions and produce energy-rich chemical feedstocks.However,the poor selectivity in C_(2)H_(4)electrosynthesis limits its implementation in industrially interesting processes.Herein,we report a composite structured catalyst composed of Ag and Cu_(2)O with different crystal faces to achieve highly efficient reduction of CO_(2)to C_(2)H_(4).The catalyst composed of Ag and octahedral Cu_(2)O enclosed with(111)facet exhibits the best CO_(2)electroreduction performance,with the Faradaic efficiency(FE)and partial current density reaching 66.8%and 17.8 mA cm2 for C_(2)H_(4)product at-1.2 VRHE in 0.5 M KHCO_(3),respectively.Physical characterization and electrochemical test analysis indicate that the high selectivity for C_(2)H_(4)product stems from the synergistic effect of crystal faces control engineering and tandem catalysis.Specifically,Ag can provide optimal availability of CO intermediate by suppressing hydrogen evolution;subsequently,C-C coupling is promoted on the intimate surface of Cu_(2)O with facetdependent selectivity.The insights gained from this work may be beneficial for designing efficient multicomponent catalysts for improving the selectivity of electrochemical CO_(2)reduction reaction to generate C2þproducts.

C_(2)H_(2)/CH_(4)燃烧特性实验及反应动力学研究

随着煤矿开采深度的增加,极易出现瓦斯与煤自燃灾害交织共生现象,增大灾害风险.为阐明煤与瓦斯共生灾害发生时的火焰传播特性,有必要开展煤自燃气体掺混对瓦斯燃烧特性的影响研究.乙炔气体(C_(2)H_(2))是煤高温氧化时产生的主要气体之一,甲烷(CH_(4))是瓦斯的主要成分,本文研究了0~2%体积分数C_(2)H_(2)掺混对CH_(4)层流燃烧速度的影响规律.结果表明,随着C_(2)H_(2)体积分数的增加,C_(2)H_(2)/CH_(4)混合燃料层流燃烧速度增大.层流燃烧速度受质热扩散作用、动力学和热力学效应的综合影响,当C_(2)H_(2)体积分数增加至2%时,混合燃料的(αLe)^(1/2)、T_(ad)分别增加了1.54%、2.98%,T_(a)减少了26.93%,说明动力学效应是C_(2)H_(2)促进CH_(4)层流燃烧速度增加的主导因素.由活性自由基体积分数分析可知,随着C_(2)H_(2)体积分数的增加,H、O、OH和CH_(3)等活性自由基体积分数均出现增加趋势,从而促进了CH_(4)的燃烧.

电刺激对过氧化氢诱导衰老肌管细胞能量代谢的影响

目的:运用电刺激肌管细胞收缩模拟骨骼肌收缩,并观察其对过氧化氢(H_(2)O_(2))诱导的C2C12细胞衰老模型能量代谢相关指标表达的影响,以此研究体外肌管收缩对衰老骨骼肌细胞能量代谢影响的分子机制。方法:使用不同浓度的H_(2)O_(2)诱导肌管细胞建立衰老模型,并用β-半乳糖苷酶染色检测衰老水平;电刺激干预培育成功的衰老肌细胞,并分为对照组(C组)、H_(2)O_(2)诱导衰老组(H组)、对照+电刺激组(CE组)、H_(2)O_(2)诱导衰老+电刺激组(HE组)。各组细胞通过Western blot法对PGC-1α蛋白表达进行检测,ATP水平测试盒测量ATP水平。结果:经过浓度为100μmol/L H_(2)O_(2)诱导肌管细胞24 h后成功构建骨骼肌细胞衰老模型。与C组比较,H组的ATP水平表达呈非常显著性的下降(P<0.01);CE组的ATP水平较C组呈非常显著性升高(P<0.01);HE组的ATP水平虽低于C组,但高于H组,且呈非常显著性差异(P<0.01);与C组相比,H组PGC-1α蛋白表达下降,呈非常显著性差异(P<0.01);HE组PGC-1α蛋白表达虽低于C组,但较H组呈非常显著性升高(P<0.01)。结论:H_(2)O_(2)是诱导骨骼肌肌管细胞衰老的一种有效方式,衰老肌管细胞的ATP和PGC-1α蛋白表达水平显著下降,进行电刺激干预后可以有效提高衰老肌管细胞ATP水平和PGC-1α蛋白表达。

用于C_(3)H_(6)/N_(2)分离的PDA@PEBA2533膜的制备

为回收聚丙烯制备尾气中的丙烯,采用本实验室独创的浸渍-旋转法在聚醚嵌段共聚酰胺(PEBA2533)膜表面沉积聚多巴胺(PDA)膜层制备出对C3H6具有更强亲和性的PDA@PEBA2533膜。利用扫描电子显微镜(SEM)和X射线衍射(XRD)对PDA颗粒和膜进行表征。考察了PDA沉积时间对膜形貌、结构以及分离性能的影响,也考察了温度和压力等操作条件对膜分离性能的影响。探索了PDA@PEBA2533膜对不同C3H6浓度的C_(3)H_(6)/N_(2)混合气的分离效果以及膜的长时间分离稳定性。结果表明,沉积PDA于PEBA2533膜表面有效提高了膜的分离性能。当沉积时间不小于24h时,可得到连续的PDA膜层,随沉积时间的增加,膜层逐渐增厚,气体渗透速率先增大后减小,选择性持续上升,沉积24h所制备的膜分离性能最佳。增大操作温度和压力,膜对C3H6和N2的渗透速率均增大,C_(3)H_(6)/N_(2)选择性则降低。增大混合气中C3H6浓度,膜对C3H6的渗透速率和选择性均呈现先上升后下降的趋势。在所制备的分离性能最好的PDA@PEBA2533膜上,0.2MPa时,对C3H6体积分数为20%的混合气,温度从0℃提高到50℃,C3H6渗透速率从8.25GPU增加到71.42GPU,C_(3)H_(6)/N_(2)选择性从22.92降低至10.14。在130h的气体分离实验中,该膜表现出良好的稳定性。该膜与其他分离C_(3)H_(6)/N_(2)混合气膜相比具有一定的优势。

大豆C_(2)H_(2)型锌指蛋白转录因子家族全基因组鉴定及表达分析

为进一步寻找与大豆产量相关的潜在候选基因,利用生物信息学与转录组学技术,通过拟南芥(Arabidopsis thaliana L.)C_(2)H_(2)型锌指蛋白(C_(2)H_(2)zinc finger protein)序列BLAST映射,将从大豆(Glycine max)的基因组数据库中筛选出的44个C_(2)H_(2)锌指蛋白家族成员分成11个亚家族,并对其进行系统进化、保守结构域、顺式作用元件、测序数据和转录组数据等相关分析。结果表明:C_(2)H_(2)锌指蛋白家族成员分布于17条大豆染色体中,且每个亚家族的基因结构域较为相近,呈高度保守性。成员启动子部分含有抗逆境胁迫以及激素相关的调控元件。RNA-seq结果显示,有8个基因在不同植物组织内表达差异显著。荧光定量PCR分析表明,3个基因的分析结果为SUPERMAN的转录调节因子,GmC1-1iZFP42为Ln位点的相应基因,参与大豆叶形和籽粒的调控,GmC1-1iZFP12、GmC1-1iZFP30为SUPERMAN基因的转录调节因子,GmC1-1iZFP21可能参与大豆籽粒形成和发育的过程,为调控相关过程的候选基因。本研究为进一步寻找和挖掘大豆高产基因提供方向,也为C_(2)H_(2)型锌指蛋白和生物信息学在植物中的利用提供参考和启示。

低温阶段煤吸附C_(2)H_(4)的吸附特性研究

为研究煤矿采空区封闭区遗煤吸附C_(2)H_(4)的演化特征,以宁夏灵新煤矿不粘煤为研究对象,采用容量法进行煤吸附C_(2)H_(4)试验,分析温压与粒径对煤吸附C_(2)H_(4)过程中的吸附量、吸附速率和吸附热力学等特征变化的影响。研究表明:当温度为30~60℃、压力为0.15~0.45 MPa、粒径为20~120目时,无论是温度降低、压力升高还是粒径减小,C_(2)H_(4)的吸附量均增加;吸附过程随时间由快变慢,进而趋于平衡,吸附速率快速趋于0;温度与粒径不变,平衡压力越大吸附速率越大;温度与压力不变,粒径越小吸附速率越快。吸附量相同,粒径越小等量吸附热越低;各粒径煤样吸附C_(2)H_(4)的等量吸附热为0.69~40.23 kJ/mol,属于物理吸附。引入压力修正系数进行拟合,温度不变,压力和粒径与吸附自由能降低值呈正比关系;粒径不变,温度与吸附自由能降低值呈反比关系。各粒径煤样吸附C_(2)H_(4)的吸附熵均为负值,吸附量增大,温度降低,吸附熵值均增大;吸附量相同条件下,粒径越大,吸附熵值越大。

高石墨化度多孔炭的制备及其乙烷/乙烯分离性能

乙烷(C_(2)H_(6))与乙烯(C_(2)H_(4))的高效分离对于制备聚合物级C_(2)H_(4)至关重要,需要开发选择性高和稳定性好的C_(2)H_(6)/C_(2)H_(4)吸附剂。本文以酚醛树脂为前驱体,FeCl3为铁源,通过在室温下聚合及800ºC下炭化的方法制备了高石墨化度多孔炭(GC-800,GC=Graphitized Carbon),并利用Vienna Ab-initio Simulation Package(VASP)计算证实了石墨化的多孔炭表面与C_(2)H_(6)分子间的结合能更高。石墨化度的增加可以有效提高多孔炭对C_(2)H_(6)的吸附能力,但高温下Fe的催化石墨化过程会破坏多孔炭的微孔结构,从而降低C_(2)H_(6)/C_(2)H_(4)的分离能力。通过调控炭化温度,实现了对多孔炭的石墨化度与孔隙结构的协同优化。结果表明,GC-800具有高的石墨化度,sp^(2)C的含量高达73%,比表面积高达574 m^(2)·g^(-1)。在298 K和1 bar的条件下GC-800对C_(2)H_(6)的平衡吸附容量为2.16 mmol·g^(-1),C_(2)H_(6)/C_(2)H_(4)(1∶1和1∶9,v/v)Ideal Adsorption Solution Theory(IAST)选择性分别达到2.4和3.8,显著高于大多数报道的高性能C_(2)H_(6)选择性吸附剂。动态穿透实验表明GC-800可以从C_(2)H_(6)和C_(2)H_(4)混合物中一步获得高纯度的C_(2)H_(4)。动态循环测试证实了GC-800具有良好的循环稳定性,含湿条件下GC-800仍能高效分离C_(2)H_(6)/C_(2)H_(4)。

CO_(2)/C_(3)H_(6)O在金属氧化物耦合吡咯氮生物炭表面的共/竞吸附机理研究

本研究采用密度泛函理论,通过比较吸附量、吸附能以及态密度和电荷差分密度的分析,探究了不同金属氧化物耦合吡咯氮生物炭(CN5@MOx,MOx=ZnO、CaO、Na2O)表面CO_(2)与C_(3)H_(6)O(CO_(2)&C_(3)H_(6)O)的吸附机理。首先从CO_(2)/C_(3)H_(6)O单组分方面计算了其在CN5@MOx表面吸附量和吸附能,计算结果表明,在333 K、100 kPa时CN5@Na2O表面对CO_(2)/C_(3)H_(6)O单组分吸附量分别为3.65、15.34 mmol/g,吸附能分别为-145.86、-132.47 kJ/mol,均高于CO_(2)/C_(3)H_(6)O单组分在CN5@CaO及CN5@ZnO表面吸附。得出Na2O掺杂吡咯氮生物炭对CO_(2)/C_(3)H_(6)O单组分吸附效果最优。进一步研究了CO_(2)&C_(3)H_(6)O在CN5@MOx表面共/竞吸附及机理。计算结果表明,CO_(2)&C_(3)H_(6)O在CN5@Na2O、CN5@CaO、CN5@ZnO表面吸附存在临界温度(分别为333、353、393 K),超过临界温度以后CO_(2)&C_(3)H_(6)O共存体系在CN5@MOx表面吸附量较CO_(2)/C_(3)H_(6)O单组分有所提高。CO_(2)&C_(3)H_(6)O在CN5@Na2O、 CN5@CaO、 CN5@ZnO表面吸附能分别比CO_(2)或C_(3)H_(6)O单组分吸附时至少高141.59、112.77、31.75 kJ/mol,CN5@MOx表面对CO_(2)和C_(3)H_(6)O的吸附表现为协同促进作用,且CN5@Na2O对CO_(2)&C_(3)H_(6)O共同吸附效果最佳。采用电荷差分密度和态密度分析CO_(2)&C_(3)H_(6)O在CN5@MOx表面协同吸附作用机理,得出CO_(2)的吸附作用力是通过C_(3)H_(6)O与CO_(2)的间接相互作用产生的,Na2O中Na与C_(3)H_(6)O电子云重叠,发生电荷转移,增强了两者间相互作用力,CN5@Na2O表面C_(3)H_(6)O与CN5在p轨道主要共振峰结合能较CN5@ZnO低了3.43 eV,使得C_(3)H_(6)O在CN5@Na2O表面吸附最稳定。

C_(2)H_(2)气体流量对WC-DLC涂层结构与性能的影响

文章采用直流磁控溅射技术制备WC-DLC耐磨涂层,为了探究C_(2)H_(2)流量对WC-DLC涂层表截面形貌、微观结构、力学和摩擦学性能的影响,在10−50 mL/min C_(2)H_(2)流量下制备了WC-DLC涂层并进行表征分析。结果表明,随着C_(2)H_(2)流量的增加,涂层中碳含量增加,晶粒逐渐细化,由柱状晶逐渐转变为细晶粒,涂层变得更加致密;涂层纳米硬度与sp3杂化的C原子含量密切相关,随着涂层中sp3-C含量的增加,硬度先升高然后降低,磨损率也先升高降低;随着碳原子含量升高,涂层中出现大量的非晶碳,表面晶粒非晶化,涂层的摩擦系数逐渐减小且更加稳定。

基于预混滞止火焰合成的纳米SnO_(2)气敏性能研究

采用预混滞止火焰合成二氧化锡(SnO_(2))纳米颗粒,分析其物相、微观形貌。与化学合成SnO_(2)相比,火焰合成SnO_(2)粒径更小,仅53nm左右,且粒径分布窄,分散性强。将2种方法合成的SnO_(2)制作成传感器,研究两者对乙烯(C_(2)H_(4))的响应情况。结果显示,在500×10^(-6)C_(2)H_(4)下,火焰合成SnO_(2)的最大响应值为5.82,是化学合成SnO_(2)的2倍多。火焰合成SnO_(2)最佳工作温度为400℃,比化学合成SnO_(2)最佳工作温度低60℃。随着C_(2)H_(4)体积分数增加,火焰合成SnO_(2)的响应值增大,并与化学合成SnO_(2)的差距越来越大。SnO_(2)的响应速度随气体体积分数增大先降后升,最后达到稳定值,其中火焰合成SnO_(2)相比化学合成SnO_(2)在达到稳定值时,响应时间减少了2~3s。探究其响应机理,火焰合成SnO_(2)提高气敏性能主要得益于颗粒尺寸的缩小。

Direct Ethylene Purification from Cracking Gas via a Metal–Organic Framework Through Pore Geometry Fitting

The direct one-step separation of polymer-grade C_(2)H_(4) from complex light hydrocarbon mixtures has high industrial significance but is very challenging.Herein,an ethylene-adsorption-weakening strategy is applied for precise regulation of the pore geometry of four tailor-made metal–organic frameworks(MOFs)with pillar-layered structures,dubbed TYUT-10/11/12/13.Based on its pore geometry design and functional group regulation,TYUT-12 exhibits exceptional selective adsorption selectivity toward C_(3)H_(8),C_(3)H_(6),C_(2)H_(6),C_(2)H_(2),and CO_(2) over C_(2)H_(4);its C_(2)H_(6)/C_(2)H_(4) adsorption selectivity reaches 4.56,surpassing the record value of 4.4 by Fe_(2)(O_(2))(dobdc)(dobdc^(4-)=2,5-dioxido-1,4-benzenedicarboxylate).The weak p–p stacking binding affinity toward C_(2)H_(4) in TYUT-12 is clearly demonstrated through a combination of neutron powder diffraction measurements and theoretical calculations.Breakthrough experiments demonstrate that C_(2)H_(4) can be directly obtained from binary,ternary,quaternary,and six-component light hydrocarbon mixtures with over 99.95%purity.

缺陷CuAg催化剂的构筑及电催化CO_(2)还原制备C_(2+)产物

通过电化学还原Ag/Cu(OH)2构筑得到了富含缺陷位点的Ag/Cu-OH催化剂,与Ag/CuO前驱体电化学还原获得的Ag/Cu-O相比,其表现出更好的电催化二氧化碳还原反应(CO_(2)RR)制备C_(2+)产物的选择性.在H型电解槽(H-cell)中评估了催化剂的电催化性能,Ag2%/Cu-OH表现出比Ag2%/Cu-O高1.5倍的乙烯(C_(2)H_(4))法拉第效率(FE)和高1.3倍的C_(2+)法拉第效率.在接近实际应用的膜电极组件(MEA)中,Ag2%/Cu-OH在高达375 mA/cm^(2)的电流密度下,表现出高达56.2%的C_(2)H_(4)法拉第效率.Ag2%/Cu-OH性能的提高不仅归因于Cu和Ag之间的协同作用,还归因于具有更多的低配位Cu缺陷位点,低配位Cu有利于*CO的吸附,进一步促进了^(*)CO二聚为C_(2+)产物.

硫掺杂管状多孔g-C_(3)N_(4)光催化剂的制备及其催化性能

以体相石墨相氮化碳(g-C_(3)N_(4))为原料,硫代乙酰胺(TAA)为硫源,通过一步水热法得到管状多孔S掺杂g-C_(3)N_(4)光催化剂(SCNB-18)。S的引入扩大了g-C_(3)N_(4)的可见光吸收范围,且管状多孔的形貌特征提高了光催化剂的比表面积,与体相g-C_(3)N_(4)相比,所合成SCNB-18的比表面积高达170.6 m^(2)/g。另外,对样品的微观形貌结构以及光电性能进行表征,并通过光催化分解水制氢以及降解水中污染物来评估样品的催化性能。研究结果表明,SCNB-18光催化剂具有优异的光催化活性和良好的循环稳定性。

高通量计算筛选分离乙烷/乙烯的金属有机框架材料

乙烯属于具有高附加值的化工产品之一,从乙烷蒸汽裂解产生乙烯后的混合气体中分离乙烯具有重要的应用,筛选用于C_(2)H_(6)/C_(2)H_(4)吸附分离的高性能金属有机骨架(MOF)材料迫在眉睫.通过先前文献报道从CoRE MOFs(2019)数据库中得出的重要结构吸附性质关系(SAPR),随后用于在G-MOFs和hMOFs数据库中筛选高性能MOFs.综合考虑热稳定性和吸附剂性能评分(APS),筛选出6种有希望用于C_(2)H_(6)/C_(2)H_(4)分离的MOFs,其中C_2H_6吸附量均大于1.05 mmol/g,选择性均大于1.99,其性能优于大多数文献报道的框架.研究发现这些MOFs对C_2H_6,C_2H_4的吸附等温线属于I型曲线,C_(2)H_(6)/C_(2)H_(4)分离的机理为热力学分离.此外,通过能量分解分析(EDA)的独立梯度模型(IGMH)电子结构计算,发现客体与框架之间的相互作用为vdW作用.当前采用的基于SAPR筛选方法有助于快速预测分离新型MOF吸附剂.

基于TDLAS的变压器油中C_(2)H_(2)在线监测装置设计

随着电力行业的不断发展,变压器的安全与稳定愈发重要。为满足变压器油中C_(2)H_(2)的在线监测需要,选取1532 nm的分布式半导体激光器与12 m光程怀特池,研制了基于可调谐二极管激光吸收光谱技术与波长调制技术的变压器油中C_(2)H_(2)在线监测装置,实现了油中溶解C_(2)H_(2)分离、气体检测、结果分析等功能,测量周期约为25 min,测试过程无损样本。该装置检测精准快速,无需人工操作,可为变压器提供实时的安全参考意见。

基于铑活化环氧树脂基板表面化学镀铜技术探究

环氧树脂基板被广泛应用于印制电路板生产中,由于基材本身惰性和较低表面能,不利于化学镀铜层的沉积,因而通常需要进行改性处理。本文提供了一种新型的环氧树脂基板化学镀铜工艺方法,将有机金属化合物Rh(C_(5)H_(7)O_(2))(CO)(PPh_(3))与双酚A型环氧树脂混合作为基材表面催化化学镀铜的活化改性层,再利用1 mol/L的硼氢化钠溶液进行40 min还原处理,最后进行化学镀铜。通过基板间剪切强度测试,发现得到的改性层与基板之间结合力较好,可满足PCB实际生产需求。利用粗糙度测试以及SEM测试分析,经过还原处理后的基材表面Ra=6.72 nm相较于未经过还原处理的基材改性层表面的Ra=5.43 nm有明显提升,从金相显微镜图和SEM测试图中可看出该技术制备的化学镀镀层表面的铜晶粒分布均匀且结晶致密,说明该化学镀铜工艺可得到表面平整光滑、厚度均匀的镀铜层。

MOFs材料在C_(2)H_(2)存储及吸附分离中的研究进展

针对当前工业中存在的乙炔(C_(2)H_(2))及含C_(2)H_(2)二元组分气体的存储与高效分离问题,梳理了近年来金属有机骨架材料(MOFs)对C_(2)H_(2)气体的吸附存储和分离研究。重点比较了含C_(2)H_(2)的二元组分气体与MOFs材料之间的构效关系及分离不同二元组分气体所用MOFs材料的筛选条件与设计原则,以期实现MOFs材料对C_(2)H_(2)的高效分离,达到对C_(2)H_(2)的纯化及存储效果,促进未来MOFs材料在该领域的发展。最后展望了MOFs材料在此方面的应用前景。

Synthesis of cystine C_(60) derivative and its protective effects on hydrogen peroxide-induced apoptosis in PC12 cells

Oxidative stress has been considered as a major cause of cellular injuries in a variety of clinical abnormalities, especially prominent in neural diseases. One of the usable ways to prevent the reactive oxygen species (ROS)-mediated cellular injury is dietary or pharmaceutical augmentation of some free radical scavenger. Water-soluble amino-fullerene is a novel compound that behaves as a free radical scavenger with excellent biology consistent. In the present study, we have synthesized and characterized a novel cystine C60 derivative for the first time, and investigated the effects on hydrogen peroxide-induced oxidative stress and apoptotic death in cultured rat pheochromocytoma (PC12) cells. PC12 cells treated with hydrogen peroxide underwent apoptotic death as determined by MTT, PI/Hoechst 33342 staining and flow cytometry analysis. These results suggested that cystine C60 derivative has the potential to prevent oxidative stress-induced cell death and has no evident toxicity.