Role of methoxy and C_(α)-based substituents in electrochemical oxidation mechanisms and bond cleavage selectivity of β-O-4 lignin model compounds

In order to better understand the specific substituent effects on the electrochemical oxidation process of β-O-4 bond, a series of methoxyphenyl type β-O-4 dimer model compounds with different localized methoxyl groups, including 2-(2-methoxyphenoxy)-1-phenylethanone, 2-(2-methoxyphenoxy)-1-phenylethanol, 2-(2-methoxyphenoxy)-1-(4-methoxyphenyl)ethanone, 2-(2-methoxyphenoxy)-1-(4-methoxyphenyl)ethanol, 2-(2,6-dimethoxyphenoxy)-1-(4-methoxyphenyl)ethanone, 2-(2,6-dimethoxyphenoxy)-1-(4-methoxyphenyl)ethanol have been selected and their electrochemical properties have been studied experimentally by cyclic voltammetry, and FT-IR spectroelectrochemistry. Combining with electrolysis products distribution analysis and density functional theory calculations, oxidation mechanisms of all six model dimers have been explored. In particular, a total effect from substituents of both para-methoxy(on the aryl ring closing to Cα) and Cα-OH on the oxidation mechanisms has been clearly observed, showing a significant selectivity on the Cα-Cβbond cleavage induced by electrochemical oxidations.

Oxidation behavior of FeV_(2)O_(4)and FeCr_(2)O_(4)particles in the air:Nonisothermal kinetic and reaction mechanism

High-temperature oxidation behavior of ferrovanadium(FeV_(2)O_(4))and ferrochrome(FeCr_(2)O_(4))spinels is crucial for the application of spinel as an energy material,as well as for the clean usage of high-chromium vanadium slag.Herein,the nonisothermal oxidation behavior of FeV_(2)O_(4)and FeCr_(2)O_(4)prepared by high-temperature solid-state reaction was examined by thermogravimetry and X-ray diffraction(XRD)at heating rates of 5,10,and 15 K/min.The apparent activation energy was determined by the Kissinger-Akahira-Sunose(KAS)method,whereas the mechanism function was elucidated by the Malek method.Moreover,in-situ XRD was conducted to deduce the phase transformation of the oxidation mechanism for FeV_(2)O_(4)and FeCr_(2)O_(4).The results reveal a gradual increase in the overall apparent activation energies for FeV_(2)O_(4)and FeCr_(2)O_(4)during oxidation.Four stages of the oxidation process are observed based on the oxidation conversion rate of each compound.The oxidation mechanisms of FeV_(2)O_(4)and FeCr_(2)O_(4)are complex and have distinct mechanisms.In particular,the chemical reaction controls the entire oxidation process for FeV_(2)O_(4),whereas that for FeCr_(2)O_(4)transitions from a three-dimensional diffusion model to a chemical reaction model.According to the in-situ XRD results,numerous intermediate products are observed during the oxidation process of both compounds,eventually resulting in the final products FeVO_(4)and V2O_(5)for FeV_(2)O_(4)and Fe_(2)O_(3)and Cr_(2)O_(3)for FeCr_(2)O_(4),respectively.

Significantly enhanced performance and conductivity mechanism in Nb/Mn co-doped CaBi_(4)Ti_(4)O_(15)ferroelectrics

With the rapid development of high-end industries,the demand for high-temperature piezoelectric materials is significantly increasing.However,realizing the ultra-high performance to meet more ap-plications still faces major scientific and engineering challenges of our time.Here,a new Nb/Mn co-doped CaBi_(4)Ti_(4)O_(15)(CBT)high-temperature piezoelectric material system of CaBi_(4)Ti_(4-x)(Nb_(2/3)Mn_(1/3))_(x)O_(15)was synthesized by the conventional solid-state sintering method.The results show that the addition of the dopants tends to break the long-range ferroelectric chain and soften the flexibility of polarization,resulting in more distorted crystal structure and better ferroelectric properties of CBT ceramics.The ultra-high piezoelectric constant(d_(33)=26.8 pC/N)is thus attained in CBT-based ceramics with x=0.12,which is about several times larger than that of pure CBT ceramics.Moreover,numerous nano-sized layered domain structures that lie on the lateral plane of grains are observed in ceramics,with lower domain wall energy and better dynamic features under electric fields,mainly responsible for the origin of enhanced performance.Besides,excess dopants could make the conductivity mechanism of CBT ceramics transform from p-type to n-type,and also result in a shift of conduction relaxation mechanism from defect dipole rotation polarization to electron relaxation polarization.The work not only provides a promising candidate for high-temperature piezoelectric materials,but also opens a window for opti-mizing performance by tailoring domain structures using chemical modification.

Study on the oxidation mechanism of Al-SiC composite at elevated temperature

Resin-bonded Al-SiC composite was sintered at 1100,1300,and 1500℃ in the air,the oxidation mechanism was investigated.The reaction models were also established.The oxidation resistance of the Al-SiC composite was significantly enhanced with temperature increase.SiC in the exterior of the composite was partially oxidized slightly,while the transformation of metastable Al_(4)C_(3) to stable Al_(4)SiC_(4) existed in the interior.At 1100℃,Al in the interior reacted with residual C to form Al_(4)C_(3).With increasing to 1300℃,high temperature and low oxygen partial pressure lead to active oxidation of SiC,and internal gas composition transforms to Al_(2)O(g)+CO(g)+SiO(g)as the reaction proceeds.After Al_(4)C_(3) is formed,CO(g)and SiO(g)are continuously deposited on its surface,transforming to Al_(4)SiC_(4).At 1500℃,a dense layer consisting of SiC and Al_(4)SiC_(4) whiskers is formed which cuts off the diffusion channel of oxygen.The active oxidation of SiC is accelerated,enabling more gas to participate in the synthesis of Al_(4)SiC_(4),eventually forming hexagonal lamellar Al_(4)SiC_(4) with mutual accumulation between SiC particles.Introducing Al enhances the oxidation resistance of SiC.In addition,the in situ generated non-oxide is uniformly dispersed on a micro-scale and bonds SiC stably.

Oxidation behavior of ferrovanadium spinel particles in air:Isothermal kinetic and reaction mechanism

The oxidation behavior of ferrovanadium spinel(FeV_(2)O_(4)),synthesized via high-temperature solid-state reaction,was investigated using thermogravimetry,X-ray diffractometry,and X-ray photoelectron spectroscopy over the temperature range of 450–700℃.The results revealed that the oxidation process of FeV_(2)O_(4)can be divided into three stages with the second stage being responsible for maximum weight gain due to oxidation.Three classical methods were employed to analyze the reaction mechanisms and model functions for distinct oxidation stages.The random nucleation and subsequent growth(A_(3))kinetic model was found to be applicable to both initial and secondary stage.The third stage of oxidation was consistent with the three-dimensional diffusion,spherical symmetry(D_(3))kinetic mode.Both the model-function method and the model-free method were utilized to investigate the apparent activation energy of the oxidation reaction at each stage.It was found that the intermediates including Fe_(3)O_(4),VO_(2),V_(2)O_(3),and Fe_(2.5)V_(7.11)O_(16),played significant roles in the oxidation process prior to the final formation of FeVO_(4)and V_(2)O_(5)through oxidation of FeV_(2)O_(4).

Mechanical Properties and Electronic Structures of M(M=Ti,V,Cr,Mn and Fe)Dopedβ-Si_(3)N_(4) from First-Principle

The structures,mechanical properties and electronic structures of M metals(M=Ti,V,Cr,Mn and Fe)dopedβ-Si_(3)N_(4) were investigated by First-principles calculations within CASTEP.The calculated lattice parameters ofβ-Si_(3)N_(4) were consistent with previous date.The cohesive energy and formation enthalpy show that initialβ-Si_(3)N_(4) has the highest structural stability.The calculated elastic constant and the Voigt-Reuss-Hill approximation indicate that elastic moduli ofβ-Si_(3)N_(4) are slightly reduced by M doping.Based on Poisson’s and Pugh’s ratio,β-Si_(3)N_(4) is a ductile material and the toughness ofβ-Si_(3)N_(4) increases with M doping,and Fe doping exhibited the best toughness.The results of density of states,charge distributions and overlapping populations indicate thatβ-Si_(3)N_(4) has the strong covalent and ionic bond strength between N and Si.

Effects of Diamond on the Mechanical Properties and Thermal Conductivity of Si_(3)N_(4)Composites Fabricated Using Spark Plasma Sintering

Micrometer-sized diamonds were incorporated into silicon nitride(Si_(3)N_(4))matrix to manufacture high-performance Si_(3)N_(4)-based composites using spark plasma sintering at 1500℃under 50 MPa.The effects of the diamond content on the phase composition,microstructure,mechanical properties and thermal conductivity of the composites were investigated.The results showed that the addition of diamond could effectively improve the hardness of the material.The thermal conductivity of Si_(3)N_(4)increased to 52.97 W/m·k at the maximum with the addition of 15 wt%diamond,which was 27.5%higher than that of the monolithic Si_(3)N_(4).At this point,the fracture toughness was 7.54 MPa·m^(1/2).Due to the addition of diamond,the composite material generated a new substance,MgSiN2,which effectively combined Si_(3)N_(4)with diamond.MgSiN2 might improve the hardness and thermal conductivity of the materials.

Design and Research of Form Controlled Planar Folding Mechanism based on 4D Printing Technology

The use of non-smart materials in structural components and kinematic pairs allows for flexible assembly in practical applications and is promising for aerospace applications.However,this approach can result in a complex structure and excessive kinematic pairs,which limits its potential applications due to the difficulty in controlling and actuating the mechanism.While smart materials have been integrated into certain mechanisms,such integration is generally considered a unique design for specific cases and lacks universality.Therefore,organically combining universal mechanism design with smart materials and 4D printing technology,innovating mechanism types,and systematically exploring the interplay between structural design and morphing control remains an open research area.In this work,a novel form-controlled planar folding mechanism is proposed,which seamlessly integrates the control and actuation system with the structural components and kinematic pairs based on the combination of universal mechanism design with smart materials and 4D printing technology,while achieving self-controlled dimensional ratio adjustment under a predetermined thermal excitation.The design characteristics of the mechanism are analyzed,and the required structural design parameters for the preprogrammed design are derived using a kinematic model.Using smart materials and 4D printing technology,folding programs based on material properties and control programs based on manufacturing parameters are encoded into the form-controlled rod to achieve the preprogrammed design of the mechanism.Finally,two sets of prototype mechanisms are printed to validate the feasibility of the design,the effectiveness of the morphing control programs,and the accuracy of the theoretical analysis.This mechanism not only promotes innovation in mechanism design methods but also shows exceptional promise in satellite calibration devices and spacecraft walking systems.

Combustion behavior and mechanism of molecular perovskite energetic material DAP-4-based composites with metal fuel Al

Combined with the oxidizer anions and fuel cations,molecular perovskite energetic materials show a good potential.In this work,the combustion behavior and mechanism of metal fuel aluminium(Al)with molecular perovskite energetic material(H_(2)dabco)[NH4(ClO_(4))_(3)](DAP-4)as a high-energy oxidant was investigated.The DAP-4 based composites with metal fuel Al were designed and fabricated by the different mass ratios.Results showed that DAP-4 exhibits a good oxygen-supplied capacity for enhancing the combustion performance of Al.The maximum combustion heat of DAP-4/Al-3 at the Al/O mass ratio of 38:62 is up to 10,412 J/g in the inert gas,which is higher than those of other ratios and the mixtures of other energetic materials and Al.The evolution of pressure output,pressurization rate,and flame temperature was monitored for DAP-4/Al with different mass ratios.Composites DAP-4/Al/F were characterized by burning rates.The combustion reaction mechanism of metal fuel Al with DAP-4 as a high-energy oxidant was provided.DAP-4 was ignited firstly and released acid and oxidizing gases,which corroded Al_(2)O_(3)shells on Al particle surfaces and accelerated the combustion reaction with Al to release a lot of energy.This work offered a new idea that molecular perovskite energetic materials have great potential in the high-energy Al-based solid rocket propellants.

Formation mechanism of MgB_2 in 2LiBH_4+MgH_2 system for reversible hydrogen storage

The formation conditions of MgB2 in 2LiBH4 ＋ MgH2 system during dehydrogenation were investigated and its mechanism was discussed. The results show that direct decomposition of LiBH4 is suppressed under relative higher initial dehydrogenation pressure of 4.0×10^5 Pa, wherein LiBH4 reacts with Mg to yield MgB2, and 9.16% （mass fraction） hydrogen is released within 9.6 h at 450 ℃. However, under relatively lower initial dehydrogenation pressure of 1.0×10^2 Pa, LiBH4 decomposes independently instead of reacting with Mg, resulting in no formation of MgB2, and 7.91% hydrogen is desorbed within 5.2 h at 450 ℃. It is found that the dehydrogenation of 2LiBH4 ＋ MgH2 system proceeds more completely and more hydrogen desorption amount can be obtained within a definite time by forming MgB2. Furthermore, it is proposed that the formation process of MgB2 includes incubation period and nucleus growth process. Experimental results show that the formation process of MgB2, especially the incubation period, is promoted by increasing initial dehydrogenation pressure at constant temperature, and the incubation period is also influenced greatly by dehydrogenation temperature.

Framework-solvent interactional mechanism and effect of NMP/DMF on solvothermal synthesis of [Zn_4O(BDC)_3]_8

In order to explore the effect mechanism of solvent on the synthesis of the metal organic framework materials, the microscopic interaction between solvent and framework and the effects of N,N-dimethyl-formamide(DMF) or N-methyl- 2-pyrrolidone(NMP) on solvothermal synthesis of [Zn4O(BDC)3]8 were investigated through a combined DFT and experimental study. XRD and SEM showed that the absorbability of NMP in the pore of [Zn4O(BDC)3]8 was weaker than that of DMF. The thermal decomposition temperature of [Zn4O(BDC)3]8 synthesized in DMF was higher than that in NMP according to TG and FT-IR. In addition, the nitrogen sorption isotherms indicated that NMP improved gas sorption property of [Zn4O(BDC)3]8. The COSMO optimized calculations indicated that the total energy of Zn4O(BDC)3 in NMP was higher than that in DMF, and compared with non-solvent system, the charge of zinc atoms decreased and the charge value was the smallest in NMP. Furthermore, the interaction of DMF, NMP or DEF in [Zn4O(BDC)3]8 crystal model was calculated by DFT method. The results suggested that NMP should be easier to be removed from pore of materials than DMF from the point of view of energy state. It can be concluded that NMP was a favorable solvent to synthesize [Zn4O(BDC)3]8 and the microscopic mechanism was that the binding force between Zn4O(BDC)3 and NMP molecule was weaker than DMF.

基于阵列声波测井估算碳酸盐岩储层岩石力学和地应力参数——以顺北4号带为例

地质力学分析在油气藏勘探开发过程中发挥着重要作用,顺北油气田中—下奥陶统一间房组—鹰山组储层地应力研究相对滞后。对比分析了顺北4号带下古生界中—下奥陶统一间房组—鹰山组碳酸盐岩不同类型储层的岩石力学和地应力特征,同时探讨了微观颗粒结构对碳酸盐岩储层地应力和岩石力学参数的控制作用,为顺北地区超深层碳酸盐岩储层评价提供了基础地质依据。基于弹簧组合模型,通过岩石力学实验和阵列声波测井确定了岩石力学和地应力特征,通过铸体薄片和X射线CT扫描表征碳酸盐岩的微观孔隙结构。研究结果表明:顺北4号带一间房组—鹰山组杨氏模量分布在50~89 GPa,抗压强度在99~136 MPa,泊松比在0.25~0.32;地层最大水平主应力为200~225 MPa,最小水平主应力为125~160 MPa。一间房组—鹰山组碳酸盐岩不同类型储层的岩石力学参数和地应力存在明显差异,从Ⅰ类、Ⅱ类、Ⅲ类到非储层段碳酸盐岩的杨氏模量、抗压强度和最大水平主应力明显增大,而泊松比和最小水平主应力变化不大。相比于一间房组—鹰山组泥晶灰岩,砂屑-生屑灰岩方解石颗粒较大,颗粒黏结程度降低,导致岩石抗压强度和杨氏模量减小;砂屑-生屑灰岩部分方解石颗粒呈次圆状或圆状,颗粒三维空间球度较大,颗粒之间咬合作用减弱,使得岩石的抗压强度和杨氏模量减小;砂屑-生屑灰岩存在大量的孔隙和裂缝,灰岩易沿着潜在的微裂缝面或者颗粒接触面摩擦滑动甚至破裂,同样导致岩石抗压强度和杨氏模量减小。此外,一间房组—鹰山组泥晶灰岩受热液作用影响,部分白云石交代为石英,导致泥晶灰岩的抗压强度和杨氏模量增加。岩石的宏观力学特征和岩石力学参数受岩石微观颗粒结构的制约,一间房组—鹰山组杨氏模量、抗压强度和最大水平主应力低值区即为顺北4号带优势储层发育区带。

纳米Fe_(3)O_(4)/超支化水性聚氨酯的制备及性能研究

采用γ-甲基丙烯酰氧基丙基三甲氧基硅烷(KH570)对纳米Fe_(3)O_(4)表面改性并将其引入经亲水改性的含不饱和双键的端羟基超支化聚酯(BoltornTMH_(2)0)中,加入光引发剂后经紫外光照射得到Fe_(3)O_(4)复合超支化水性聚氨酯(Fe_(3)O_(4)/WHBPU)固化膜,采用红外光谱(FTIR)、X-射线衍射(XRD)对其结构进行表征分析,利用振动样品磁强计(VEM)和万能试验机对其磁性能和机械性能进行测试。结果表明,Fe_(3)O_(4)/WHBPUA具有良好的超顺磁性,其硬度、抗拉强度、断裂伸长率和杨氏模量分别为3H、31.88MPa、91.51%、335.78MPa,相较于未引入Fe_(3)O_(4)粒子的WHBPU提升了约100%。

CDK4/6抑制剂在HR^(+)晚期乳腺癌治疗中的耐药机制及进展后治疗策略

细胞周期蛋白依赖性激酶4/6(CDK4/6)抑制剂联合内分泌治疗已成为激素受体阳性(HR^(+))、人类表皮生长因子受体-2阴性(HER2^(-))乳腺癌患者的晚期一线及二线标准治疗方案。尽管CDK4/6抑制剂可实现有效的疾病控制,但对于晚期乳腺癌患者最终仍会因耐药出现疾病进展。目前CDK4/6抑制剂相关耐药机制尚不完全清楚,同时治疗失败后的最佳治疗策略仍是一个亟待解决的问题。本文就CDK4/6抑制剂的潜在耐药机制和后续治疗策略的最新研究进展做一综述。

Wear behavior and mechanism of B_4C reinforced Mg-matrix composites fabricated by metal-assisted pressureless infiltration technique

The B4C/Mg composites fabricated by metal-assisted pressureless infiltration technique were used as experimental material, and the wear behavior and mechanism of this material were studied. A pin-on-disc apparatus was used to evaluate the wear behavior where loads of 20, 40, 60 and 80 N, and a sliding velocity of 250 r/min were exerted. The results show that B4C/Mg composites possess superior wear resistance than pure Mg under various applied loads, and the content of Ti, as infiltration inducer, has an influence on the wear resistance of B4C/Mg composites. The dominant wear mechanism for pure Mg is abrasion, while that for B4C/Mg composites under low loads is adhesion and delamination. Under high loads, the wear mechanism of B4C/Mg composites can be attributed to thermal softening and melting or plastic deformation.

部分浸泡再生混凝土Mg^(2+)-SO_(4)^(2-)-Cl^(-)复合盐侵蚀耐久性损伤特征与机制

为系统研究与揭示西北地区部分掩埋再生混凝土(RAC)结构耐久性损伤特征与机制,以浓度为20%的复合盐溶液为侵蚀介质,开展了14种掺辅助胶凝材料RAC部分浸泡于复合盐溶液的耐久性试验,综合分析RAC动弹性模量、宏观与微观形貌、侵蚀产物物相组成与相对含量的经时变化规律。部分浸泡RAC沿纵向高度分为饱和区、气-液两相界面区、水分传输区及干燥区。侵蚀初期气-液两相界面区损伤程度高于饱和区;侵蚀中后期饱和区的损伤持平或超过气-液两相界面区,水分传输区损伤初现。饱和区侵蚀状态由初期的化学侵蚀转变为中后期的化学-物理双重侵蚀,气-液两相界面区在侵蚀期间均呈现出化学-物理双重侵蚀。化学侵蚀产物为水镁石、硬石膏/石膏、钙矾石、Friedel盐及碱式氯化镁;物理结晶盐包含氯镁石、白钠镁矾、氯化钠、水合硫酸镁、Na_(2)SO_(4)及芒硝,各侵蚀产物与结晶盐的相对含量均随浸泡时间延长而改变。侵蚀后期,Na_(2)SO_(4)和芒硝相互转化使RAC物理力学性能急速退化。粉煤灰-矿渣复掺RAC抗侵蚀性能整体较好,粉煤灰-硅灰复掺最差,后者在浸泡时间180 d时抗压强度损失率高于60%。矿渣-硅灰-偏高岭土三掺RAC耐久性显著高于粉煤灰-矿渣-偏高岭土三掺,后者在侵蚀180 d时已经溃散。四掺辅助胶凝材料RAC性能衰减速度均匀,但抗侵蚀性能仍处于较低水平,相同浸泡时间下,其耐久性指标均与粉煤灰-矿渣复掺RAC差距较大。

气道压力释放通气通过调控ITGB4相关通路减轻ARDS肺部炎症的机制研究

目的分析气道压力释放通气(APRV)和小潮气量通气(LTV)对急性呼吸窘迫综合征(ARDS)炎症的影响,探讨不同机械通气模式对ARDS机械应力相关的作用及机制。方法构建巴马小型成年猪重度ARDS模型,应用LTV与APRV通气模式,进行48 h机械通气治疗,分为空白对照组(control组,n=3)、疾病对照组(ARDS组,n=3)、LTV机械通气组(LTV组,n=4)以及APRV机械通气组(APRV组,n=4)。观察两种通气模式对氧合指数、炎症因子的影响。对肺组织进行高通量测序,并在蛋白层面验证差异基因ITGB4对ARDS机械通气后炎症的影响。使用A549细胞系构建APRV样牵张模型及LTV样牵张模型,进行4 h体外牵张实验,探讨两种牵张模式通过ITGB4对细胞炎症因子分泌的影响。使用小干扰RNA(siRNA)沉默ITGB4表达,比较LTV+siRNA组与APRV+siRNA组ITGB4-FAK-p38-MAPK-IL-8通路表达差异。使用p38抑制剂(SB203580)对细胞进行干预,比较LTV+SB203580组和APRV+SB203580组IL-8表达水平的差异。结果重度ARDS造模成功后,通气48 h,APRV组肺泡灌洗液及肺组织中IL-6、IL-8水平显著低于LTV组(P<0.05),而两组IL-1、TNF-α差异无统计学意义(P>0.05)。转录组高通量测序结果显示,机械通气后细胞外基质受体交互通路及黏着斑信号通路显著富集。在肺组织中,APRV组ITGB4、p-FAK、p-p38蛋白表达水平显著低于LTV组(P<0.05)。细胞牵张模型在体外细胞中复现LTV与APRV样牵张,周期性牵张4 h使细胞IL-8水平显著升高(P<0.05),IL-6水平无明显变化(P>0.05)。APRV组的IL-8、ITGB4、p-FAK和p-p38表达水平显著低于LTV组(P<0.05)。沉默ITGB4可以显著下调机械牵张后APRV组与LTV组p-FAK、p-p38的表达水平,APRV+siRNA组下调趋势明显,但相较LTV+siRNA组差异无统计学意义(P>0.05)。使用p38抑制剂后,相较于LTV+SB203580组,APRV+SB203580组p-p38磷酸化水平显著下调(P=0.032)。结论APRV机械通气模式通过ITGB4-p38-MAPK通路显著改善重度ARDS后炎症因子IL-8的分泌,可能为ARDS治疗提供潜在的干预靶点。

Mechanism of action of Zhuyu Annao pill in mice with cerebral intrahemorrhage based on TLR4

Objective:To explore the protective effect and possible mechanism of action of Zhuyu Annao pill in mice with intracerebral hemorrhage(ICH).Methods:Sixty mice were divided into the control group,hemorrhage group,drug-treated group(after hemorrhage),TLR4-knockout hemorrhage group and TLR4-knockout hemorrhage + drug-treated group(after hemorrhage) with 12 in each group.Model of autologous ICH was established in all groups.After drilling and 12 h of fasting,models in the control group hemorrhage group and TLR4-knockout hemorrhage group were all drenched with 10 mL/kg distilled water by intragastric administration.Models in the drug-treated group and TLR4-knockout hemorrhage + drugtreated group were drenched with 6.25 g/kg of Zhuyu Annao pill.All groups were treated for 7 d.Longa scoring method was used to measure the neurological defect scores and determine the brain water contents of all groups;ELISA was employed to detect the inflammatory factor interleukin(IL)-6,tumor necrosis factor- α(TNF- α) and IL-1β in brain tissues;and Western blot was applied to test the expression quantities of apoptotic protein Bax and anti-apoptotic protein Bcl-2 in brain tissues.Results:At day 3 and7,compared with the hemorrhage group,the neurological defect scores of the drug-treated group,TLR4-knockout hemorrhage group and TLR4-knockout hemorrhage + drug-treated group decreased significantly(P<0.05) Compared with the hemorrhage group,the brain water contents of the drug-treated group,TLR4-knockout hemorrhage group and TLR4-knockout hemorrhage + drug-treated group reduced significantly(P<0.05) Compared with the hemorrhage group,the inflammatory factor IL-6,TNF-α and IL-1β of the drug-treated group,TLR4-knockout hemorrhage group and TLR4-knockout hemorrhage + drug-treated group decreased significantly(P<0.05).Compared with the hemorrhage group,the expression of apoptotic protein Bax of the drug-treated group,TLR4-knockout hemorrhage group and TLR4-knockout hemorrhage+ drug-treated group decreased significantly and the expression of anti-apoptotic protein Bcl-2 increased significantly(P<0.05).Conclusions:Zhuyu Annao pill can alleviateencephaledema for mice with ICH and reduce inflammatory responsesandnerve cell apoptosis.TLR4 can mediate inflammatory injury induced by ICH.Thus,Zhuyu Annao pill can play a protective role for brains by decreasing the expression of TLR4.

溶剂热法合成NiFe_(2)O_(4)纳米颗粒及其光催化降解亚甲基蓝实验

本文以3种溶剂合成了不同形貌特征的尖晶石型NiFe_(2)O_(4)纳米颗粒,并利用紫外-可见分光光度计测试了其对工业标准染料亚甲基蓝(MB)的降解效率。结果表明,使用乙二醇为溶剂合成的NiFe_(2)O_(4)纳米颗粒,催化剂用量为4g·L^(-1)、亚甲基蓝初始浓度为20mg·L^(-1)、pH值为2~4、温度为50℃、H_(2)O_(2)投加量为20mL·L^(-1),在紫外光源照射60min左右时,超过95.4%的亚甲基蓝染料被降解。表征结果表明,使用乙二醇为溶剂合成的NiFe_(2)O_(4)有着轮廓清晰的纺锤体性质,伴随着多孔性以及高透明度,可以有效地对紫外光进行吸收,更快地形成电子-空穴对,对亚甲基蓝进行分解。通过自由基淬灭实验对制备的NiFe_(2)O_(4)纳米粒子的光催化机理进行了研究,并通过重复循环实验研究了制备的NiFe_(2)O_(4)纳米粒子的稳定性。

金属有机框架衍生的Co_(3)O_(4)/SnO_(2)复合材料制备及其光催化性能

金属有机框架(metal-organic framework,MOF)材料ZIF-67衍生Co_(3)O_(4)十二面体纳米块在室温下与SnO_(2)复合,制备出立方体Co_(3)O_(4)/SnO_(2)复合光催化剂.煅烧后形成的Co_(3)O_(4)/SnO_(2)材料禁带宽度明显降低,荧光淬灭明显,说明Co_(3)O_(4)的加入拓展了SnO_(2)的光响应范围至可见光甚至红外光区域,同时促进了光催化反应过程中光生载流子的分离.以罗丹明B(Rhodamine B,Rh B)为目标反应物,在可见光下考察了MOF衍生的Co_(3)O_(4)/SnO_(2)的光催化降解活性,发现Co_(3)O_(4)/SnO_(2)在60 min内可以降解89.6%的Rh B,分别是纯SnO_(2)和纯ZIF-67的4.5倍和3倍.同时,Co_(3)O_(4)/SnO_(2)表现出了良好的光反应能力和稳定性.基于以上实验结果并结合自由基淬灭实验,提出了MOF衍生的Co_(3)O_(4)/SnO_(2)复合材料光催化降解有机染料RhB的机理.