Effect of Exogenous Hydrogen Sulfide(H_2S) on the Electrocardiogram(ECG) of Rats Generally Anaesthetized by Zoletil

Hydrogen sulfide （H2S） is the third gaseous signaling molecule discovered in recent years, and plays an important physiological role in the cardivascular system. To explore the effects of different doses of exogenous H2S on the electrocardiogram （ECG） of rats generally anesthetized by zoletil, different doses of NariS solution were used for the intervention of intraperitoneal injection 20 rain before the zoletil anesthesia. The ECGs of rats from each treatment group during the time range of 10^th-50^th min were determined under general anesthesia, and then were compared with those from the control group. The results showed that exogenous H2S could significantly reduce the Q-T interval time limit, thus played a role in slowing tachycardia or arrhythmia and other anomalies, thereby protecting the heart. S-T segment and T segment evaluation values were significantly reduced, which might be associated with bradycardia.

Hydrogen sulfide protects against amyloid beta-peptide induced neuronal injury via attenuating inflammatory responses in a rat model

Neuroinflammation has been recognized to play a critical role in the pathogenesis of Alzheimer＇s disease （AD）, which is pathologically characterized by the accumulation of senile plaques containing activated microglia and amyloid β-peptides （Aβ）. In the present study, we examined the neuroprotective effects of hydrogen sulfide （H2S） on neuroinflammation in rats with Aβ1-40 hippocampal injection. We found that Aβ-induced rats exhibited a disorder of pyramidal cell layer arrangement, and a decrease of mean pyramidal cell number in the CA1 hippocampal region compared with those in sham operated rats. NaHS （a donor of H2S, 5.6 mg/kg/d, i.p.） treatment for 3 weeks rescued neuronal cell death significantly. Moreover, we found that H2S dramatically suppressed the release of TNF-α, IL-1β and IL-6 in the hippocampus. Consistently, both immunohistochemistry and Western blotting assays showed that H2S inhibited the upregulation of COX-2 and the activation of NF-κB in the hippocampus. In conclusion, our data indicate that H2S suppresses neuroinflammation via inhibition of the NF-κB activation pathway in the Aβ-induced rat model and has potential value for AD therapy.

Establishment of mitral regurgitation swine model and study the change of hydrogen sulfide system

Objective To establish the mitral regurgitation swine model and study the change of hydrogen sulfide(H2S)system in chronic heart failure model.Methods Miniature pigs were randomly divided into two groups,the control group(n=6)and mitral regurgitation group(n=6).Chronic heart failure models were established by pulling mitral chordal through a small incision extracorporeal.

基于炉膛水冷壁H_(2)S气氛场实时测量的锅炉运行监测与优化研究

为揭示锅炉水冷壁H_(2)S在不同负荷时的浓度分布、H_(2)S与炉膛组分CO和SO_(2)的关系、结焦区域H_(2)S分布情况以及运行调整对H_(2)S和NO_(x)的影响情况,指导锅炉运行,在某300 MW等级电站锅炉上安装了水冷壁气氛在线监测装置,系统研究了炉内近壁面H_(2)S、CO等还原性组分的生成规律及运行调整对炉内氛围的影响。结果表明:(1)在高负荷时炉内H_(2)S、CO整体浓度较高,并且负荷越高,腐蚀倾向越严重。(2)负荷在由高向低下降的过程中,存在一临界负荷(40%BMCR),当降至此临界负荷时,壁面气氛由还原性气氛开始转化为氧化性气氛。该炉易发生高温腐蚀的负荷范围为60%~100%。(3)总体上壁面H_(2)S与CO表现出正相关性,而H_(2)S与SO_(2)呈负相关性,但同时壁面各组分间又呈现出一定的独立性。(4)结焦区域H_(2)S平均浓度比非结焦区域高出537×10^(-6)(体积分数,下同),这与结焦区域水冷壁相较于非结焦区域水冷壁腐蚀更严重的现象一致。(5)关闭燃尽风投运层数、增加运行氧量,可以显著降低H_(2)S浓度,最高降幅可达91.4%,但H_(2)S浓度降低会引起NO_(x)增加,关一层燃尽风,NO_(x)平均上涨109 mg/m^(3)。建议在实际运行中,需要平衡好这对矛盾。

高热惊厥患儿外周血NLR和H_(2)S水平变化及与脑损伤的相关性

目的探讨高热惊厥患儿外周血中性粒细胞/淋巴细胞比值(NLR)和硫化氢(H_(2)S)水平变化及与脑损伤的相关性。方法选取2021年1月至2023年1月期间本院收治的高热惊厥患儿共220例,其中单纯性153例纳入单纯性组,复杂性67例纳入复杂性组,同期选取高热无惊厥患儿109例纳入对照组。所有患儿均检测外周血NLR和H_(2)S水平,采用受试者工作特征(ROC)曲线鉴别单纯性及复杂性高热惊厥患儿。根据高热惊厥患儿有无脑损伤发生情况分为脑损伤组及无脑损伤组,收集两组高热惊厥患儿临床资料,采用多因素Logistic回归模型分析影响高热惊厥患儿脑损伤的独立危险因素。结果与对照组比较,单纯性组及复杂性组外周血NLR水平升高,H_(2)S水平降低(P<0.05),与单纯性组比较,复杂性组外周血NLR水平升高,H_(2)S水平降低(P<0.05)。ROC分析结果显示,外周血NLR、H_(2)S单独检测及二者联合检测鉴别单纯性及复杂性高热惊厥患儿的AUC值(95%CI)分别为0.615(0.547~0.680)、0.731(0.667~0.788)、0.827(0.771~0.875),NLR、H_(2)S联合检测的预测效能高于单独检测(Z=4.488、2.161,P<0.05)。脑损伤组惊厥时体温≥40℃、复杂性高热惊厥、惊厥发作次数≥2次、惊厥持续时间≥15 min例数占比、外周血NLR水平均高于无脑损伤组,H_(2)S水平低于无脑损伤组(P<0.05)。多因素Logistic回归模型分析结果显示,复杂性高热惊厥、惊厥发作次数≥2次,惊厥持续时间≥15 min、外周血NLR高水平及H_(2)S低水平是影响高热惊厥患儿发生脑损伤的独立危险因素(P<0.05)。结论高热惊厥患儿外周血NLR水平升高,H_(2)S水平降低,外周血NLR、H_(2)S水平对于高热惊厥患儿分型具有重要的鉴别价值,且与高热惊厥患儿脑损伤的发生密切相关。

Effect of H_2S on the transformation of 1-hexene over NiMoS/γ-Al_2O_3 with hydrogen

The effect of H2S contents on the transformation of 1-hexene with hydrogen over NiMoS/γ-Al2O3 catalyst was investigated.Inhibition of H2S on both hydrogenation and isomerization reactions of olefin has been demonstrated.And the promotion effect of H2S on the formation of C6 thiols and C12 thioethers has also been observed.It was found out that there was only one type of active site on the NiMoS/γ-Al2O3 for reactions which include hydrogenation reaction,isomerization reaction and sulfides formation reaction,and the formation reactions of sulfides were superior to both hydrogenation and isomerization reactions.The reaction network for the conversion of 1-hexene in the presence of H2S was proposed.

Zinc Oxide Nanostructure Thick Films as H₂S Gas Sensors at Room Temperature

The ZnO nanostructures have been synthesized and studied as the sensing element for the detection of H2S. The ZnO nanostructures were synthesized by hydrothermal method followed by sonication for different interval of time i.e. 30, 60, 90 and 120 min. By using screen printing method, thick films of synthesized ZnO nanostructure were deposited on glass substrate. Gas sensing properties of ZnO nanostructure thick films were studied for low concentration H2S gas at room temperature. The effects of morphology of synthesized ZnO nanostructure on gas sensing properties were studied and discussed. ZnO nanostructure synthesized by this method can be used as a promising material for semiconductor gas sensor to detect poisonous gas like H2S at room temperature with high sensitivity and selectivity.

Analysis of H_2S Tolerance of Pd-Cu Alloy Hydrogen Separation Membranes

The presence of a limited amount of H2S in H2-rich feed adversely affects the Pd-Cu membrane permeation performance due to the sulphidization of the membrane surface. A theoretical model was proposed to predict the S-tolerant performance of the Pd-Cu membranes in presence of H2S under the industrial water-gas-shift(WGS) reaction conditions. The ideas of surface coverage and competitive adsorption thermodynamics of H2S and H2 on Pd-Cu surface were introduced in the model. The surface sulphidization of the Pd-Cu membranes mainly depended on the pressure ratio of H2S to H2, temperature and S-adsorbed surface coverage, i.e., the occurrence of sulphidization on the surface was not directly related with the bulk compositions and structures [body centered cubic and face centered cubic(bcc or fcc)] of Pd-Cu alloy membranes because of the surface segregation phenomena. The resulting equilibrium equations for the H2S adsorption/sulphidization reactions were solved to calculate the pressure ratio of H2S to H2 over a wide range of temperatures. A validation of the model was performed through a comparison between lots of literature data and the model calculations over a rather broad range of operating conditions. An extremely good agreement was obtained in the different cases, and thus, the model can serve to guide the development of S-resistant Pd alloy membrane materials for hydrogen separation.

Hydrogen Permeation Behaviors of X52 Pipeline Steel in NACE A Solution with Saturated H_2S/CO_2

With the aid of hydrogen permeating devices, the hydrogen permeation behaviors of X52 pipeline steel in NACE A solution with saturated H2S/CO2 were studied under the conditions of different ambient temperatures and pH values, and the hydrogen permeation behaviors of X52 pipeline steel in weld seam zone were comparatively studied. The experimental results show that the hydrogen permeation coefficient value is directly proportional to the time required for reaching the saturation anode current and inversely proportional to the saturation anode current, and the hydrogen permeation coefficient is influenced by the corrosion scales; the temperature is directly proportional to the saturation anode current, and the hydrogen permeation coefficient is influenced by the temperature and corrosion scales, heat-affected zone and matrix zone in NACE A solution with saturated H2S/CO2 at normal temperature. The hydrogen permeation coefficient in weld seam zone is larger than that in heat-affected zone which is further larger than that in matrix zone.

H_2S Gas Sensor Based on Nanocrystalline ZnO Synthesized by Electrochemical-Deposition

ZnO nanocrystals were prepared by a direct current electrochemical deposition process under 3.0V working voltage and 30A/m^2 current density using zinc sulfate as raw materials.The nanocrystals were characterized by X-ray diffraction (XRD)and transmission electron microscopy(TEM).The results indicated that the nanocrystals are hexagonal wurtzite ZnO with particle size range of 25nm～40nm without any treating.Gas sensing properties of the sensors were tested by mixing a gas in air at static state;the tested results showed that the sensors based on nanocrystalline ZnO had satisfied gas sensing properties to H_2S gas at rather low temperature.

Structural Characterization of Nanocrystalline La_1-xSr_xCrO₃Thick Films for H₂S Gas Sensors

The nanocrystalline of La1-xSrxCrO3 (x = 0.0, 0.1, 0.2, 0.3 & 0.4) were prepared by sol-gel method and their crystal structures & morphology were characterized by X-ray diffraction (XRD) and Transmission Electron Microscopy (TEM). XRD patterns indicate that the average particle size of the nanocrystalline La0.7Sr0.3CrO3in the range of 30 - 35 nm. The gas sensing properties were studied towards reducing gases like Ammonia gas (NH3), liquefied petroleum gas (LPG), hydrogen sulphide (H2S) and H2 gas and it is observed that undoped LaCrO3 shows response to H2S gas at relatively high operating temperature 300°C. The La1-xSrxCrO3 based sensor with x = 0.3 shows better sensitivity towards H2S gas at an operating temperature 210°C. The effect of Sr doping on sensitivity, response time and recovery time of the sensor in the presence of H2S and other reducing gases were studied and discussed.

Simulation of CO₂and H₂S Removal Using Methanol in Hollow Fiber Membrane Gas Absorber (HFMGA)

Application of methanol solvent for physical absorption of CO2 and H2S from CO2/H2S/CH4 mixture in gas–liquid hollow fiber membrane gas absorber (HFMGA) was investigated. A computational mass transfer (CMT) model for simulation of HFMGA in the case of simultaneous separation of CO2 and H2S was developed. The membrane gas absorber model explicitly calculates for the rates of mass transfer through the membrane and components concentration profiles. Due to the lack of experimental data in the literature, the model was validated using available individual components’ water absorption data. The numerical predictions were in good agreement with the experimental data. The effects of operating conditions such as liquid velocity, gas velocity, temperature and pressure were analyzed. It is shown that methanol solvent can successfully be used for CO2 and H2S removal in membrane gas absorber. Also it is found that the concentration distribution of CO2 and H2S in the gas phase along the fiber length obeys plug flow model whereas in the methanol absorbent deeply affected by the interface concentration, absorbent velocity and diffusivity. In addition, it is shown that application of membrane gas absorber using methanol absorbents for H2S removal and at higher flow rate is more efficient. Moreover, at operating pressures above 10 atm even at low absorbent rate, H2S concentration depletion is relatively complete while at 1 atm this value is about 30%. This means that removal efficiency decreases with an increase in temperature and it is more important especially for H2S.

芳氢与配位硫原子之间(sp^2C—H…S)的分子内氢键

化合物（Ｅｔ４Ｎ）２［Ｐｄ２（ｍｐ）２（Ｈｍｐ）２］（１）（Ｈ２ｍｐ＝２－巯基苯酚）的１ＨＮＭＲ谱中芳氢Ｈ１６的峰出现在δ８．７９处，与预测值（δ７．１）相差１．７，这是由于Ｈ１６与配位硫Ｓ２原子之间存在弱相互作用，即新型的ｓｐ２Ｃ—Ｈ…Ｓ之间的氢键作用．原子间距离Ｃ１６…Ｓ２（０．３６１ｐｍ）和Ｈ１６…Ｓ２（０．２９５ｐｍ）分别小于相应原子的范德华半径之和（０．３７０ｐｍ和０．３０５ｐｍ），Ｃ１６—Ｈ１６…Ｓ２角为１２８．１°，证明了这种新型氢键的存在．此外，在分子振动光谱中观察到这种氢键的作用使得芳氢νＣ—Ｈ出现在低于３０００ｃｍ－１处．通过与类似物［Ｐｄ２（ＰＰｈ３）２（Ｈｍｐ）２Ｃｌ２］（２）的比较，以及１在ＤＭＳＯ溶剂中仍然保持Ｏ—Ｈ…Ｏ和Ｃ—Ｈ…Ｓ这２种氢键的事实，表明Ｃ—Ｈ…Ｓ之间的作用，对１的配体Ｈｍｐ中的苯环与Ｐｄ２Ｓ２平面之间的夹角偏离９０°可能是有贡献的．

弱碱性阴离子交换纤维吸附H_2S和CO_2混合气体的研究

主要研究了弱碱性阴离子交换纤维对高浓度的 H2 S、CO2 混合气体的吸附性能 ,考察了各种因素对吸附的影响规律 ,为今后进一步的深入研究打下了一定的基础。

内源性H_(2)S、TAT、sPECAM-1对老年髋部骨折围术期下肢深静脉血栓形成的预测价值研究

目的探讨内源性硫化氢(endogenous hydrogen sulfidem,H_(2)S)、血浆凝血酶-抗凝血酶复合物(thrombin/antithrombin complex,TAT)及可溶性血小板内皮细胞黏附分子-1(soluble platelet endothelial cell adhesion molecule 1,sPECAM-1)对老年髋部骨折围术期下肢深静脉血栓形成(deep vein thrombosis,DVT)的预测价值。方法选取2018年11月至2019年7月北京积水潭医院急诊科住院接受手术治疗的新发老年髋部骨折患者187例,随机抽取120例患者(建模集),采用多因素logistic回归方程分析建模集患者DVT的影响因素,并建立预测模型;将剩余67例患者纳入验证集,进行预测模型的内部验证。结果建模集120例患者中男39例(32.50%),女81例(67.50%);平均年龄(78.6±7.1)岁;BMI为(22.5±4.2)kg/m^(2)。多因素logisitic回归分析显示,BMI、发病至就诊的时间及TAT越高,H_(2)S及sPECAM-1越低的患者,越容易发生DVT(P<0.05)。建立的DVT风险预测模型为:logit(P)=0.130×BMI+0.010×发病至就诊的时间-0.098×H_(2)S+0.039×TAT-0.322×sPECAM-1-3.581。预测模型的ROC曲线的AUC为0.844(95%CI:0.774~0.915,P=0.000)。应用验证集数据对模型进行内部验证结果显示验证模型的ROC曲线的AUC为0.816(95%CI:0.713~0.919,P=0.000)。结论基于BMI、受伤至入院时间、TAT、H_(2)S和sPECAM-1等因素建立的模型对于预测老年髋部骨折患者围术期DVT的发生具有良好的筛查能力。

H_(2)S暴露对保育猪氧化还原状态及硫化氢代谢的影响

本试验旨在研究硫化氢(H_(2)S)暴露对保育猪氧化还原状态及内源性H_(2)S代谢的影响。试验选取12头体况健康、体重相近((11.61±1.51)kg)的35日龄大白猪,随机分为2组并分配到2个环控舱内,公母各半,每组6头猪。试验组环控舱内H_(2)S浓度控制为30 mg·m^(-3),对照组环控舱内H_(2)S浓度控制为0 mg·m^(-3),试验期28 d。试验结束后采集血清和肝组织样品,检测氧化还原和H_(2)S代谢相关指标。结果显示,与对照组相比:1)血清中ROS含量极显著增加(P<0.01),MDA含量显著增加(P<0.05);抗氧化酶T-SOD活性显著降低(P<0.05),CAT和GPX活性极显著降低(P<0.01);非酶抗氧化物GSH和GSSG含量无显著变化(P>0.05)。2)肝中T-SOD和GPX活性极显著升高(P<0.01),·OH清除能力显著提高(P<0.05);ROS、H_(2)O_(2)、PC、MDA、GSH、GSSG含量无显著差异(P>0.05)。3)肝中Keap1的mRNA表达量显著下调(P<0.05),Nrf2的mRNA表达量显著上调(P<0.05);抗氧化相关基因(SOD2、GPX1、GPX2、GPX4和GSR)的mRNA表达量显著上调(P<0.05)。4)血清和肝中H_(2)S含量显著降低(P<0.05);肝内源H_(2)S合成酶CSE和CBS的mRNA表达量显著下调(P<0.05),3-MST的mRNA表达量无显著变化(P>0.05);肝H_(2)S分解代谢酶SQR和SUOX的mRNA表达量下调,但差异不显著(P>0.05)。结果表明,30 mg·m^(-3)H_(2)S暴露导致保育猪血清抗氧化系统受损,而肝中Nrf2/Keap1信号通路的激活使肝免受氧化损伤;此外,H_(2)S暴露抑制了保育猪内源性H_(2)S的合成代谢。

Distribution and treatment of harmful gas from heavy oil production in the Liaohe Oilfield, Northeast China

The distribution and treatment of harmful gas （H2S） in the Liaohe Oilfield, Northeast China, were investigated in this study. It was found that abundant toxic gas （H2S） is generated in thermal recovery of heavy oil. The H2S gas is mainly formed during thermochemical sulfate reduction （TSR） occurring in oil reservoirs or the thermal decomposition of sulfocompounds （TDS） in crude oil. H2S generation is controlled by thermal recovery time, temperature and the injected chemical compounds. The quantity of SO4^2- in the injected compounds is the most influencing factor for the rate of TSR reaction. Therefore, for prevention of H2S formation, periodic and effective monitoring should be undertaken and adequate H2S absorbent should also be provided during thermal recovery of heavy oil. The result suggests that great efforts should be made to reduce the SO4^2- source in heavy oil recovery, so as to restrain H2S generation in reservoirs. In situ burning or desulfurizer adsorption are suggested to reduce H2S levels. Prediction and prevention of H2S are important in heavy oil production. This will minimize environmental and human health risks, as well as equipment corrosion.

H_2S Sensing Characteristics of Thin Film SnO_2 Sensor with N_2 Treatment

<正>SnO_2 thin film sensors were fabricated by a thermal evaporation method.The sensors were heated for thermal oxidation.For high porosity,SnO_2 thin film sensors were treated in a N_2 atmosphere.The sensors that were treated with O_2 after being treated with N_2 showed 70 % sensitivity for 1×10~ -6) of H_2S,which is higher than the sensors that were only treated with O_2.The Ni metal,as a catalyst,was evaporated on the thin film Sn on the Al_2O_3 substrate.The sensor was heated to grow the Sn nanowire in a tube furnace with N_2 flow.Sn nanowire was heated for oxidation.The sensitivity of SnO_2 nanowire sensor was measured for 500×10~ -9) of H_2S.The selectivity of the SnO_2 nanowire sensor was compared with the thin film and the thick film SnO_2.Each sensor was measured for H_2S,CO,and NH_3 in this study.

Geochemical characteristics of ultra-deep natural gas in the Sichuan Basin, SW China

The natural gas components and geochemistry of 38 ultra-deep gas wells(burial depth greater than 6 000 m) in the Sichuan Basin were analyzed to determine the genesis of ultra-deep natural gas in the basin. The ultra-deep natural gas components of the basin have the following characteristics: Methane has an absolute advantage, which can be up to 99.56% with an average of 86.6%; ethane is low, with an average of 0.13%; there is nearly no propane and butane. So it is dry gas at over-mature thermal stage. The content of H2 S can be up to 25.21%, with an average of 5.45%. The alkane gas isotopes are: the carbon isotope varies from-32.3‰ to-26.7‰ for methane and from-32.9‰ to-22.1‰ for ethane. There is nearly no carbon isotopic reversal among methane and its homologues. Hydrogen isotope varies from-156‰ to-114‰ for methane, and from-103‰ to-89‰ for some ethane. The carbon isotope of CO_2 varies from-17.2‰ to 1.9‰ and most of them fall within the range of 0±3‰. According to the δ^(13)C_1-δ^(13)C_2-δ^(13)C_3 plot, except some wells, all other ultra-deep gas wells are dominated by coal-derived gas. Based on the CO_2 origin distinguishing plot and δ^(13)C_(CO_2), except some individual wells, most of the ultra-deep CO_2 are of carbonate metamorphic origin. H2 S in the ultra-deep layer of Longgang and Yuanba gas fields belongs to thermochemical sulfate reduction(TSR), while H2 S from Well Shuangtan belongs to thermal decomposition of sulfides(TDS).

外源H_(2)S对番茄双断根嫁接砧木及嫁接苗生长的影响

为筛选出适宜番茄双断根嫁接砧木根系再生及嫁接苗生长的硫化氢(H_(2)S)浓度,以金钻为砧木,以粉都金冠王为接穗,研究不同浓度NaHS(0.1、0.2、0.3、0.4、0.5 mmol·L^(-1),H_(2)S供体)对双断根番茄砧木及嫁接苗生长、根系形态的影响。结果表明,0.2 mmol·L^(-1) NaHS处理的断根番茄砧木株高、茎粗、叶面积、单株鲜质量和干质量、再生根系活力均达到最大值,且显著提高了砧木内源H_(2)S含量及D-半胱氨酸脱巯基酶(DCD)活性;亦显著促进了双断根嫁接苗的生长及根系发育。