基于转录组学研究鳖血柴胡治疗肝阴虚证的作用机制

目的:研究鳖血柴胡对肝阴虚证的治疗作用及机制。方法:将36只雄性SD大鼠随机分为空白组、模型组、阳性药组、柴胡组、鳖甲-柴胡组、鳖血柴胡组,每组6只。采用腹腔注射CCl4联合灌胃温热中药的方法建立肝阴虚证模型。通过检测肝功能指标、阴虚指标及炎症因子指标,观察肝脏HE染色切片,评价鳖血柴胡对肝阴虚证的治疗作用。并通过转录组测序技术探究鳖血柴胡治疗肝阴虚证的作用机制,采用实时荧光定量PCR(qRT-PCR)验证转录组测序结果的准确性。结果:与模型组比较,柴胡组、鳖甲-柴胡组及鳖血柴胡组均可显著降低血清中肝功能指标天门冬氨酸氨基转移酶(AST)、丙氨酸氨基转移酶(ALT)、总胆红素(TBIL)水平(P<0.01);降低环磷酸腺苷(cAMP)、环磷酸腺苷与环磷酸鸟苷比值(cAMP/cGMP)、三碘甲状腺原氨酸(T3)、甲状腺素(T4)水平(P<0.01);降低促炎细胞因子肿瘤坏死因子-α(TNF-α)、白细胞介素-6(IL-6)表达,促进抗炎细胞因子白细胞介素-10(IL-10)表达(P<0.01)。转录组测序结果显示,鳖血柴胡通过调控687个基因起到治疗肝阴虚证的作用。KEGG通路富集结果显示,差异基因显著富集在补体与凝血级联反应通路,PPI分析得到的10个hub基因中,有5个都显著富集于此通路。结论:柴胡经鳖血炮制后劫肝阴之性减弱,可用于肝阴虚证的治疗。其机制是通过调控补体与凝血反应通路,调节免疫反应与炎症反应,进而起到治疗肝阴虚证的作用。

二氧化碳捕集与地热发电全链能流分析

以CO_(2)为工质的增强型地热发电系统(CO_(2)-EGS)拓展了CO_(2)封存汇的种类,同时其从干热岩中获得的热量还可补充因捕集、输运和封存消耗的能量,有效提高了项目的经济性。但多大程度上可填补CO_(2)捕集及输运的能耗是该技术规模化应用与发展过程中亟需解决的关键问题之一。为此,通过对CO_(2)捕集电站与地热发电全链系统的解构和耦合,在降低了全链系统某些参数的敏感性基础上,编制了全链优化软件。然后以某超临界燃煤电站为参考电站(热效率设为42.30%,净功为590.8 MW),对4种捕集方法(燃烧后捕集、加压富氧燃烧、化学链燃烧、分级气化)对应的全链系统进行了能流分析。结果表明:①对于中等温度的热储,化学链燃烧和分级气化法与CO_(2)-EGS结合后,全链系统的净输出可超过无CO_(2)捕集的参考电站,即CO_(2)-EGS的输出功可以弥补因捕集和输运造成的能量损失;②对于高温热储,CO_(2)-EGS的净输出可补偿加压富氧、化学链和分级气化法捕集和输运能耗。最后,基于全链能量梯级利用理念,结合CO_(2)膨胀发电的特点,提出了热量反哺的全链能量优化利用方法。结论认为:①全链能耗的主要差异体现在捕集过程,具体数值可达到数量级的差别;②压缩和输运及CO_(2)-EGS的单位能耗差异因捕集气的组分差异导致,数值上相差不大;③热量反哺理念显示了基于全链系统的能量优化利用优势,使系统的能量分配得到了优化,燃烧后捕集和分级气化两种捕集方案的指标得以提高。

基于低场核磁共振的煤粉动态吸附测量

煤层气的开发是我国非常规天然气开发的重要环节,与常规天然气不同的是煤层气中甲烷主要以吸附形式赋存在煤的一系列纳米孔中。甲烷在煤粉颗粒孔隙中吸附行为的动态过程对煤层气的开发具有重要意义。实现了一种基于低场核磁共振技术在线测量煤粉吸附特性的实验方法,通过横向驰豫分布区别孔隙中含氢流体分布,定量表征游离气和吸附气含量。结果表明煤粉颗粒的甲烷吸附在核磁共振的横向弛豫图谱中呈现多峰分布,其中弛豫时间在0.1~1 ms的峰包含了纳米孔隙中甲烷含气量的信息。随着时间增加,甲烷气体逐渐转换为吸附态。通过不同压力下核磁共振的横向弛豫图谱,定量分析了甲烷在颗粒样品中随时间和压力变化的动态吸附过程,并得到了等温吸附曲线且符合Langmuir拟合模型。

Effect of reactive surface area of minerals on mineralization trapping of CO_2 in saline aquifers

The reactive surface area, an important parameter controlling mineral reactions, affects the amount of mineralization trapping of CO2 which affects the long-term CO2 storage. The effect of the reactive surface area on the mineralization trapping of CO2 was numerically simulated for CO2 storage in saline aquifers. Three kinds of minerals, including anorthite, calcite and kaolinite, are involved in the mineral reactions. This paper models the relationship between the specific surface area and the grain diameter of anorthite based on experimental data from literature （Brantley and Mellott, 2000）. When the reactive surface areas of anorthite and calcite decrease from 838 to 83.8 m^2/m^3, the percentage of mineralization trapping of CO： after 500 years decreases from 11.8% to 0.65%. The amount of dissolved anorthite and the amounts of precipitated kaolinite and calcite decrease significantly when the reactive surface areas ofanorthite and calcite decrease from 838 to 83.8 m2/m3. Calcite is initially dissolved in the brine and then precipitates during the geochemical reactions between CO2-H20 and the minerals. Different reactive surface areas of anorthite and calcite lead to different times from dissolution to precipitation. The pH of the brine decreases with decreasing reactive surface areas of anorthite and calcite which influences the acidity of the saline aquifer. The gas saturation between the upper and lower parts of the saline aquifer increases with decreasing reactive surface areas of anorthite and calcite. The mass density distribution of brine solution shows that the CO2^＋brine solution region increases with decreasing reactive surface areas ofanorthite and calcite.

Multi-objective Optimization of Geothermal Extraction from the Enhanced Geothermal System in Qiabuqia Geothermal Field, Gonghe Basin

A geothermal demonstration exploitation area will be established in the Enhanced Geothermal System of the Qiabuqia field, Gonghe Basin, Qinghai–Xizang Plateau in China. Selection of operational parameters for geothermal field extraction is thus of great significance to realize the best production performance. A novel integrated method of finite element and multi-objective optimization has been employed to obtain the optimal scheme for thermal extraction from the Gonghe Basin. A thermal-hydraulic-mechanical coupling model(THM) is established to analyze the thermal performance. From this it has been found that there exists a contraction among different heat extraction indexes. Parametric study indicates that injection mass rate(Q_(in)) is the most sensitive parameter to the heat extraction, followed by well spacing(WS) and injection temperature(T_(in)). The least sensitive parameter is production pressure(p_(out)). The optimal combination of operational parameters acquired is such that(T_(in), p_(out), Q_(in), WS) equals(72.72°C, 30.56 MPa, 18.32 kg/s, 327.82 m). Results indicate that the maximum electrical power is 1.41 MW for the optimal case over 20 years. The thermal break has been relieved and the pressure difference reduced by 8 MPa compared with the base case. The optimal case would extract 50% more energy than that of a previous case and the outcome will provide a remarkable reference for the construction of Gonghe project.

用于粪便样本的A组轮状病毒RT-PCR快速检测方法的建立及应用

目的建立用于粪便样本A组轮状病毒(RVA)的实时荧光RT-PCR(RT-PCR)快速检测方法并探究其应用价值。方法收集2016年8月至2018年12月本院门诊儿科及住院部儿科稀便及水样便标本200例轮状病毒胶体金阳性标本为研究对象,采用实时荧光RT-PCR检测样本RVA,分析其灵敏度、特异性及精密度,并与胶体金免疫层析、试剂盒检测方法进行对比研究。结果本研究一步法实时荧光RT-PCR检测RVA灵敏度高,与种属相近病毒无交叉反应;不同浓度RVA上清样本Ct值标准差在0.17~0.42范围内,变异系数(CV)在0.49%~1.87%范围内;与胶体金免疫层析方法对比,阳性符合率为91.03%、阴性符合率为90.98%,总符合率为91.00%,Kappa值为0.813,与上海之江RVA检测试剂盒检测结果对比,阳性符合率为100%,阴性符合率为97.41%,总符合率99.5%,Kappa值为0.969。结论本研究建立的一步法实时荧光RT-PCR具有灵敏度、特异性、精密度高,简单快速,通用性好等特点,对临床RVA引起的小儿腹泻快速诊断有一定应用价值。

基于人文理念的细节化护理对重症肺炎患者肺功能与不良事件风险的影响

目的探讨基于人文理念的细节化护理对重症肺炎患者肺功能与不良事件风险的影响。方法80例重症肺炎患者随机分为两组,对照组给予常规护理,观察组给予基于人文理念的细节化护理,比较两组的临床症状恢复时间、肺功能与不良事件。结果观察组的喘息消退时间、退热时间、肺部湿啰音消退时间均短于对照组(P<0.05)。护理后,观察组的FVC、FEV_(1)、FEV_(1)/FVC均高于对照组(P<0.05)。观察组的不良事件发生率低于对照组(P<0.05)。结论基于人文理念的细节化护理可缩短重症肺炎患者的临床症状恢复时间,改善肺功能,降低不良事件风险。

短跑竞赛服涡流发生器气动减阻性能评价的数值模拟研究

目的研究前向楔形涡流发生器周向分布角度对圆柱减阻效果的影响,为设计短跑运动员减阻竞赛服提供理论依据。方法根据NIKE公司Aero Blade减阻贴片构建出前向楔形涡流发生器。基于运动员肢体可简化为不同直径圆柱开展竞赛服减阻研究的假设,将48个前向楔形涡流发生器均匀分布为4列,在圆柱迎风面两侧关于YOZ平面对称均匀粘贴。采用多面体网格离散光滑和表面修饰圆柱的计算域,大涡模拟空气以短跑运动员平均跑动速度32 km/h流过圆柱时的阻力和流场变化、压强分布。结果两列涡流发生器以10°或15°间隔周向布置在55°~75°范围内时减阻效果较好,主要通过改变圆柱背风区的压强分布以降低其所受压差阻力实现,其减阻机制是流体吹过圆柱表面的前向楔形涡流发生器后在其下游产生微涡,加速尾迹区流动向临界流动转捩,从而有效降低圆柱所受的阻力。结论以合适周向角度布置的前向楔形涡流发生器可以有效降低圆柱所受的空气阻力。研究结果可用于指导风洞试验和短跑减阻竞赛服设计。

航天飞行器热防护相变发汗冷却研究进展

随着航天飞行器飞行速度与时间的提高,气动、燃烧等带来的超高温、大热流使得飞行器部件温度远超材料耐温极限,高效可靠的热防护技术成为制约航天飞行器发展的重要瓶颈之一。发汗冷却技术自20世纪40年代提出以来,被认为是一种具有极高冷却效率的主动热防护技术,可实现航天飞行器超高温/大热流表面的有效热防护。该文对国际、国内主要研究团队和作者研究团队近年来相变发汗冷却的研究进行了综述,阐述了亚声速和超声速主流中相变发汗冷却流动与换热规律,提出了仿生自抽吸自适应相变发汗冷却方法及其优化结构,给出了发汗冷却在航天飞行器典型热端结构中的应用和优化方法。结合先进材料的发展探索非均匀热流、过载等条件下相变发汗冷却的流动换热规律是未来相变发汗冷却发展的重要方向,从而为航天飞行器跨越式发展提供可靠的技术支持。

高超声速飞行器发动机热防护与发电一体化系统

在对高超声速飞行器的热防护和机载设备电能需求的综合考虑下,立足发动机能量管理优化,结合CO_(2)的物性特点,提出了以超临界CO_(2)为循环工质的高效热防护与高温发电一体化系统。此一体化方案可以在实现发动机热防护的同时,提供电能、并减少冷却用燃油流量。基于燃油为该一体化系统的唯一热沉,通过理论分析和计算,提出了两个一体化系统,通过对一体化系统的优化分析,给出了提高一体化系统性能的措施:尽量提高燃油在CO_(2)冷却器中被加热的终态温度以及采用回热来提高CO_(2)闭式布雷顿循环的性能,该系统的热效率可达到17%。相对于采用蓄电池和燃料电池为机载设备供电的方案,当飞行器飞行时间为30 min,该一体化系统的净增质量分别降低85%和68%,体积分别降低81%和59%。

二氧化碳地质封存与增产油/气/热利用技术中关键热质传递问题研究进展

碳捕集、利用与封存技术(carbon capture,utilization and storage,CCUS)是指将CO_(2)从能源利用、工业生产或大气中分离出来,经过提纯运送到可利用或封存场地,以实现被捕集的CO_(2)与大气长期分离的技术。联合国政府间气候变化专门委员会(IPCC)近期在报告中指出:CCUS技术是碳减排与碳中和的“foundation”技术。在我国碳达峰碳中和的“双碳”目标大背景下,CCUS技术被认为是我国实现碳中和目标不可或缺的关键性技术之一。该文对国际、国内主要研究团队和作者研究团队近年来在CO_(2)地质封存、增产致密油/页岩气/深层地热开采过程中的关键热质传递问题研究进行了综述,通过理论分析,利用分子动力学、格子Boltzmann、计算流体力学等模拟方法,和微观孔隙尺度可视化实验、岩心尺度核磁共振实验、超临界压力流体对流换热实验等实验手段,从不同尺度阐述了储层条件下超临界CO_(2)在微纳多孔结构中多相多组分流动与热质传递机理,分析了矿物反应、降压析出、流体变物性、尺度效应等对CO_(2)地质封存和驱油、驱气、采热过程中的影响规律,从而为CO_(2)地质封存和利用的应用提供理论和技术支撑。

木香有效活性成分调节多信号通路抗恶性肿瘤的研究进展

恶性肿瘤也称为癌症,是一种细胞异常增殖并且能够侵犯周围组织或扩散到其他部位的疾病。该疾病是肿瘤细胞失去了对正常生长和分化的控制,导致它们不受限制地增殖。近年来,木香有效活性成分木香烃内酯、去氢木香内酯、环氧木香内酯治疗恶性肿瘤已有诸多报道,通过查阅国内外对恶性肿瘤机制的研究发现,多个信号通路参与恶性肿瘤的发病与发展,包括磷脂酰肌醇3激酶-蛋白激酶B、蛋白激酶B-哺乳动物雷帕霉素靶蛋白-信号转导与转录激活因子3、核因子κB、肿瘤蛋白p53、酪氨酸激酶-信号转导和转录激活因子、c-Jun氨基末端激酶等信号通路,涉及细胞的生存、生长、增殖与凋亡等。现从木香治疗恶性肿瘤的信号通路进行论述,阐明当前治疗恶性肿瘤的核心靶点,梳理木香有效活性成分与各个信号通路之间的作用联系,为后续中药木香治疗恶性肿瘤的研究提供理论支撑。

超临界压力CO2竖直管内传热恶化抑制实验

为抑制浮升力导致的超临界压力流体传热恶化,该文采用光管内插螺旋结构,增强管内湍流发展,提高流体管内换热性能。对超临界压力CO2在竖直光管、内插螺旋管内对流换热进行了实验研究,比较了热流密度、进口Re、流动方向等因素对换热的影响,讨论了内插螺旋结构对传热恶化现象的抑制作用。研究结果表明:由于浮升力传热恶化作用,流体在光管内向上流动壁温分布呈非线性变化趋势,壁温峰值区域随热流密度升高逐渐向入口区域移动;光管内插入螺旋结构可以有效抑制由浮升力产生的传热恶化作用,显著提高超临界压力CO2管内对流换热强度,内插螺旋结构管相对于光管可以提高对流换热系数约200%以上;超临界压力CO2在内插螺旋结构管内流动与换热时,在热流密度较高情况下,浮升力依然会对换热起到一定的恶化作用,流体向下流动时沿程对流换热系数略高于向上流动。

Theoretical and experimental study of the thermal conductivity of nanoporous media

The nanoparticle thermal conductivity and nanoscale thermal contact resistance were investigated by molecular dynamics(MD) simulations to further understand nanoscale porous media thermal conductivity.Macroscale porous media thermal conductivity models were then revised for nanoporous media.The effective thermal conductivities of two packed beds with nanoscale nickel particles and a packed bed with microscale nickel particles were then measured using the Hot Disk.The measured results show that the nano/microscale porous media thermal conductivities were much less than the thermal conductivities of the solid particles.Comparison of the measured and calculated results shows that the revised combined parallel-series model and the revised Hsu-Cheng model can accurately predict the effective thermal conductivities of micro-and nanoparticle packed beds.

Internal heat transfer coefficients in microporous media with rarefaction effects

The internal heat transfer of different gases in microporous media was investigated experimentally and numerically.The experimental test section had a sintered bronze porous media with average particle diameters from 11 μm to 225 μm.The Knudsen numbers at the average inlet and outlet pressures of each test section varied from 0.0006 to 0.13 with porosities from 0.16 to 0.38.The particle-to-fluid heat transfer coefficients of air,CO 2 and helium in the microporous media were determined experimentally.The results show that the Nusselt numbers for the internal heat transfer in the microporous media decrease with decreasing the particle diameter,d p,and increasing Knudsen number for the same Reynolds number.For Kn>0.01,the rarefaction affects the internal heat transfer in the microporous media.A Nusselt number correlation was developed that includes the influence of rarefaction.The computational fluid dynamics(CFD) numerical simulation was carried out to do the pore scale simulation of internal heat transfer in the microporous media considering the rarefaction effect.Pore scale three-dimensional numerical simulations were also used to predict the particle-to-fluid heat transfer coefficients.The numerical results without slip-flow and temperature jump effects for Kn<0.01 corresponded well with the experimental data.The numerical results with slip-flow and temperature jump effects for 0.01<Kn<0.13 are lower than the numerical results without rarefaction effects,but closer to the experimental data.The numerical results with rarefaction effects can accurately simulate the unsteady heat transfer in the microporous media.