局麻下开髓封失活剂250例临床体会

干髓治疗对后牙急性牙髓炎的浆液期、慢性牙髓炎的早期都有较好的疗效。在治疗过程中,放入干髓剂之前应常规进行牙髓的失活处理。对已穿髓的(牙合)面龋封失活剂,失活效果一般都比较好,但是对未穿髓的(牙合)面深龋以及邻面龋、较深的楔状缺损。

活血祛瘀封包联合针灸治疗肩周炎50例

目的:观察活血祛瘀封包联合针灸治疗肩周炎的临床疗效。方法:笔者用活血祛瘀封包联合针灸治疗肩周炎患者50例,与西医止痛对症治疗肩周炎患者50例进行临床对照观察。结果:治疗组的显著好转率及总有效率分别为76.00%、92.00%,明显高于对照组(64.00%、88.00%),两组比较,存在显著性差异(P<0.05),同时两组治疗前后的生存质量也存在显著性差异(P<0.05)。结论:活血祛瘀封包联合针灸对肩周炎患者的治疗临床疗效显著。

封髓失活法治疗急性牙髓炎的效果观察

目的观察开髓引流法治疗急性牙髓炎的效果。方法将260例患者随机分观察组与对照组，对照组用开髓引流法，观察组用封髓失活法。结果治疗24小时后疼痛缓解率观察组为91．5％，对照组为78．4％，观察组明显高于对照组。结论封髓失活法能及时有效缓解急性牙髓炎患者疼痛，值得临床推广。

活血止痛方中药封包外敷配合红光照射治疗盆腔炎的临床效果研究

目的探讨活血止痛方中药封包外敷配合红光照射治疗盆腔炎的临床效果。方法选取南通市通州区中医院2021年12月—2023年7月收治的180例盆腔炎患者为研究对象,按照治疗方案不同将其分为对照组(n=80)和观察组(n=100)。对照组采用妇笑颗粒治疗,观察组在对照组基础上采用活血止痛方中药封包外敷配合红光照射治疗。比较两组治疗效果、疼痛程度和临床各项指标消失时间。结果观察组治疗总有效率为97.00%,高于对照组的88.75%,差异有统计学意义(P<0.05)。治疗后,观察组疼痛视觉模拟评分低于对照组,差异有统计学意义(P<0.05)。观察组下腹坠胀消失时间、腰骶部疼痛消失时间、白带恢复正常时间均短于对照组,组间差异有统计学意义(P<0.05)。结论活血止痛方中药封包外敷配合红光照射治疗盆腔炎效果较为显著,能够缓解疼痛,改善临床各项指标,在临床治疗方案中值得大范围推广与实施。

Multi-enzymes Production Studies in Single Tray Solid State Fermentation with Opened and Closed System

The robustness ofA. awamori and A. oryzae as enzyme producers is exploited in fungal fermentation on agricultural solid waste. High-level production of extracellular glucoamylase, protease, cellulase and xylanase has been achieved. Three different types of ＇waste＇ solids （wheat bran, soybean hulls and rapeseed meal） have been used in studies of solid state fermentation （SSF）. The enzymes could be produced in significant levels by continuously supplying oxygen （02） through the tray system known as ＂closed＂ and ＂opened＂ tray systems. A perforated tray system was developed in this study that permits direct access to 02. Testing the tray system with different perforated mesh aperture sizes in this study did not yield different results in growth performance of A. awamori and A. oryzae. A. awamori and A. oryzae can be very versatile in producing various enzymes with different substrates with different starch, protein, hemiceilulose and cellulose contents. These studies indicate that A. awamori is more suitable for the efficient production of multiple enzymes in the closed system including xylanase and cellulase, while the production of glucoamylase and protease is superior in the opened system. A. oryzae is more suitable for the efficient production of protease and cellulase in the closed system, while the production of protease is more favourable the opened system. A. awamori efficiently consumed starch in wheat bran medium and produced very high glucoamylase activity, and after that, the fungus efficiently produced other enzymes to degrade other complex nutrients such as protein, hemicellulose and cellulose. Meanwhile, A. oryzae efficiently consumed protein in rapeseed meal and produced very high protease activity. The ability of both filamentous fungi, to convert biomass through SSF bioconversion will have a great impact on food and agro-industry in every aspect of life from food and medicine to fuel.

Carbon Sequestration through CO2 Foam-Enhanced Oil Recovery： A Green Chemistry Perspective

Enhanced oil recovery （EOR） via carbon dioxide （CO2） flooding has received a considerable amount of attention as an economically feasible method for carbon sequestration, with many recent studies focus- ing on developing enhanced CO2 foaming additives, However, the potential long-term environmental effects of these additives in the event of leakage are poorly understood and, given the amount of additives injected in a typical CO2 EOR operation, could he far-reaching, This paper presents a summary of recent developments in surfactant and surfactant/nanoparticle-hased CO2 foaming systems, with an emphasis on the possible environmental impacts of CO2 foam leakage, Most of the surfactants studied are unlikely to degrade under reservoir conditions, and their release can cause major negative impacts on wildlife, With recent advances in the use of additives （e,g,, nonionic surfactants, nanoparticles, and other chemicals） the use of harsh anionic surfactants may no longer he warranted, This paper discusses recent advances in producing foaming systems, and highlights possible strategies to develop environmentally friendly CO2 EOR methods,

Evolution of Building Envelopes through Creating Living Characteristics

Building envelopes include facades and roof, which have the most interaction and exchange with outside and natural environment. In the future, meeting buildings various complicated needs with new technological advances necessitates a change and evolution in building envelopes. Controlling the energy consumption of the buildings is mostly through controlling the energy performance of the building envelopes. New technologies lead to the intelligent facades and envelopes. The envelope can be designed to be a part of the whole building＇s metabolism （energy production, storage and consumption） and morphology. The envelope would be a controlled part of the building which is managed through the central control system of the building, which connects it to other parts. It caused building envelope design to be changed fundamentally, so that there is a need to interact with engineering disciplines including computer engineering, mechanical engineering, material engineering and so on. All of these caused building envelope to get closer to biological and living systems. The physical restrictions which affect buildings system and living systems are the same. So they cause the same forces to shape the structure and form of the systems and the same rules to interact with the environment. The restrictions of material and energy resources caused living systems to be energy efficient and consuming less material. But the most important difference between living systems and building systems is in maximum use of different resources. As living systems use information maximally, the building system technology is based on using maximum energy. Now, there are many reasons and restrictions that building envelopes cannot act like living systems. But technological developments and contributing more disciplines in design and construction of building envelopes caused the future way of these envelopes get close to living systems for their energy efficiency. Some of living systems characteristics which the future building envelopes would have partially or benefit for the design process or construction are self-organization, evolution principles, hierarchical levels, processing energy, reaction to environmental stimuli and self-adjustment. Self-organization is achieved in some design software and in building material production for creating formal patterns. Evolution principles provide infrastructure for soft wares for optimization purposes and form creation. Hierarchical levels refer to giving hierarchical structure to the building envelopes through layering and designing different scales. Processing energy （metabolism） would be achieved through photovoltaic and solar collectors to produce energy and in passive systems for energy storage and distribution. Controlling solar radiation absorption and transmittance would help energy transfer from outside to building and vice versa. Reaction to environmental stimuli which is one of the most important characteristics of future building envelopes would use different types of active and passive sensors to create envelope mechanical reactions through material properties or collect data for processing in the control center to determine the right reaction. The reaction would be through different strategies such as changing properties and moving. Reaction could be passive or active. Self-adjustment can be achieved by control systems and processing units. All of these mean intelligent envelopes are essential parts of future buildings. Though it is now started with new design soft wares based on biological principles to optimize different parameters affecting the envelope function or to create the most efficient form.

Highly efficient organic solar cells enabled by a porous ZnO/PEIE electron transport layer with enhanced light trapping

In this study,a porous inorganic/organic(ZnO/PEIE,where PEIE is polyethylenimine ethoxylated)(P-ZnO)hybrid material has been developed and adopted in the inverted organic solar cells(OSCs).The P-ZnO serving as the electron transport layer(ETL)not only presents an ameliorative work function,but also forms the cratered surface with increased ohmic contact area,revealing suppressed charge recombination and enhanced charge extraction in devices.Particularly,P-ZnO-based OSCs show improved light trapping in the active layer compared with ZnO-based ones.The universality of P-ZnO serving as ETL for efficient OSCs is verified on three photovoltaic systems of PBDB-T/DTPPSe-2 F,PM6/Y6,and PTB7-Th/PC_(71)BM.The enhancements of 8%in power conversion efficiency(PCE)can be achieved in the state-of-the-art OSCs based on PBDB-T/DTPPSe-2F,PM6/Y6,and PTB7-Th/PC_(71)BM,delivering PCEs of 14.78%,16.57%,and 9.85%,respectively.Furthermore,a promising PCE of14.13%under air-processed condition can be achieved for PZnO/PBDB-T/DTPPSe-2F-based OSC,which is among the highest efficiencies reported for air-processed OSCs in the literature.And the P-ZnO/PBDB-T/DTPPSe-2F-based device also presents superior long-term storage stability whether in nitrogen or ambient air-condition without encapsulation,which can maintain over 85%of its initial efficiency.Our results demonstrate the great potential of the porous hybrid PZnO as ETL for constructing high-performance and air-stable OSCs.

Fluid dynamic modeling of a free piston engine with labyrinth seals

Preliminary design and simulation of a free piston engine suitable for small-scale energy production in distributed energy systems is presented in this paper.The properties,particularly the properties of gas seals of the engine are simulated using a simulation program developed for this case,and the results are utilized in preliminary main design parameter selection.The engine simulation program was developed by combining and modifying the source codes of the simulation and calculation programs obtained from Helsinki University of Technology,Tampere University of Technology,and Lappeenranta University of Technology.Because of the contact-free labyrinth seal used in the piston,the efficiency of the motor is lower than the efficiency of a conventional motor with oil lubricated piston rings.On the other hand,the lack of bearing losses,and the lack of losses associated with a crankshaft system and a gearbox,as well as the lack of lubrication oil expenses,compensates this effect.As a net result,this new motor would perform slightly better than the conventional one.Being completely oil-free,it is very environmentally friendly,and its exhaust gases are completely free of oil residuals which are causing problems in normal gas motors.