中药在痛风疾病中的应用及其作用机制研究进展

痛风是仅次于糖尿病的第2大代谢类疾病,在全球范围内发病率较高,痛风作为一种常见且复杂的关节炎类疾病,如果不及时得到治疗,将会损伤关节,严重时还会发生肾结石甚至是肾衰竭,危及生命。虽然西药在治疗痛风领域中也取得了显著的成果,但是西药在治疗痛风时常常伴随胃肠道反应、肝脏损伤等不良反应,且在停药后易复发,使得根治痛风成为一个难题。我国传统中药应用于痛风已有较为悠久的历史,中药具有多成分多靶点的特点,不仅能通过抑制尿酸产生相关酶的活性而降低尿酸(UA)生成,亦能通过促进尿酸排泄而降低尿酸,除降尿酸作用外大部分应用于痛风邻域的中药还能有效缓解关节炎症;中药药性温和,在发挥痛风治疗作用时不良反应的发生率明显低于西药,部分中药甚至能够在发挥作用的同时对肾脏具有保护作用,所以中药有望解决根治痛风这一难题。近年来,国内外对应用于痛风邻域的中药进行了大量研究,通过对近10年中药在痛风疾病中的应用研究进行总结,并对作用机制和物质基础进行归纳分析,以期能够为中药防治痛风相关研究提供参考。     

提升“湘九味”品牌价值 高质量发展湖南中药材产业

湖南省历经8年聚力打造“湘九味”中药材品牌，已逐渐形成品牌品种引领的产业链发展模式。为达成湖南省中药材产业链千亿发展目标，梳理了“湘九味”品牌培育历程，厘清并阐释了相关概念，分析了产业发展现状及问题，研判了大健康应用背景下未来的中药材产业的发展趋势，并提出相关发展建议。     

Structural Response Prediction of Thin-Walled Additively Manufactured Parts Considering Orthotropy,Thickness Dependency and Scatter

Besides the design freedom offered by additive manufacturing, another asset lies within its potential to accelerate product development processes by rapid fabrication of functional prototypes. The premise to fully exploit this benefit for lightweight design is the accurate structural response prediction prior to part production. However, the peculiar material behavior, characterized by anisotropy, thickness dependency and scatter, still constitutes a major challenge. Hence, a modeling approach for finite element analysis that accounts for this inhomogeneous behavior is developed by example of laser-sintered short-fiber-reinforced polyamide 12. Orthotropic and thickness-dependent Young’s moduli and Poisson’s ratios were determined via quasi-static tensile tests. Thereof, material models were generated and implemented in a property mapping routine for finite element models. Additionally, a framework for stochastic finite element analysis was set up for the consideration of scatter in material properties. For validation, thin-walled parts on sub-component level were fabricated and tested in quasi-static three-point bending experiments. Elastic parameters showed considerable anisotropy, thickness dependency and scatter. A comparison of the predicted forces with experimentally evaluated reaction forces disclosed substantially improved accuracy when utilizing the novel inhomogeneous approach instead of conventional homogeneous approaches. Furthermore, the variability observed in the structural response of loaded parts could be reproduced by the stochastic simulations.     

A Computational Geometry Generation Method for Creating 3D Printed Composites and Porous Structures

A computational method for generating porous materials and composite structures was developed and implemented. The method is based on using 3D Voronoi cells to partition a defined space into segments. The topology of the segments can be controlled by controlling the Voronoi cell set. The geometries can be realized by additive manufacturing methods, and materials can be assigned to each segment. The geometries are generated and processed virtually. The macroscopic mechanical properties of the resulting structures can be tuned by controlling microstructural features. The method is implemented in generating porous and composite structures using polymer filaments i.e., polylactic acid (PLA), thermoplastic polyurethane (TPU) and nylon. The geometries are realized using commercially available double nozzle fusion deposition modelling (FDM) equipment. The compressive properties of the generated porous and composite configurations are tested quasi statically. The structures are either porous of a single material or composites of two materials that are geometrically intertwined. The method is used to produce and explore promising material combinations that could otherwise be difficult to mix. It is potentially applicable with a variety of additive manufacturing methods, size scales, and materials for a range of potential applications.     

Change in Pull-Out Force during Resorption of Magnesium Compression Screws for Osteosynthesis of Mandibular Condylar Fractures

Background: Magnesium has been used as degradable fixation material for osteosynthesis, but it seems that mechanical strength is still a current issue in these fixations. The aim of this study was to evaluate the axial pull-out force of compression headless screws made of magnesium alloy during their resorption. Methods: The tests included screws made for osteosynthesis of the mandible head: 2.2 mm diameter magnesium alloy MgYREZr (42 screws) and 2.5 mm diameter polylactic-co-glycolic acid (PLGA) (42 pieces, control). The screws were resorbed in Sørensen’s buffer for 2, 4, 8, 12, and 16 weeks, and force was measured as the screw was pulled out from the polyurethane block. Results: The force needed to pull the screw out was significantly higher for MgYREZr screws than for PLGA ones (p < 0.01). Within eight weeks, the pull-out force for MgYREZr significantly decreased to one third of its initial value (p < 0.01). The dynamics of this decrease were greater than those of the pull-out force for PLGA screws (p < 0.05). After these eight weeks, the values for metal and polymer screws equalized. It seems that the described reduction of force requires taking into account when using magnesium screws. This will provide more stable resorbable metallic osteosynthesis.     

Numerical Study on the Dependency of Microstructure Morphologies of Pulsed Laser Deposited TiN Thin Films and the Strain Heterogeneities during Mechanical Testing

Numerical study of the influence of pulsed laser deposited TiN thin films’ microstructure morphologies on strain heterogeneities during loading was the goal of this research. The investigation was based on the digital material representation (DMR) concept applied to replicate an investigated thin film’s microstructure morphology. The physically based pulsed laser deposited model was implemented to recreate characteristic features of a thin film microstructure. The kinetic Monte Carlo (kMC) approach was the basis of the model in the first part of the work. The developed kMC algorithm was used to generate thin film’s three-dimensional representation with its columnar morphology. Such a digital model was then validated with the experimental data from metallographic analysis of laboratory deposited TiN(100)/Si. In the second part of the research, the kMC generated DMR model of thin film was incorporated into the finite element (FE) simulation. The 3D film’s morphology was discretized with conforming finite element mesh, and then incorporated as a microscale model into the macroscale finite element simulation of nanoindentation test. Such a multiscale model was finally used to evaluate the development of local deformation heterogeneities associated with the underlying microstructure morphology. In this part, the capabilities of the proposed approach were clearly highlighted.     

可吸收明胶海绵棒在椎弓根内止血的应用

[目的]观察评价可吸收明胶海绵棒在椎弓根置钉过程中的止血效果。[方法]2017年10月~2018年6月,48例胸腰椎骨折即将行后路手术的患者纳入本研究,采用随机数字表法分为明胶海绵组和骨蜡组。明胶海绵组共23例,置钉过程中应用明胶海绵棒填塞至椎弓根孔道止血;骨蜡组共25例,在透视定位时应用骨蜡封闭椎弓根孔道。记录置钉情况;记录术中出血量、自体血回输量、置钉过程中的出血量、输血量;检测术前和术后5 d RBC、HB和HCT。[结果]两组在置钉总数、伤椎置钉数、伤椎位置各椎置钉数量的差异均无统计学意义(P>0.05)。术后两组各出现1例小腿肌间静脉血栓,抗凝治疗后于复查时消失。术后两组均无明胶海绵或骨蜡导致的不良反应。两组在术中出血量、术中自体血回收量、输血量的差异无统计学意义(P>0.05),但明胶海绵组上述指标均小于骨蜡组。每钉置入过程中明胶海绵组的出血量显著少于骨蜡组,差异有统计学意义(P<0.05)。两组术后5 d的RBC、HB和HCT均较术前显著减少,两时间点间差异均有统计学意义(P<0.05)。术前两组在RBC、HB和HCT的差异均无统计学意义(P>0.05),术后5 d两组在RBC、HB和HCT的差异亦均无统计学意义(P>0.05)。[结论]应用明胶海绵棒填塞椎弓根孔道止血可显著减少安置椎弓根螺钉过程中的出血,是一种简单、安全、有效的脊柱外科术中止血方法。     

Generation of nanovesicles with sliced cellular membrane fragments for exogenous material delivery

We propose a microfluidic system that generates nanovesicles (NVs) by slicing living cell membrane with microfabricated 500 nm-thick silicon nitride (Si_xN_y) blades. Living cells were sliced by the blades while flowing through microchannels lined with the blades. Plasma membrane fragments sliced from the cells self-assembled into spherical NVs of ∼100–300 nm in diameter. During self-assembly, the plasma membrane fragments enveloped exogenous materials (here, polystyrene latex beads) from the buffer solution. About 30% of beads were encapsulated in NVs, and the generated NVs delivered the encapsulated beads across the plasma membrane of recipient cells, but bare beads could not penetrate the plasma membrane of recipient cells. This result implicates that the NVs generated using the method in this study can encapsulate and deliver exogenous materials to recipient cells, whereas exosomes secreted by cells can deliver only endogenous cellular materials.     

Orthogonally oriented scaffolds with aligned fibers for engineering intestinal smooth muscle

Controlling cellular alignment is critical in engineering intestines with desired structure and function. Although previous studies have examined the directional alignment of cells on the surface (x–y plane) of parallel fibers, quantitative analysis of the cellular alignment inside implanted scaffolds with oriented fibers has not been reported. This study examined the cellular alignment in the x–z and y–z planes of scaffolds made with two layers of orthogonally oriented fibers. The cellular orientation inside implanted scaffolds was evaluated with immunofluorescence. Quantitative analysis of coherency between cell orientation and fiber direction confirmed that cells aligned along the fibers not only on the surface (x–y plane) but also inside the scaffolds (x–z & y–z planes). Our study demonstrated that two layers of orthogonally aligned scaffolds can generate the histological organization of cells similar to that of intestinal circular and longitudinal smooth muscle.