同一消解液同时测定中成药中砷汞铅铜含量的研究

以新癀片为对象采用同一的微波、酸消解法，用还原气化冷原子荧光法测汞；用氢化发生-电感耦合等离子体原子发射光谱法测砷；用石墨炉原子吸收法测铅和铜。并用加际消化和国家标准物质的测定，证明方法准确可靠。     

Kubicek每搏心输出量计算公式的三维有限元仿真研究

我们从 Kubicek模型三维有限元仿真的角度对 Kubicek每搏心输出量计算公式的临床应用价值进行了研究。在计算机仿真研究中 ,我们对比了模型仿真结果、具体采用 Kubicek每搏心输出量计算公式所得结果以及所设模型的理论计算结果。仿真结果表明 :模型中阻抗改变与主动脉中血液容积改变之间存在着近似的线性关系 ,证明了 Kubicek每搏心输出量计算公式具有一定的临床应用价值 ,同时也为心阻抗血流图基础理论提供了新的研究途径。     

Finite-element models of the human head

A review is presented of the existing finite-element (FE) models for the biomechanics of human head injury. Finite element analysis can be an important tool in describing the injury biomechanics of the human head. Complex geometric and material properties pose challenges to FE modelling. Various assumptions and simplifications are made in model development that require experimental validation. More recent models incorporate anatomic details with higher precision. The cervical vertebral column and spinal cord are included. Model results have been more qualitative than quantitative owing to the lack of adequate experimental validation. Advances include transient stress distribution in the brain tissue, frequency responses, effects of boundary conditions, pressure release mechanism of the foramen magnum and the spinal cord, verification of rotation and cavitation theories of brain injury, and protective effects of helmets. These theoretical results provide a basic understanding of the internal biomechanical responses of the head under various dynamic loading conditions. Basic experimental research is still needed to determine more accurate material properties and injury tolerance criteria, so that FE models can fully exercise their analytical and predictive power for the study and prevention of human head injury.     

Evolution of Vertebroplasty: A Biomechanical Perspective

This paper is a collection of computational, finite element studies on vertebroplasty performed in our laboratory, which attempts to provide new biomechanical evidence and a fresh perspective into how the procedure can be implemented more effectively toward the goal of preventing osteoporosis-related fractures. The percutaneous application of a bone cement to vertebral defects associated with osteoporotic vertebral compression fracture has proven clinical successful in alleviating back pain. When the biomechanical efficacy of the procedure was examined, however, vertebroplasty was found to be limited in its ability to provide sufficient augmentation to prevent further fractures without risking complications arising from cement extravasations. The procedure may instead be more efficient biomechanically as a prophylactic treatment, to mechanically reinforce osteoporotic vertebrae at risk for fracture. Patient selection for such intervention may be reliably achieved with the more accurate fracture risk assessments based on vertebral strength, predicted using geometrically detailed, specimen-specific finite element models, rather than on bone density alone. Optimal cement volume, placement, and material properties were also recommended. The future of vertebroplasty involving biodegradable augmentation material laced with osteogenic agents that upon release will stimulate new bone growth and increase bone mass was proposed.     

Effect of Enamel Prism Decussation and Chemical Composition on the Biomechanical Behavior of Dental Tissue: A Theoretical Approach to Determine the Loading Conditions to Which Modern Human Teeth are Adapted

This theoretical study explored whether the directions of loads to which modern human molars are commonly subjected to are reflected in the biomechanical behavior of the tissue itself. A detailed finite element model of a piece of decussating enamel (M³ paracone) was created, taking into account differences in crystal orientation between the prism head and the interprismatic matrix, and was tested under differently angled mediolateral loads (i.e., mimicking various stages of the chewing cycle). Second, although teeth are highly mineralized, they also contain organic material and water, while in modern humans, there are systematic differences in chemical composition from the outer enamel surface to the dentinoenamel junction. To test the biomechanical effects of this gradient in mineralization a second set of models with gradually changing properties was created and subjected to the same loads. Chemically heterogeneous enamel yielded overall lower stress levels than homogenous enamel, especially at extreme loading angles. However, the general trends regarding the increase in tensile stresses at more oblique angles, and the number of nodes exhibiting tension, were comparable between the different set‐ups. The findings support suggestions that (a) the biomechanical behavior of dental tissue is the combined result of micromorphology and chemical composition and (b) that the range of loading directions, to which teeth are normally subjected to, can be inferred from dental microanatomy. For (palaeo)biological applications, the findings suggest that the absolute strength of teeth (e.g., bite force) cannot be predicted with certainty, whereas kinematic parameters of the masticatory apparatus can. Anat Rec, 2007. © 2008 Wiley‐Liss, Inc.     

枢椎齿突骨折的有限元分析

目的：建立枢椎的三维有限元(FE)模型，探讨在前、后方不同载荷下齿突的不同损伤机制和骨折类型。方法：对一例新鲜枢椎标本进行CT扫描，层厚1mm，扫描图像转换后输入微机，通过软件PRO／E重建枢椎的三维立体模型，再转入有限元软件MARK并赋予此模型物理材料属性，然后模拟齿突骨折的受力条件，在齿突中性矢状面对齿突施加不同角度的载荷，分析各种条件下枢椎模型的应力、应变分布，探讨相应条件下可能导致的枢椎齿突骨折类型。结果：(1)对于齿突前部斜向后下方载荷，应力集中区从齿突前上部斜贯穿至后下部；对于齿突前部斜向后上方载荷，应力集中区从齿突前下部斜贯穿至后上部；齿突腰部始终保持高应力；(2)在齿突后部载荷下，其应力集中情况与前部载荷相似，不过应力集中区位置有所偏下。结论：(1)在齿突中性矢状面，齿突前部载荷容易导致齿突腰部发生断裂，形成枢椎齿突Ⅱ型骨折，也可能导致基底部发生断裂，形成枢椎齿突Ⅲ型骨折；(2)齿突后部载荷更容易导致基底部发生断裂，形成枢椎齿突Ⅲ型骨折。     

股骨颈骨折空心钉内固定手术参数的优化分析

闭合复位空心钉内固定手术是目前治疗股骨颈骨折的常用方法,采用有限元方法对空心钉内固定手术进行力学综合分析,根据股骨近端力学实验的结果,建立股骨近端有限元分析模型,对可能影响手术效果的患者体重、骨折线角度、空心钉布局与角度等几个参数进行分组分析,提取骨折面、钉子的应力应变分析结果,获得了216组不同手术参数组合的情况下,影响术后愈合与承载能力的骨折端面的错位位移、钉孔底部应变、钉子最大应力、股骨最大应变四个参数,并进行综合分析比较,找到一组符合生物力学规律的内固定治疗参数,并应用于医疗机器人手术参数规划及手术效果的评价系统。     

Elastohydrodynamic separation of pleural surfaces during breathing

To examine effects of lung motion on the separation of pleural surfaces during breathing, we modeled the pleural space in two dimensions as a thin layer of fluid separating a stationary elastic solid and a sliding flat solid surface. The undeformed elastic solid contained a series of bumps, to represent tissue surface features, introducing unevenness in fluid layer thickness. We computed the extent of deformation of the solid as a function of sliding velocity, solid elastic modulus, and bump geometry (wavelength and amplitude). For physiological values of the parameters, significant deformation occurs (i.e. bumps are 'flattened') promoting less variation in fluid thickness and decreased fluid shear stress. In addition, deformation is persistent; bumps of sufficient wavelength, once deformed, require a recovery time longer than a typical breath-to-breath interval to return near their undeformed configuration. These results suggest that in the pleural space during normal breathing, separation of pleural surfaces is promoted by the reciprocating sliding of lung and chest wall.     

Three-dimensional finite element analysis of the stress of the patellofemoral joint after medial patellofemoral ligament reconstruction by different femoral reconstruction insertion points北大核心

BACKGROUND: There are many ways to reconstruct the patellofemoral ligament. Among them, the lateral insertion of the femur has a greater influence. At present, there are many ways to select femoral insertion points, but there are no conclusions. OBJECTIVE: Through the analysis of three-dimensional finite element software, the change of femoral reconstruction insertion position of medial patellofemoral ligament under different flexion states can analyze the stress of the patellofemoral joint to select a suitable femoral reconstruction insertion. METHODS: CT data of normal knee joints of adults were obtained to import Mimics, Geomagic and Soildworks software to extract molds and add ligaments. The femoral insertion points of the ligament were the midpoint between the medial epicondyle and the adductor tubercle, the medial epicondyle, the adductor tubercle, the projection point from the top of the femoral intercondylar fossa to the medial condyle and 10 mm below the adductor tubercle. The mold added with ligament was imported into the mechanical software Ansys to analyze the stress of patellofemoral joint after reconstruction of different femoral insertion points using finite element analysis. RESULTS AND CONCLUSION: (1) When the knee flexion was 0° and 30°, the stress of patellofemoral joint at any femoral insertion point of reconstructed medial patellofemoral ligament was greater than that at other angles (60°, 90°, and 120°). No matter which position was used as the femoral insertion point, when the knee joint was flexed more than 30°, there was basically no difference in the contact stress between the patellofemoral joints. (2) At 0° and 30° of knee flexion, the patellofemoral contact pressure was the largest at the point of the adductor tubercle, and the contact force at the midpoint between the medial epicondyle and the adductor tubercle was the smallest. When the knee was flexed 30°, the midpoint between the medial epicondyle and the adductor tubercle, the projection point from the top of the femoral intercondylar fossa to the medial condyle, and 10 mm below the adductor tubercle as the insertion point showed no significant difference in the contact stress. (3) Results indicate that when reconstructing medial patellofemoral ligament, the best choice of femoral lateral insertion point is the midpoint between the medial epicondyle and the adductor tubercle. This point can effectively restore the stability of knee joint and delay the degeneration of joint and cartilage. © 2023, Publishing House of Chinese Journal of Tissue Engineering Research. All rights reserved.     

Development of a non-linear finite element modelling of the below-knee prosthetic socket interface

A non-linear finite element model has been established to predict the pressure and shear stress distribution at the limb-socket interface in below-knee amputees with consideration of the skin-liner interface friction and slip. In this model, the limb tissue and socket liner were respectively meshed into 954 and 450 three-dimensional eight-node isoparametric brick elements, based on measurements of an individual's amputated limb surface; the bone was meshed into three-dimensional six-node triangular prism elements, based on radiographic measurements of the individual's residual limb. The socket shell was assumed to be a rigid boundary. An important feature of this model is the use of 450 interface elements (ABAQUS INTER4) which mimic the interface friction condition. The results indicate that a maximum pressure of 226 kPa, shear stress of 53 kPa and less than 4 mm slip exist at the skin-liner interface when the full body weight of 800 N is applied to the limb. The results also show that the coefficient of friction is a very sensitive parameter in determining the interface pressures, shear stresses and slip. With the growth of coefficient of friction, the shear stresses will increase, while the pressure and slip will decrease.