懒猴肩关节的多变量分析

在懒猴与其它灵长类肩关节局部解剖的基础上,对肩关节有关指数的多变量分析结果表明,与骨骼相比,肩关节肌的种间差别明显较大。肩胛盂宽指数、肩胛骨指数和锁肱指数对种的区分有重要意义。懒猴具有类似于叶猴三角肌、大圆肌和喙肱中肌较远的止点及发达的背阔肌和斜方肌颅侧部,增强了肩关节的运动,表现出适应树栖四足运动的特征。而懒猴粗壮的肱骨、较长的锁骨和较长的肱骨,是攀爬型和四足倒挂运动的适应结果。     

女子拳击运动员上肢和腰部肌肉力量训练的肌电分析

目的：利用肌电指标分析拳击运动员上肢和腰部肌肉力量训练效果。方法：用Mega公司的ME6000肌电图仪记录分析10名女子拳击运动员上臂肱二头肌（主动肌）与肱三头肌（拮抗肌）、前臂屈肌（主动肌）与伸肌（拮抗肌）和腰部肌群的运动诱发肌电,规定运动为手持2.5 kg的哑铃负荷进行直拳空击运动直至局部肌肉力竭。结果：直拳空击运动至局部肌肉力竭过程中,上肢拮抗肌的中位频率（MF）下降幅度和速度大于相对应的主动肌,且从肌群作功来看,主动肌作功百分比较拮抗肌大。其中9名普通运动员腰肌的肌电频率（MF）均值较1名指定样本世界冠军的下降缓慢,而且其作功百分比都较小。结论：通过对普通女子拳击运动员上肢和腰部肌群肌电指标测试与世界冠军的比较分析,提示本研究中所测普通拳击运动员拮抗肌和腰部肌肉力量训练不足,有待加强该部肌肉的力量训练。     

成年太行山猕猴肩关节变量的研究

本项研究对成年太行山猕猴桃肩并节变量进行了测量和统计,作了异速生长分析,并对太行山猕猴、滇南猕猴、川西猕猴、湘鄂猕猴肩并关节变量进行了比较和聚类分析,与上述３个亚种相比,太行山猕猴较短的肩胛骨,较小的锁肱指数,较大的三角肌止点指数和较小的摆荡指数,表明太行山猕猴肩关节形态结构更适应于地面上的活动,说明其在地面上活动较多,在树上活动较少。     

四足型灵长类踝关节的生物力学研究

对猕猴属５种踝关节和跟骨生物力学和多变量分析的结构表明,踝关节的运动主要与距骨关节面的形态有关。楔形指数和跟骨指数是区别种间差异的重要指标。结合生态学观察的结果推测,短尾猴和藏酋猴的运动方式最为接近,表现出适应地栖四足型运动的特征,而豚尾猴和熊猴有关对的树栖运动方式,猕猴的运动介于两者之间,既有一定的地栖性运动,也有较大的树栖性运动。     

人猿超科和旧大陆猴7种高等灵长类FKN全基因序列的测定及进化分析

测定人猿超科(人、黑猩猩、大猩猩、红毛猩猩和长臂猿)和旧大陆猴(猕猴和叶猴)7种高等灵长类FKN全基因序列, 探讨其系统进化分析。用简并引物PCR(Degenerated PCR)法分别扩增FKN的3个外显子, 其产物经琼脂糖凝胶回收、纯化后测序, 然后用BioEdit软件剪切拼接FKN基因全序列, 用DNAStar比对后比较基因和氨基酸序列同源性, Mega软件重构FKN基因进化树, 应用Datamonkey分析FKN的负选择位点。序列分析发现人猿超科较旧大陆猴FKN基因除了有散在的点突变外, 还有一明显的30 bp的核苷酸缺失突变; 人FKN基因序列与黑猩猩、大猩猩、红毛猩猩、长臂猿、猕猴和叶猴的同源性分别是99.2%、98.4%、98.1%、96.5%、95.9%和93.8%, 由此推导的氨基酸序列同源性分别是98.5%、98.0%、97.7%、94.7%、93.7%和90.5%; FKN基因进化树表明人与黑猩猩关系更近, FKN基因进化和通常认为的物种进化一致; Datamonkey分析结果显示FKN存在3个负选择位点53Q、84D、239N。成功获得人、黑猩猩、大猩猩、红毛猩猩、长臂猿、猕猴和叶猴7种高等灵长类物种FKN全基因序列, 为后续探讨FKN在高等灵长类物种进化过程中免疫学功能演变及其结构与功能的关系奠定基础。     

小针刀配合中药治疗肱骨外上髁炎的临床观察

肱骨外上髁炎是临床常见病,是一种由前臂伸肌起点,特别是桡侧屈腕短肌的慢性撕裂性病变.2003年以来,我们运用针刀配合中药治疗30例肱骨外上髁炎患者,并与针灸药物、局部封团治疗的患者作对照观察,现报告如下.     

成年太行山猕猴(Macaca mulatta tcheliensis)肩关节变量的研究

本项研究对成年太行山猕猴肩关节变量进行了测量和统计,作了异速生长分析,并对太行山猕猴(M.mulatta tcheliensis)、滇南猕猴(M.mulatta mulatta)、川西猕猴(M.mulatta lasiotis)、湘鄂猕猴(M.mulatta littoralis)肩关节变量进行了比较和聚类分析。与上述3个亚种相比,太行山猕猴较短的肩胛骨、较小的锁肱指数、较大的三角肌止点指数和较小的摆荡指数,表明太行山猕猴肩关节形态结构更适应于地面上的活动,说明其在地面上活动较多,在树上活动较少。     

酢浆草叶片及花朵感夜运动的结构机制

为了解酢浆草(Oxalis corniculata)叶片和花朵的感夜性,采用半薄切片方法对其叶枕和花托进行形态解剖学观察。结果表明,黑暗处理酢浆草后叶片完全闭合,3枚叶片以叶轴为轴线向下紧贴闭合。黑暗处理8 h花瓣完全闭合并螺旋成束状,花萼紧贴螺旋的花瓣但不发生螺旋。叶片张开时屈肌侧皮层薄壁细胞收缩,伸肌侧皮层薄壁细胞膨大。叶片闭合时屈肌侧皮层细胞膨胀,伸肌侧表皮细胞和3～5层外皮层薄壁细胞收缩。花朵闭合时,花托基部的5个维管束收缩合并成2束明显分离的维管束群,且存在细胞壁加厚的现象;花托角隅处细胞膨胀。叶枕中的屈肌和伸肌细胞的收缩或膨胀控制酢浆草叶片的感夜运动,酢浆草花朵的感夜运动主要与花托基部的维管束群和花托角隅处细胞的膨大和收缩有关。     

中国滇、川、湘鄂猕猴(Macaca mulatta)肩胛骨的比较研究

本文是中国滇、川、湘鄂猕猴肩胛骨和肩关节形态结构对环境适应性的比较研究结果。多变量分析结果表明,肩胛冈长、肩峰长、关节盂仰角和三角肌止点对猕猴种下分类有重要作用。川西猕猴较大的体重和体型明显不同于湘鄂(华中)和滇南猕猴,表现出更多的地上四足型运动的适应特征。华中和滇南猕猴具有更相似的肩胛骨形态结构,且有更多的树上活动。     

金丝猴(RHINOPITHECUS)脑的外部形态

本文是对三种金丝猴脑的外部形态的观察结果表明:金丝猴的大脑皮层除存在猴科固有的全部沟裂外,还较其他猴科动物具有更多的副沟。大脑的沟型与疣猴亚科的特征完全吻合,但是很多特点都较叶猴更近似于长臂猿。另外,除了蚓叶和蚓结节较小,四叠体的下丘较猕猴发达以外,金丝猴的小脑和脑干均与猴科的一般特征无明显差异。     

Dependence between the parameters of dynamic and stationary segments of the EMG activity in the elbow joint muscles and the joint angle during realization of targeted movements in cats

In experiments on cats we studied the pattern of EMG activity recorded from the flexors and extensors of the elbow joint and related to realization of flexor targeted operant movements of the forearm. The levels of stationary EMG activity generated by the flexors at a stabilized equilibrium position of the joint demonstrated no correlation with the values of joint angles. We suppose that this feature depends on manifestation of the hysteresis effects of muscle contraction. A target position was attained mostly due to the dynamic phases of muscle activity. The respective patterns of the movement-related activity of synergic muscles significantly differed; separate components related to leaving an equilibrium state with a certain acceleration and attaining a presettled equilibrium joint angle could be differentiated in this activity. Final positions of the forearm could be significantly different at equal levels of the stationary EMG activity generated during stabilization of these positions; they depended on specificities in the time course of dynamic phase of the activity (in particular, on the time of activity decay to a stationary level). We conclude that the movement of a limb link from one equilibrium position to another is mostly controlled via coordination of the dynamic phase of muscle activity.     

Microvascular architecture of the pampiniform plexus-testicular artery system in the rat: a scanning electron microscope study of corrosion casts

Because the architectural and biochemical properties of skeletal muscle dictate its force, velocity, and displacement properties, the major extensors (triceps brachii) and flexors (biceps brachii, brachialis, and brachioradialis) of the elbow in a primate (cynomolgus, monkey) were studied. Functional cross-sectional areas (CSA) were calculated from muscle mass, mean fiber length (normalized to a 2.20 microns sarcomere length), and angle of fiber pinnation measurements from each muscle. Fiber-type distributions were determined and used as a gross index of the biochemical capacities of the muscle. The extensor group had a shorter mean fiber length (31 vs. 47 mm), a larger CSA (13 vs. 8 cm2), and a higher overall percentage of slow-twitch fibers (47 vs. 26%). Consequently, the elbow extensors had a relatively greater potential for force production and force maintenance than the flexors. In contrast, the flexors were designed to optimize their length-velocity potentials; i.e., they had relatively long fibers and a higher fast-twitch fiber composition than the extensors. These morphologic differences between antagonistic muscle groups should be considered when evaluating the motor control mechanisms regulating reciprocal movements about the elbow.     

In vivo assessment of elbow flexor work and activation during stretch-shortening cycle tasks.

The purpose of this study was to use an electromyography (EMG) based muscle model to investigate the performance enhancement of stretch-shortening cycle (SSC) tasks at different elbow flexion-extension velocities. A torque motor was used to oscillate the forearms of seven healthy male subjects (23-40 years) during SSC and non-SSC contractions at four frequencies of movement (.58, 1.5, 2.4 and 3.3Hz) over a range of 105 degrees -162 degrees of elbow extension. The torque was integrated as a function of joint angle to yield the work produced by the elbow flexors. The elbow flexors were transcutaneously stimulated with a voltage equivalent to 60% maximum voluntary isometric contraction torque for 4s at 50Hz. EMG of the elbow flexors and extensors was recorded from the biceps and triceps respectively. The processed EMG was used to drive a Hill based model to predict the torque of the elbow flexors. Results indicate that muscle work increases from non-SSC to SSC trials. Work decreases for SSC and non-SSC trials with increasing velocity. The simulated constant activation muscle model predicted work well for all trials and conditions, indicating muscle model accuracy. The EMG driven model predicted well for all non-SSC trials, but significantly underestimated the work for SSC tasks, suggesting that the contractile component is directly involved in optimising muscle work during SSC tasks.     

Feasibility of using EMG driven neuromusculoskeletal model for prediction of dynamic movement of the elbow.

Neuromusculoskeletal (NMS) modeling is a valuable tool in orthopaedic biomechanics and motor control research. To evaluate the feasibility of using electromyographic (EMG) signals with NMS modeling to estimate individual muscle force during dynamic movement, an EMG driven NMS model of the elbow was developed. The model incorporates dynamical equation of motion of the forearm, musculoskeletal geometry and musculotendon modeling of four prime elbow flexors and three prime elbow extensors. It was first calibrated to two normal subjects by determining the subject-specific musculotendon parameters using computational optimization to minimize the root mean square difference between the predicted and measured maximum isometric flexion and extension torque at nine elbow positions (0-120 degrees of flexion with an increment of 15 degrees ). Once calibrated, the model was used to predict the elbow joint trajectories for three flexion/extension tasks by processing the EMG signals picked up by both surface and fine electrodes using two different EMG-to-activation processing schemes reported in the literature without involving any trajectory fitting procedures. It appeared that both schemes interpreted the EMG somewhat consistently but their prediction accuracy varied among testing protocols. In general, the model succeeded in predicting the elbow flexion trajectory in the moderate loading condition but over-drove the flexion trajectory under unloaded condition. The predicted trajectories of the elbow extension were noted to be continuous but the general shape did not fit very well with the measured one. Estimation of muscle activation based on EMG was believed to be the major source of uncertainty within the EMG driven model. It was especially so apparently when fine wire EMG signal is involved primarily. In spite of such limitation, we demonstrated the potential of using EMG driven neuromusculoskeletal modeling for non-invasive prediction of individual muscle forces during dynamic movement under certain conditions.     

The utility of an empirically derived co-activation ratio for muscle force prediction through optimization

Biomechanical optimization models that apply efficiency-based objective functions often underestimate or negate antagonist co-activation. Co-activation assists movement control, joint stabilization and limb stiffness and should be carefully incorporated into models. The purposes of this study were to mathematically describe co-activation relationships between elbow flexors and extensors during isometric exertions at varying intensity levels and postures, and secondly, to apply these co-activation relationships as constraints in an optimization muscle force prediction model of the elbow and assess changes in predictions made while including these constraints. Sixteen individuals performed 72 isometric exertions while holding a load in their right hand. Surface EMG was recorded from elbow flexors and extensors. A co-activation index provided a relative measure of flexor contribution to total activation about the elbow. Parsimonious models of co-activation during flexion and extension exertions were developed and added as constraints to a muscle force prediction model to enforce co-activation. Three different PCSA data sets were used. Elbow co-activation was sensitive to changes in posture and load. During flexion exertions the elbow flexors were activated about 75% MVC (this amount varied according to elbow angle, shoulder flexion and abduction angles, and load). During extension exertions the elbow flexors were activated about 11% MVC (this amount varied according to elbow angle, shoulder flexion angle and load). The larger PCSA values appeared to be more representative of the subject pool. Inclusion of these co-activation constraints improved the model predictions, bringing them closer to the empirically measured activation levels.     

Control of the Elbow Extensor Muscles in Slow Targeted Extensions of the Arm in Humans

Relations between the kinematic parameters of slow (non-ballistic) targeted extension movements in the elbow joint of humans and characteristics of the movement-related EMG activity in the two heads of the m. triceps brachii were analyzed. Test movements were performed under conditions of application of non-inertional external loadings directed toward flexion. It was shown that the movement-related EMG activity of the elbow extensors, similarly to what was observed in the flexors at flexion movements with the same parameters, demonstrates a complex structure and includes dynamic and stationary phases. In the former phase, in turn, initial and main components can be differentiated. The rising edge and decay of the main component of the dynamic extensor EMG phase could be approximated by exponential functions; this component was never split into a few subcomponents. Dependences between the amplitudes of m. triceps brachii EMG phases and the amplitude of the movement (or external loading) were, as a rule, nonlinear but monotonic. An increase in the test movement velocity led to an increase in the rate of rise of the rising edge of the dynamic EMG phase, while an increment in the amplitude was less significant. Under the used test conditions, the activity of the elbow extensors was usually accompanied by some coactivation of the antagonists (m. biceps brachii). It is concluded that motor commands coming to the elbow extensors at performance of the extension test movements differ from motor commands to the flexors at analogous flexion test movements by a simpler structure and more tonic pattern. Biomechanical specificities of fixation of the mentioned muscle groups to the arm bones (stability of the moment for application of the extensor force under conditions of changing the joint angle vs variable moment of the flexor force) are considered one of the main reasons for such specificity of the patterns of the extensor and flexor motor commands.     

Architectural specialization of the intrinsic thoracic limb musculature of the American badger (Taxidea taxus)

Evaluation of the relationships between muscle structure and digging function in fossorial species is limited. Badgers and other fossorial specialists are expected to have massive forelimb muscles with long fascicles capable of substantial shortening for high power and applying high out‐force to the substrate. To explore this hypothesis, we quantified muscle architecture in the thoracic limb of the American badger (Taxidea taxus) and estimated the force, power, and joint torque of its intrinsic musculature in relation to the use of scratch‐digging behavior. Architectural properties measured were muscle mass, belly length, fascicle length, pennation angle, and physiological cross‐sectional area. Badgers possess hypertrophied shoulder flexors/humeral retractors, elbow extensors, and digital flexors. The triceps brachii is particularly massive and has long fascicles with little pennation, muscle architecture consistent with substantial shortening capability, and high power. A unique feature of badgers is that, in addition to elbow joint extension, two biarticular heads (long and medial) of the triceps are capable of applying high torques to the shoulder joint to facilitate retraction of the forelimb throughout the power stroke. The massive and complex digital flexors show relatively greater pennation and shorter fascicle lengths than the triceps brachii, as well as compartmentalization of muscle heads to accentuate both force production and range of shortening during flexion of the carpus and digits. Muscles of most functional groups exhibit some degree of specialization for high force production and are important for stabilizing the shoulder, elbow, and carpal joints against high limb forces generated during powerful digging motions. Overall, our findings support the hypothesis and indicate that forelimb muscle architecture is consistent with specializations for scratch‐digging. Quantified muscle properties in the American badger serve as a comparator to evaluate the range of diversity in muscle structure and contractile function that exists in mammals specialized for fossorial habits. J. Morphol. 2013. © 2012 Wiley Periodicals, Inc.     

Elbow joint adductor moment arm as an indicator of forelimb posture in extinct quadrupedal tetrapods

Forelimb posture has been a controversial aspect of reconstructing locomotor behaviour in extinct quadrupedal tetrapods. This is partly owing to the qualitative and subjective nature of typical methods, which focus on bony articulations that are often ambiguous and unvalidated postural indicators. Here we outline a new, quantitatively based forelimb posture index that is applicable to a majority of extant tetrapods. By determining the degree of elbow joint adduction/abduction mobility in several tetrapods, the carpal flexor muscles were determined to also play a role as elbow adductors. Such adduction may play a major role during the stance phase in sprawling postures. This role is different from those of upright/sagittal and sloth-like creeping postures, which, respectively, depend more on elbow extensors and flexors. Our measurements of elbow muscle moment arms in 318 extant tetrapod skeletons (Lissamphibia, Synapsida and Reptilia: 33 major clades and 263 genera) revealed that sprawling, sagittal and creeping tetrapods, respectively, emphasize elbow adductor, extensor and flexor muscles. Furthermore, scansorial and non-scansorial taxa, respectively, emphasize flexors and extensors. Thus, forelimb postures of extinct tetrapods can be qualitatively classified based on our quantitative index. Using this method, we find that Triceratops (Ceratopsidae), Anhanguera (Pterosauria) and desmostylian mammals are categorized as upright/sagittally locomoting taxa.     

Effects of two days of isokinetic training on strength and electromyographic amplitude in the agonist and antagonist muscles

The purpose of this study was to examine the effects of 2 days of isokinetic training of the forearm flexors and extensors on strength and electromyographic (EMG) amplitude for the agonist and antagonist muscles. Seventeen men (mean +/- SD age = 21.9 +/- 2.8 years) were randomly assigned to 1 of 2 groups: (a) a training group (TRN; n = 8), or (b) a control group (CTL; n = 9). The subjects in the TRN group were tested for maximal isometric and concentric isokinetic (randomly ordered velocities of 60, 180, and 300 degrees x s(-1)) torque of the dominant forearm flexors and extensors before (pretest) and after (posttest) 2 days of isokinetic strength training. Each training session involved 6 sets of 10 maximal concentric isokinetic muscle actions of the forearm flexors and extensors at a velocity of 180 degrees x s(-1). The subjects in the CTL group were also tested for strength but did not perform any training. Surface EMG signals were detected from the biceps brachii and triceps brachii muscles during the strength testing. The results indicated that there were no significant (p > 0.05) pre- to post-test changes in forearm flexion and extension torque or EMG amplitude for the agonist and antagonist muscles. Thus, unlike previous studies of the quadriceps femoris muscles, these findings for the forearm flexors and extensors suggested that 2 days of isokinetic training may not be sufficient to elicit significant increases in strength. These results may have implications for the number of visits that are required for rehabilitation after injury, surgery, or both.     

Using biofeedback to reduce left arm extensor EMG of string players during musical performance

Electromyographic (EMG) feedback offers a mechanism for helping musicians reduce specific muscle tension during performance. Nine intermediate to advanced level string players participated in a four-session, pretest/posttest design study to determine (1) if left forearm extensor EMG could be reduced using biofeedback, (2) if reductions in EMG would generalize to a no-feedback condition, and (3) if reductions in EMG would generalize from extensors to flexors. Results indicate that biofeedback did facilitate significant decreases in EMG, that the reductions in EMG did generalize to a no-feedback condition, and that generalization from extensors to flexors did not occur.