针刺运动疗法联合早期康复训练对急性踝关节扭伤患者踝关节功能、血清炎症因子和致痛物质水平的影响

摘要 目的：观察针刺运动疗法联合早期康复训练对急性踝关节扭伤患者踝关节功能、血清炎症因子和致痛物质水平的影响。方法：选取湖南中医药大学第一附属医院2019年5月~2022年1月期间收治的116例急性踝关节扭伤患者。按照随机数字表法分为对照组（早期康复训练,n=58）和研究组（针刺运动疗法联合早期康复训练,n=58）。观察两组治疗前、治疗4周后的疗效、量表评分[视觉模拟评分（VAS）、美国足与踝关节协会（AOFAS）踝-后足功能评分]、踝关节功能、血清炎症因子[白细胞介素（IL）-1β、IL-6和肿瘤坏死因子-α（TNF-α）]和致痛物质[神经肽（NPY）、P物质（SP）]水平。结果：研究组的临床总有效率为96.55%,高于对照组的77.59%,差异有统计学意义（P<0.05）。治疗4周后,研究组的AOFAS评分高于对照组（P<0.05）,VAS评分低于对照组（P<0.05）,血清IL-6、TNF-α、IL-1β水平低于对照组（P<0.05）,踝关节背伸活动度、踝关节跖屈活动度大于对照组（P<0.05）,血清NPY、SP水平低于对照组（P<0.05）。结论：急性踝关节扭伤患者经针刺运动疗法联合早期康复训练干预后,可有效降低其血清致痛物质和炎症因子水平,有利于疼痛症状的缓解及踝关节功能的恢复。     

不同内固定方式治疗老年踝关节骨折的临床研究

摘要 目的：探讨老年踝关节骨折患者的内固定方式的选择情况及不同内固定方式的疗效,进而指导临床医师根据患者的具体情况选择合适的内固定方式。方法：本研究为回顾性研究,选取我院2016年1月~2018年12月期间收治的老年踝关节骨折患者40例作为研究对象,统计患者一般情况,内容包括骨折块情况、骨折类型、骨质疏松情况、软组织情况与体质。术后随访12个月,评价所有患者末次随访时的踝关节跖屈度、踝关节背伸度、美国足踝外科协会（AOFAS）踝-后足功能评分,记录所有患者的骨折愈合时间。结果：40例研究对象中,使用克氏针张力带11例,Herbert螺钉10例,解剖锁定钢板7例,解剖复合钢板6例,1/3管型钢板6例。骨折块较小、外踝撕脱性骨折的患者主要应用克氏针张力带;伴有骨质疏松的患者主要应用解剖锁定钢板;软组织条件不佳或受损的患者主要应用Herbert螺钉或1/3管型钢板;超重或肥胖患者主要应用解剖复合钢板;瘦弱患者主要应用1/3管型钢板。末次随访时,5种内固定方式患者的踝关节背伸度、踝关节跖屈度、AOFAS踝-后足功能评分比较未见显著性差异（P＞0.05）。5种内固定方式的骨折愈合时间对比差异存在统计学意义（P＜0.05）。结论：老年踝关节骨折应根据患者具体情况选择合理的内固定方式,不同内固定方式患者的骨折愈合时间虽存在差异,但最终均可获得较为满意的疗效。     

Lower limb kinematics in individuals with chronic low back pain during walking

Several investigators have suggested the presence of a link between Chronic Low Back Pain (CLBP) and lower limbs kinematics that can contribute to functional limitations and disability. Moreover, CLBP has been connected to postural and structural asymmetry. Understanding the movement pattern of lower extremities and its asymmetry during walking can provide a basis for examination and rehabilitation in people with CLBP. The present study focuses on lower limbs kinematics in individuals with CLBP during walking. Three-dimensional movements of the pelvic, hip, knee and ankle joints were tracked using a seven-camera Qualysis motion capture system. Functional dada analysis (FDA) was applied for the statistical analysis of pelvic and lower limbs motion patterns in 40 participants (20 CLBP and 20 controls). The CLBP group showed significantly different hip motion pattern in the transvers plane, altered knee and ankle motion pattern in the sagittal plane on the dominant side and different hip motion pattern in the transvers and frontal planes on the non-dominant side in comparison with the control group over the stance phase. In terms of symmetry, in the CLBP group, hip and knee moved through a significantly different motion patterns in the transvers plane on the dominant side in comparison with the non-dominant side. In the control group, knee moved through a significantly different motion pattern in the transvers plane on the dominant side in comparison with the non-dominant side. In conclusion, low back pain lead to altered movement patterns of the main joints of lower limbs especially on the dominant side during stance phase. Therefore, care should be taken to examine dominant lower limb movement pattern in CLBP to make a better clinical decision.     

Interaction against different environmental dynamics during a leg extension task is controlled by temporal rather than amplitude scaling of muscular activity

Force exertion against different mechanical environments can affect motor control strategies in order to account for the altered environmental dynamics and to maintain the ability to produce force. Here, we investigated the change of muscular activity of selected muscles of the lower extremities while the participants interacted with an external mechanical device of variable stability. Twenty-five healthy participants exerted force against the device by performing a unilateral ballistic leg extension task under 1 or 3 degrees of freedom (DoF). Directional force data and electromyographic responses from four leg muscles (TA, VM, GM, PL) were recorded. Muscle responses to the altered experimental conditions were analyzed by calculating time to peak electrical activity (TTP), peak electrical activity (PEA), slope of EMG-signal and muscle activity. It was found that neuromuscular system adjustments to the task are expressed mainly by temporal (TTP) rather than amplitude (PEA) scaling of muscular activity. This change was specific for the investigated muscles. Moreover, a selective increase of muscle activity occurred while increasing external DoF. This scheme was accompanied by a significant reduction of applicable force against the device in the unstable 3 DoF condition. The findings suggest that orchestration of movement control is linked to environmental dynamics also affecting the ability to produce force under dynamic conditions. The adjustments of the neuromuscular system are rather temporal in nature being consistent with the impulse timing hypothesis of motor control.     

Human talus bones from the Middle Pleistocene site of Sima de los Huesos (Sierra de Atapuerca,Burgos, Spain)

Here we present and describe comparatively 25 talus bones from the Middle Pleistocene site of the Sima de los Huesos (SH) (Sierra de Atapuerca, Burgos, Spain). These tali belong to 14 individuals (11 adult and three immature). Although variation among Middle and Late Pleistocene tali tends to be subtle, this study has identified unique morphological characteristics of the SH tali. They are vertically shorter than those of Late Pleistocene Homo sapiens, and show a shorter head and a broader lateral malleolar facet than all of the samples. Moreover, a few shared characters with Neanderthals are consistent with the hypothesis that the SH population and Neanderthals are sister groups. These shared characters are a broad lateral malleolar facet, a trochlear height intermediate between modern humans and Late Pleistocene H. sapiens, and a short middle calcaneal facet. It has been possible to propose sex assignment for the SH tali based on their size. Stature estimates based on these fossils give a mean stature of 174.4 cm for males and 161.9 cm for females, similar to that obtained based on the long bones from this same site.     

透明质酸钠联合硫酸氨基酸葡萄糖钾胶囊对踝关节损伤患者血清骨性标志物水平及关节功能的影响

目的:探讨透明质酸钠联合硫酸氨基酸葡萄糖钾胶囊对踝关节损伤患者血清骨性标志物水平及关节功能的影响。方法:选择2015年1月至2017年1月在我院接受治疗的120例踝关节损伤患者,将其随机分为观察组和对照组,每组各60例。对照组患者采用透明质酸钠联治疗,观察组则在对照组治疗方案的基础上联合硫酸氨基酸葡萄糖钾胶囊进行治疗。检测和比较两组患者治疗前后血清骨钙素(BGP)、I型前胶原羧基端肽(PICP)、骨源性碱性磷酸酶(BALP)水平及Baird-Jackson踝关节评分的变化情况及治疗后的临床疗效。结果:治疗后,观察组的总有效率(91.67%)明显高于对照组(78.33%,P0.05)。两组患者治疗后的血清BGP、PICP、BALP水平及Baird-Jackson踝关节评分均较治疗前显著升高,且观察组明显高于对照组(P0.05)。两组治疗过程中均无明显不良反应发生。结论:透明质酸钠联合硫酸氨基酸葡萄糖钾胶囊治疗踝关节损伤患者的临床疗效显著优于单用透明质酸钠联治疗,其可有效改善血清骨性标志物水平,且利于踝关节功能的恢复。     

Children with cerebral palsy have larger Achilles tendon moment arms than typically developing children

The effectiveness of the plantarflexor muscle group to generate desired plantarflexion moments is modulated by the geometry of the Achilles tendon moment arm (ATMA). Children with cerebral palsy (CP) frequently have reduced plantarflexion function, which is commonly attributed to impaired muscle structure and function, however little attention has been paid to the potential contribution of ATMA geometry. The use of musculoskeletal modelling for the simulation of gait and understanding of gait mechanics, rely on accuracy of ATMA estimates. This study aimed to compare 3D in-vivo estimates of ATMA of adults, children with CP and typically developing (TD) children, as well as compare 3D in-vivo estimates to linearly scaled musculoskeletal model estimates. MRI scans for eight children with CP, 11 TD children and nine healthy adults were used to estimate in-vivo 3D ATMA using a validated method. A lower limb musculoskeletal model was linearly scaled to individual tibia length to provide a scaled ATMA estimate. Normalised in-vivo 3D ATMA for children with CP was 17.2% ± 2.0 tibia length, which was significantly larger than for TD children (15.2% ± 1.2, p = 0.013) and adults (12.5% ± 0.8, p < 0.001). Scaled ATMA estimates from musculoskeletal models significantly underestimated in-vivo estimates for all groups, by up to 34.7%. The results of this study show children with CP have larger normalised 3D ATMA compared to their TD counterparts, which may have implications in understanding reduced plantarflexor function and the efficacy of surgical interventions whose aim is to modify the musculoskeletal geometry of this muscle group.     

The prostacyclin analogue beraprost sodium prevents development of arterial stiffness in elderly patients with cerebral infarction

Prostacyclin (PGI(2)) inhibits platelet aggregation, smooth muscle cell proliferation, and vasoconstriction. Arterial stiffness assessed by pulse wave velocity (PWV) predicts mortality in various cardiovascular diseases. To study the preventive effects of a prostacyclin analogue, beraprost sodium, on arterial PWV values in elderly patients with cerebral infarction. Forty-four patients with a history of cerebral infarction received beraprost sodium (120 microg/day p.o.) or no beraprost sodium (control) for 3 months. Arterial PWV and ankle brachial indices (ABI) were determined prior to starting the medication and after 3 months of medication. Initially, there were no differences in age, blood pressure, and body mass index. Further, PWV or ABI did not differ between the beraprost sodium group (n = 22) and the control group (n = 22). After 3 months, PWV in beraprost sodium group was significantly reduced (-123 +/- 282) when compared with the control group (147 +/- 274)(P = 0.006). ABI was not significantly different when comparing the two groups at 3 months. Long-term administration of beraprost sodium prevents the decline in arterial biomechanics in elderly patients with cerebral infarction.     

Discovery of a thermophilic protein complex stabilized by topologically interlinked chains

A growing number of organisms have been discovered inhabiting extreme environments, including temperatures in excess of 100 degrees C. How cellular proteins from such organisms retain their native folds under extreme conditions is still not fully understood. Recent computational and structural studies have identified disulfide bonding as an important mechanism for stabilizing intracellular proteins in certain thermophilic microbes. Here, we present the first proteomic analysis of intracellular disulfide bonding in the hyperthermophilic archaeon Pyrobaculum aerophilum. Our study reveals that the utilization of disulfide bonds extends beyond individual proteins to include many protein-protein complexes. We report the 1.6 A crystal structure of one such complex, a citrate synthase homodimer. The structure contains two intramolecular disulfide bonds, one per subunit, which result in the cyclization of each protein chain in such a way that the two chains are topologically interlinked, rendering them inseparable. This unusual feature emphasizes the variety and sophistication of the molecular mechanisms that can be achieved by evolution.     

Inter-joint coupling effects on muscle contributions to endpoint force and acceleration in a musculoskeletal model of the cat hindlimb

The biomechanical principles underlying the organization of muscle activation patterns during standing balance are poorly understood. The goal of this study was to understand the influence of biomechanical inter-joint coupling on endpoint forces and accelerations induced by the activation of individual muscles during postural tasks. We calculated induced endpoint forces and accelerations of 31 muscles in a 7 degree-of-freedom, three-dimensional model of the cat hindlimb. To test the effects of inter-joint coupling, we systematically immobilized the joints (excluded kinematic degrees of freedom) and evaluated how the endpoint force and acceleration directions changed for each muscle in 7 different conditions. We hypothesized that altered inter-joint coupling due to joint immobilization of remote joints would substantially change the induced directions of endpoint force and acceleration of individual muscles. Our results show that for most muscles crossing the knee or the hip, joint immobilization altered the endpoint force or acceleration direction by more than 90° in the dorsal and sagittal planes. Induced endpoint forces were typically consistent with behaviorally observed forces only when the ankle was immobilized. We then activated a proximal muscle simultaneous with an ankle torque of varying magnitude, which demonstrated that the resulting endpoint force or acceleration direction is modulated by the magnitude of the ankle torque. We argue that this simple manipulation can lend insight into the functional effects of co-activating muscles. We conclude that inter-joint coupling may be an essential biomechanical principle underlying the coordination of proximal and distal muscles to produce functional endpoint actions during motor tasks.