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Objective To examine the effects of ankle brace on biomechanics of the lower extremity during landing, so as to provide a theoretic support to choose ankle brace for people with different sports levels. Methods The key words (ankle brace OR ankle braces OR ankle bracing OR ankle support) AND (landing OR land OR jump OR hopped OR hopping) AND (biomechanics OR kinematics OR kinetics OR electromyography OR neuromuscular) in Chinese and English were searched from different electronic databases (CNKI, Web of Science, EBSCO, PubMed and other databases), for a period of Jan. 2000 to Dec. 2020. Cochrane was used to evaluate the quality of eligible studies. For meta analysis, subgroup analysis was used to assess the impact of ankle braces on ankle biomechanics.Results Thirteen studies with a total of 222 participants were included for mata analysis in this study. The semi-rigid ankle brace reduced the peak of ankle inversion by 25.8% compared with the elastic ankle brace (SMD=-0.562, P<0.001). Moreover, the elastic ankle brace reduced ankle plant flexion during landing among athletes (SMD=-3.42, P=-0.021). As for collagiate students, both elastic ankle and semi-rigid ankle decreased the ankle inversion (elastic ankle brace: 35.4%, SMD=-1.000, P=-0.013; semi-rigid ankle brace: 31.11%, SMD=-0.881, P<0.001) and ankle plant flexion (elastic ankle brace:23.30%, SMD=-1.381, P<0.001;semi-rigid ankle brace: 36.33%, SMD=-1.605, P<0.001).Conclusions Both ankle braces can prevent ankle sprain for athletes (basketball, volleyball, running) who experience training more than 5 years. The elastic ankle brace can limit the inversion and plantar flexion, while the semi-rigid ankle brace can merely decrease the ankle inversion. Therefore, athletes are more suitable for the elastic ankle brace. As for collegiate students without training history, both ankle brace can decrease the ankle inversion and plantar flexion. The elastic ankle brace has greater restriction on inversion, while the semi-rigid ankle brace has more restriction on plantar flexion. Therefore, the elastic ankle brace should be utilized if collegiate students have calcaneofibular ligament injury, while the semi-rigid ankle brace is more suitable for collegiate students who have a history of anterior talofibular ligament injury.
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Objective To investigate the effects of shoes type (barefoot, ordinary running shoes, minimalist shoes) and walking speed (jogging, walking at normal speed) on biomechanical parameters of knee joint, so as to provide theoretical reference for scientific fitness. Methods Vicon three-dimensional (3D) motion capture system and Kistler 3D force plate were used to collect biomechanical parameters of lower limbs from 10 subjects during walking at different speed with different shoes. Two-way (2 walking conditions × 3 shoe conditions) repeated measures analysis of variance was used to statistically analyze each dependent variable. Results Compared with jogging, the lateral excursion of plantar center of pressure (COP) was greater, the moment arm in frontal plane, the adduction moment and peak loading rate of knee joint were smaller, but the angular impulse of knee joint in frontal plane was greater. Compared with ordinary running shoes, the stride length was decreased, the lateral excursion of COP was greater, and the moment arm of knee joint in frontal plane, the knee adduction moment, the peak load rate and the angular impulse of knee joint in frontal plane were smaller. Conclusions In order to reduce the angular impulse and peak loading rate of knee joint in frontal plane, it is recommended to jog with small strides for ordinary people with minimalist footwear.
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Objective To compare the biomechanical characteristics of lower limbs of young people with different body mass index (BMI) before and after the intervention of Baduanjin exercise, so as to provide references for scientific exercise and sport prescription for young Baduanjin practitioners with different BMIs. Methods Young volunteers with different BMI were divided into standard group, overweight group and obesity group. The BTS SMART 3D infrared motion capture system was used to capture the motion parameters and electromyography (EMG) parameters, the KISTLER dynamometer was used to collect the dynamic parameters, the AnyBody simulation software was used to calculate the kinematic parameters and dynamic parameters, and BTS SMART Analyzer was used to compare the different integral electromyography values. Results There was no significant difference in each parameter before the intervention of Baduanjin. After the intervention, the angle and angular velocity of the knee joint during extension and flexion in standard group, overweight group and obesity group, and the angular acceleration of the knee joint during extension and flexion in standard group significantly increased. Baduanjin significantly increased the knee flexion force and moment in standard group, overweight group and obesity group, and increased the hip flexion force and moment as well as ankle metatarsal flexion force and moment in standard group. Compared with obesity group, the knee flexion force and moment in standard group were significantly different. The knee joint force and moment were positively correlated with BMI. Baduanjin significantly increased muscle strength of iliopsoas, gluteus medius, piriformis, gluteus maximus, rectus femoris, sartorius, tibialis anterior, biceps femoris longhead, flexor digitorum longus, flexor pollicis longus, musculus peroneus longus and musculus peroneus brevis. Baduanjin significantly increased the integrated electromyogram (iEMG) of rectus femoris, tibialis anterior, biceps femoris. Conclusions Baduanjin can improve muscle strength and neuromuscular control ability of young people. The larger the BMI, the greater the flexion force and moment of the knee joint.
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BACKGROUND: The motor neuromuscular control of the ankle is decreased in individuals with chronic ankle instability, which impairs athletic performance. Kinesio taping has been widely used in the prevention and treatment of chronic ankle instability. However, there is limited research exploring the effects of kinesio taping on motor neuromuscular control in individuals with chronic ankle instability currently, and moreover, the results are in controversy with large heterogeneity. OBJECTIVE: To describe the current research situation of the effects of kinesio taping on motor neuromuscular control in individuals with chronic ankle instability, thereby providing reliable reference in clinical practice METHODS: The first author searched the articles addressing the application of kinesio taping in chronic ankle instability from January 2009 to July 2019 in the databases of PubMed, Cochrane, WOS and CNKI. The keywords were “chronic ankle instability, ankle instability, ankle”, “kinesio tap*, kinesiology tap*, kinaesthetic tap*, tap*” in Chinese and English. RESULTS AND CONCLUSION: Kinesio taping may improve ankle proprioception and jumping biomechanical performance in individuals with chronic ankle instability, but more high-quality researches are required. There is insufficient evidence to encourage that the use of kinesio taping can facilitate muscle strength, activation characteristics and balance function in individuals with chronic ankle instability. The existing studies have extensive heterogeneity in the selection of subjects, so it is difficult to comprehensively summarize the patients with chronic ankle instability of different exercise types and levels. The included scales of different studies are different, there are obvious differences in the methods, pull, direction, and duration when using kinesio taping, and there is no uniform standard. There is a lack of high-quality meta-analysis for evidence-based argumentation.
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In recent years, the effects of the neuro-biomechanical ergogenic technology on improving and enhancing human function and physical movement performance have widely attracted certain attentions. This review summarized the recent achievements in the effects of non-invasive brain stimulation (NIBS) and biomechanical ergogenic technology based on sports equipment on human physical performance, and further explored the possible mechanisms for improving and promoting human physical performance. The obtained preliminary evidence based on animal experiments and biomechanical researches on neuromotor control under multi-joint movement were also summarized, so as to explain the coordinated development of human function enhancement at cerebral cortex regulation and neuromuscular coordinated control levels, and interpret its integration with sports equipment. This review ultimately provided certain references for the future frontier development and research position of neuro-biomechanics and human sports biomechanics.
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Objective To study the intrinsic relationship between hemiplegic gait features and abnormal muscle strength of lower limbs, so as to elucidate the muscle strength causes of hemiplegic gait and provide recommendations for its clinical treatment. Methods Models of hemiplegic gait and normal gait were established for simulation, and the validity of the models was verified by comparing the simulation model with measured data of the normal gait. The differences in kinetic data, ground reaction force (GRF) and muscle force between the two models were analyzed to explore the different dynamic characteristic of hemiplegic gait and normal gait. Results The complex correlation coefficient between LifeMOD simulation results and measured data was 0.922, indicating that the established dynamic model was reasonable and effective. Hemiplegic patient with low tibialis anterior muscle strength led to ankle dorsiflexion inadequacy during initial ground period, and low gastrocnemius muscle could not achieve the promoting effect from ground during preswing period. Conclusions The strength weakness of tibialis anterior muscle and gastrocnemius are the main reasons for foot drooping and other hemiplegic gait characteristics. LifeMOD modeling and simulation can assist the diagnosis of abnormal muscle strength in hemiplegia patients.
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Objective To study the intrinsic relationship between hemiplegic gait features and abnormal muscle strength of lower limbs,so as to elucidate the muscle strength causes of hemiplegic gait and provide recommendations for its clinical treatment.Methods Models of hemiplegic gait and normal gait were established for simulation,and the validity of the models was verified by comparing the simulation model with measured data of the normal gait.The differences in kinetic data,ground reaction force (GRF) and muscle force between the two models were analyzed to explore the different dynamic characteristic of hemiplegic gait and normal gait.Results The complex correlation coefficient between LifeMOD simulation results and measured data was 0.922,indicating that the established dynamic model was reasonable and effective.Hemiplegic patient with low tibialis anterior muscle strength led to ankle dorsiflexion inadequacy during initial ground period,and low gastrocnemius muscle could not achieve the promoting effect from ground during preswing period.Conclusions The strength weakness of tibialis anterior muscle and gastrocnemius are the main reasons for foot drooping and other hemiplegic gait characteristics.LifeMOD modeling and simulation can assist the diagnosis of abnormal muscle strength in hemiplegia patients.
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Martial arts are practiced in both amateur and in high professional level, stimulating scientific research in several areas of knowledge, including biomechanics. The main purpose of this review is to present the biomechanics methods used in the study of martial arts. The great importance of this study is the compilation of information science of what has already been analyzed under the biomechanics aspects related to martial arts and how this has been done. The methodology was directed to the revision of literature starting from articles, books, and seminars. From the collection of bibliographic surveys, it has been concluded that depending on the parameters studied e.g.: reaction time, speed, strength, power, among others, there is the need to apply one or more methods since there are situations in which only one biomechanical method will not be enough to answer the pointed question. It is also concluded that the investigated studies in the presented review showed the character of a descriptive examination, not directly applied to the development of techniques used on different modalities.
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Humans , Martial Arts/physiology , Biomechanical Phenomena , Martial Arts , Kinesiology, Applied , Meta-Analysis as Topic , SportsABSTRACT
En este artículo se presenta el estudio de la técnica deportiva para esgrima por medio de un análisis biomecánico, realizado con ayuda de sistemas optoelectrónicos que capturan en tiempo real los dos gestos más destacados, el paso adelante y el fondo, con el objetivo de caracterizar digitalmente la biomecánica para su posterior análisis cinemático y de esta manera describir la técnica que tiene el deportista en la ejecución del movimiento. Con este estudio se lograron caracterizar de una forma cuantitativa las curvas de posición, ángulos articulares, velocidades y aceleraciones de cada uno de los marcadores situados en el cuerpo del deportista. Este estudio se realizó en un deportista de alto rendimiento, destacado en la modalidad de espada.
This article presents the study of fencing techniques through biomechanical analysis, using optoelectronic systems that capture in real time two main gestures: advance and lunge, with the objective to digitally characterize the biomechanics, for its further kinematical analysis to describe the fencer's technique in the movement execution. This study was made to characterize position curves, joint angles, velocity and acceleration of each of the markers located on the athlete's body, in a quantitative manner. This study was developed on a high performance athlete in sword modality.