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Objective To explore the relationship between shoe comfort and foot loading characteristics in two types of basketball shoe during different basketball footwork. Methods Two Kistler 3D force platforms and Medilogic insole plantar pressure system were used to collect the kinetic data of 12 healthy male basketball players wearing two types of basketball shoe (shoe L and shoe N) during three varieties of basketball footwork (side-step cutting, 90° varied-direction running, lay-up), including peak impact force, peak loading rate, and peak plantar pressure. The perception test scale was used to evaluate comfort for two types of basketball shoe during three kinds of basketball footwork. Results For the two types of basketball shoes, there was no significantly difference in the impact force during the three kinds of basketball footwork, but the plantar pressure of shoe L was significantly greater than that of shoe N during side-step cutting and lay-up. Shoe N was significantly more comfortable than shoe L, with a significant difference in preference (heel stability, heel responsiveness, forefoot cushioning, heel cushioning, and overall liking) and intensity (forefoot and heel cushioning) on a dynamic scale. Conclusions The plantar pressure and comfort show significant differences in the two types of shoes; however, none of the shoes appeared definitively superior in the two evaluations. It is suggested that the biomechanical characteristics of the shoes and the subjective evaluation of the athletes should be considered in the overall design and evaluation of specialized shoes.
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Objective To investigate the influence of barefoot running and shod running with different foot-strike patterns on characteristics of plantar pressures and ground reaction force (GRF).Methods Kistler force plates and Medilogic insole plantar pressure system were used to collect the kinetic data from a total of 12 healthy male volunteers under shod and barefoot conditions with heel strike and forefoot strike at the speed of 3 m/s,including the GRF,the peak impact force,the maximum loading rate,the peak plantar pressure and impulse.Results (1) Shod running with heel strike significantly reduced the maximum loading rate and extended the time to reach the peak impact force.Under forefoot strike pattern,shod running significantly increased the maximum push-off force than barefoot running.(2) More plantar pressure parameters were influenced by the foot-strike patterns as compared to those under the shod conditions,and there was a significant difference in the peak pressure and the time to reach the peak pressure in the mid-foot and heel region between two foot-strike patterns.Conclusions The foot-strike pattern shows a more obvious influence on plantar pressure during jogging than the shod conditions.Shod running with heel strike can reduce the impact load,while barefoot running with forefoot strike can cause an excessive concentration of plantar pressure on the forefoot region,indicating that a suitable pair of sports shoes is needed for both foot-strike patterns to reduce the plantar pressure during jogging.
ABSTRACT
Objective To investigate the influence of barefoot running and shod running with different foot-strike patterns on characteristics of plantar pressures. Methods Kistler force plates and Medilogic insole plantar pressure system were used to collect and compare the kinetic data from a total of 12 healthy male volunteers under shod and barefoot conditions with heel-toe run and toe-toe run at the speed of 3 m/s, including the GRF, loading rate, plantar pressure and impulse. Results (1) Shod running with heel-toe strike significantly reduced the maximum loading rate and extended the time to reach the peak of impact force. Under forefoot strike pattern, shod running significantly increased the maximum push-off force than barefoot running. (2) More plantar pressure parameters were influenced by the foot-strike patterns as compared to those under the shod conditions, and there was a significant difference in the peak pressure and the time to reach the peak pressure in the mid-foot and heel region between the two foot-strike patterns. Conclusions The foot-strike pattern shows a more obvious influence on plantar pressure during jogging than the shod conditions. Shod running with heel strike can reduce the impact force, while barefoot running with forefoot strike can cause an excessive concentration of plantar pressure on the forefoot region, which indicates that a suitable pair of sports shoes is needed for both foot-strike patterns to reduce plantar pressure during jogging.
ABSTRACT
Objective To investigate the influence of barefoot running and shod running with different foot-strike patterns on characteristics of plantar pressures and ground reaction force (GRF).Methods Kistler force plates and Medilogic insole plantar pressure system were used to collect the kinetic data from a total of 12 healthy male volunteers under shod and barefoot conditions with heel strike and forefoot strike at the speed of 3 m/s,including the GRF,the peak impact force,the maximum loading rate,the peak plantar pressure and impulse.Results (1) Shod running with heel strike significantly reduced the maximum loading rate and extended the time to reach the peak impact force.Under forefoot strike pattern,shod running significantly increased the maximum push-off force than barefoot running.(2) More plantar pressure parameters were influenced by the foot-strike patterns as compared to those under the shod conditions,and there was a significant difference in the peak pressure and the time to reach the peak pressure in the mid-foot and heel region between two foot-strike patterns.Conclusions The foot-strike pattern shows a more obvious influence on plantar pressure during jogging than the shod conditions.Shod running with heel strike can reduce the impact load,while barefoot running with forefoot strike can cause an excessive concentration of plantar pressure on the forefoot region,indicating that a suitable pair of sports shoes is needed for both foot-strike patterns to reduce the plantar pressure during jogging.
ABSTRACT
Objective To investigate the influence of barefoot running and shod running with different foot-strike patterns on characteristics of plantar pressures and ground reaction force (GRF).Methods Kistler force plates and Medilogic insole plantar pressure system were used to collect the kinetic data from a total of 12 healthy male volunteers under shod and barefoot conditions with heel strike and forefoot strike at the speed of 3 m/s,including the GRF,the peak impact force,the maximum loading rate,the peak plantar pressure and impulse.Results (1) Shod running with heel strike significantly reduced the maximum loading rate and extended the time to reach the peak impact force.Under forefoot strike pattern,shod running significantly increased the maximum push-off force than barefoot running.(2) More plantar pressure parameters were influenced by the foot-strike patterns as compared to those under the shod conditions,and there was a significant difference in the peak pressure and the time to reach the peak pressure in the mid-foot and heel region between two foot-strike patterns.Conclusions The foot-strike pattern shows a more obvious influence on plantar pressure during jogging than the shod conditions.Shod running with heel strike can reduce the impact load,while barefoot running with forefoot strike can cause an excessive concentration of plantar pressure on the forefoot region,indicating that a suitable pair of sports shoes is needed for both foot-strike patterns to reduce the plantar pressure during jogging.
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AbstractIntroduction Footwear is no longer just an accessory but also a protection for the musculoskeletal system, and its most important characteristic is comfort.Objectives This study aims to identify and to analyze the vertical ground reaction force in barefoot women and women with unstable shoes.Methodology Five women aged 25 ± 4 years old and mass of 50 ± 7 kg participated in this study. An AMTI force plate was used for data acquisition. The 10 trials for each situation were considered valid where the subject approached the platform with the right foot and at the speed of 4 km/h ± 5%. The instable shoe of this study is used in the practice of physical activity.Results The results showed that the first peak force was higher for the footwear situation, about 5% and significant differences between the barefoot and footwear situation. This significant difference was in the first and second peaks force and in the time of the second peak.Conclusion The values showed that the footwear absorbs approximately 45% of the impact during gait.
ResumoIntrodução O calçado deixou de ser acessório e tornou-se uma proteção para o sistema musculoesquelético, tendo como principal objetivo o conforto.Objetivo O presente estudo tem como objetivo verificar e analisar a componente vertical de reação do solo em mulheres descalço e com calçado instável.Metodologia Participaram deste estudo cinco mulheres com idade de 25 ± 4 anos e massa de 50 ± 7 kg. Para a aquisição dos dados foi utilizado plataforma AMTI. Foram consideradas válidas 10 tentativas de o sujeito abordar a plataforma com o pé direito e na velocidade de 4 km/h ± 5%. O calçado instável deste estudo foi utilizado na prática de atividade física.Resultados Os resultados apresentaram que o primeiro pico de força foi maior para a situação calçado, cerca de 5%, e diferenças significativas entre a situação descalço e com calçado para o primeiro pico de força, segundo pico de força e tempo do segundo pico de força.Conclusão Verificou-se que o calçado absorve aproximadamente 45% do impacto durante a marcha.
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Objective To explore the influence of basketball shoes on impact force and corresponding muscle activation in the lower limb during the active and passive landing. Methods Twelve male ball players wearing two types of shoes (basketball shoes with cushioning insole vs. control shoes) performed the jump drop and passive landing from three different height on the tiltable platform. The dynamometric platform and electromyography (EMG) measurement system were used to collect the impact forces and EMG data from 5 major muscles in the lower limb simultaneously. Results As for the active drop jump, wearing basketball shoes didn’t have any effect on the amplitude/frequency of impact forces and muscle activation in the lower limb. However, during the passive landing, wearing basketball shoes could significantly decrease the amplitude of impact forces, the peak loading rate and the input frequency (P<0.05), and the post-activation of major muscles in the lower limb were also significantly decreased (P<0.05). Conclusions During the active landing, the intervention of footwear shows no significantly influence on characteristics of impact forces and muscle activation. However, when the human body does not under the full control of landing, wearing basketball shoes can change the input frequency, decrease the muscle post-activation, and play a positive role in preventing the sports injuries and enhancing the metabolic efficiency during the landing.
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[Objective]To simulate the biomechanics mechanism and environment of humeral fracture caused by indirect impact force for the purpose of biomechanics understanding and treatment of such fracture.[Method]Based on the data source, which was high-resolution anatomic slice images from approximal clavicle to distal humerus, 1 mm thickness and totally 380 layers, the geometric model of total shoulder joint was established according to the order:point, line,area, and further meshed to set up the three dimension finite element model of shoulder, fracture sites and instantaneous stress and strain of humerus were simulated and analyzed under the condition which longitudinal impact force was loaded on the humerus based on the 12 functional positions of shoulder(abduction 30?、 45?、 60?、 90?, and simultaneous neutrality, internal rotation 45?,external rotation 45?).[Result]According to the humeral shaft load-strain curve in different functional positions of shoulder, linear relation was found when load changed from 0 N to 250 N, after which non-linear come out, and even load was removed , bone was deformed eternally. With the rise in load amount, the increase in stress was detected. When abduction degree changed from 90? to 30?, the strain of humerus, both the lateral and the medial increased gradually,and increase in internal rotation 45?and external rotation 45? was more significant than that in neutrality. Meanwhile, stress difference could be seen between the lateral and the medial , and medial was larger than the lateral. Increase in stress in rotation positions was quicker and more than that in other functional positions.[Conclusion]Based on 4 abduction degrees (30?, 45?, 60?, 90?) and 3 rotation degrees(neutrality, internal rotation 45?,external rotation 45?) ,the three dimensional finite element shoulder could simulate precisely stress, strain, general trend of fracture line, three dimension images of bone failure. Three dimension finite element simulation and analysis of shoulder is a valuable mechanical method for research on biomechanics theory related to humerus fracture.