Background. This study establishes the shoulder model on the drawing side of recurve archers by the finite element method and finds out the stress changes on the rotator cuff muscles in the position of the humerus and scapula under different stages of special techniques. The aim of this study is to investigate the mechanism of rotator cuff damage on a recurve archer’s drawing arm. Methods. A 22-year-old healthy male’s shoulder CT and MRI data were collected, and the drawing side shoulder joint finite element model was constructed, which contains the structure of the shoulder blades, clavicle, humerus, supraspinatus, infraspinatus, teres minor, and subscapularis. The humerus on the drawing arm was simulated to raising the bow, drawing, holding, and releasing on the scapula plane, and stress changes in rotator cuff muscles are analyzed. Results. The peak stress on the infraspinatus increased slowly, and from the start of raising the bow to hold and release, the stress peak increased from 0.007 MPa to 0.009 MPa. The peak stress on teres minor rises slowly from 0.003 MPa at the start of raising the bow to 0.010 MPa at the moment of releasing. The peak stress in the subscapularis increased from 0.096 MPa to 0.163 MPa between the start of raising the bow and releasing. The peak stress on the supraspinatus varied greatly, and from the start of raising the bow to the start of drawing, the stress peak increased markedly from 1.159 MPa to 1.395 MPa. Subsequently, the stress peak immediately decreased to 1.257 MPa at the start of holding and then increased to 1.532 MPa at releasing. Conclusion. The position of the humerus and scapula would change with the different stages of special techniques. It causes stress changes in the rotator cuff muscles, and when the stress accumulates over time, the shoulder 5on the drawing side will gradually become injured and dysfunctional. In combination with the depth of the structural site and the surrounding structural features, corrective exercises can be used to prevent injury to the rotator cuff muscles.
Background:The purpose of this study was to simulate the drawing arm of male recurve archers by finite element method. And observe the stress changes of humerus and scapula on the subacromial bursa under different stages of special techniques. To investigate the mechanism of the subacromial bursa injury in male recurve archers. Methods: Collected a 22-year-old healthy men shoulder CT and MRI data, construct the bow side shoulder joint finite element model, contains the structure of the shoulder blades, clavicle, humerus, and subacromial bursa. The humerus on the drawing side of the curve was simulated to perform the raising the bow, drawing, holding and releasing actions on the scapula plane, analysis of stress changes in subacromial bursa. Results: The peak stress on the subacromial bursa varied greatly. From the start of raising the bow to the start of drawing, the stress peak decreased markedly from 0.280 MPa to 0.036 MPa. Then, the peak stress immediately increased to 0.347 MPa at the beginning of the holding and decreased to 0.262 MPa at releasing. Conclusions: The reason for the stress surge on the subacromial bursa in the holding phase is that its structure is easily squeezed by multiple surrounding tissue structures, resulting in high stress and susceptibility to damage. In combination with the depth of the structural site and the surrounding structural characteristics, this can prevent subacromial bursa injury. The results of this work are particularly relevant to the prevention of subacromial bursa injury in male recurve archers.
Mobile robots belong to mechanical devices. Mobile robots are commanded by humans and restricted by the principles established by artificial intelligence technology, mainly to assist humans in dangerous tasks. Intelligent mobile robot is a system that integrates perception, analysis, and decision-making, and it integrates a number of high-end technologies. It is currently the most active field of technological development. Infant sport is essentially a process of cultivating and caring for the physical fitness of children. This article aims to explore the auxiliary role of intelligent mobile robots in the standard training of children’s sports movements. The physique of the early childhood stage is closely related to the entire life stage. Once there is a deviation in the early childhood training stage, there will be very serious consequences. Therefore, the mobile intelligent robot is combined with children’s physical training, and it is expected that it will give correct guidance to improve children’s physical fitness. This article briefly designs the mobile robot, uses two independent wheels and a robotic arm with degrees of freedom, and analyzes the forward and inverse kinematics of the chassis and the robotic arm, which provides a theoretical basis for the design of the control algorithm. This article will focus on the training of children’s sports, explore the current deficiencies in children’s sports, and analyze the reasons and the role that intelligent mobile robots can provide in sports training. The experimental results in this paper show that the balance ability of children standing on one foot with eyes open is mainly distributed in the second, third, and fourth levels. Among them, the second level has the largest number of people, accounting for 52%, the third level accounts for 27%, the fourth level accounts for 22%, and the other levels are less distributed. When the intelligent mobile robot assists children’s movement, the child’s balance ability is generally distributed in the fourth and fifth levels. Among them, the fourth level has the largest number of people, accounting for 52%, followed by the fifth level, accounting for 26%, and the third level accounting for 14%. This shows that the intelligent mobile robot is effective in guiding the movement of young children.
Stress-related memory deficit is correlated with neurotransmitter system impairment. Exercise improves memory function and neurotransmitter. However, no studies have been performed to directly observe exercise-related effects on neurotransmitter in stress model, in association with memory function and hippocampal neuron. This study aimed to investigate the effect of exercise on hippocampal neuron and dopamine in stress model, followed by working memory in a passive avoid test. Our study found that stress rat had significantly neuron impairment and dopamine loss in hippocampus plus working memory deficit, which can be rescued by exercise. In summary, this study demonstrated that the neuroprotective effect of stress-associated working memory by treadmill exercise via ameliorated neuron impairment and dopamine loss.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.