Aiming at the gait instability phenomenon under disturbed conditions, domestic and foreign scholars have done some research works, but the relationship between the independent balancing act with the surface electromyographic and gait parameters in the process of instability has yet rarely been involved. In this study, using the gait analysis combined with electromyographic signal analysis, we investigated balance adjustment mechanism of joints and muscles of the human lower limb under the condition of walking on the level trail and after foot heel touching the ground and unexpected sliding. Studying 10 healthy subjects with the unified shoes, we acquired and analyzed the changing rule of the lower limb joint torque, joint angle, and the surface electromyographic of the main muscle groups involved in situations of dry or oid trails. Studies showed that when accident sliding happened, the body would increase ankle dorsiflexion torque moment, knee unbend torque and straight angle, and meanwhile increase the torque of hip extension, and timely adjust muscle activation time (Followed by activation of Tibialis anterior muscle→Rectus femoris→Gastrocnemius→Femoral biceps) to adjust the center of gravity, to maintain balance of the body, and to avoid falling down. The results of the research could be used to explore new ideas and to provide a certain reference value for preventing slip damage, rehabilitation training and development of lower limb walker.
At present, balanced scorecard is widely used in hospital performance management, but because of the difficulty in selecting indicators and the ambiguity of causality, its implementation on the application level is limited. Based on the theory of “competitive advantage” and resource arrangement, this study constructs an improved balanced scorecard index system for discipline performance evaluation from the perspective of improving discipline competitiveness of Ningbo No.2 Hospital. The index system mainly includes the dimensions of discipline quality development, resource allocation efficiency and so on, with the characteristics of “focusing on advantages, accurate positioning” and innovation, and has achieved good results in practical application.
Objective To investigate a modified robotized hydraulictensor for management of the ligament balance in the total knee arthroplasty. Methods The effect of the modified robotized hydraulic tensor on the mechanical behaviour of the ligament system balance in the total knee arthroplasty was analyzed andthe related information was obtained. Results The robotized hydraulic tensor acted as a tensorsensor system, which could assist the surgeon by providing thequantitative information to align the lower limb in extension, equalize the articular spaces in extension and flexion, balance the internal and external forces, and define the femoral component rotation, and by providing the information toplan the releasing of the soft tissues and the rotating of the femoral component. Conclusion The modified robotized hydraulic tensor can enable the surgeon to properly manage the ligament balance in the total knee arthroplasty.
Safe and effective anticoagulation is the key to successful blood purification. Compared with traditional systemic anticoagulation, regional citrate anticoagulation (RCA) has the advantages of prolonging the life of extracorporeal circulation and reducing bleeding complications. However, the complex protocol, the disorder of electrolyte and acid-base status and the accumulation risk in special populations have dissuaded many clinicians. This review starts with the clinical monitoring of RCA, then analyzes the causes and treatments of complications. The risk assessments in special populations were also introduced in order to the widely promotion of RCA in critically ill patients.
This study systematically explores the assessment tools for balance function in elderly patients after total hip arthroplasty and their clinical applications, while also envisioning future trends toward multidimensional integration and intelligent development. By summarizing the commonly used subjective and objective assessment in clinical practice and analyzing the application of these methods in preoperative prehabilitation and postoperative rehabilitation monitoring for elderly total hip arthroplasty patients, this article proposes that future efforts should focus on promoting the integration of subjective and objective assessment, developing intelligent predictive models, and establishing closed-loop rehabilitation systems to enhance the precision and effectiveness of assessment and rehabilitation.
ObjectiveTo explore the surgical technique and effectiveness of sliding osteotomy of medial femur condyle in handling soft tissue balance of severe valgus deformity in total knee arthroplasty (TKA). MethodsBetween June 2008 and February 2014, 18 cases (19 knees) of severe valgus knees undergoing sliding osteotomy of medial femur condyle in primary TKA were included. Of the 18 patients, 6 were male and 12 were female with an average age of 52.3 years (range, 29-72 years), including 3 cases (3 knees) of osteoarthritis, 11 cases (12 knees) of rheumatoid arthritis, 3 cases (3 knees) of post-traumatic arthritis, and 1 case (1 knee) of deformities in skeletal dysplasia. Before surgery, the tibial-femur angle (TFA) was (33.0±2.9)°; the Hospital for Special Surgery (HSS) score was 41.6±7.7; the Knee Society Score (KSS) lateral stability score was 6.0±5.4. All cases were rated as type II according to Krackow classification of valgus knee. During primary TKA, sliding osteotomy of medial femur condyle was performed via a medial parapatellar approach. ResultsIncision healed by first intention in all cases. Peroneal nerve palsy occurred in 1 patient, which was cured after 6 months of conservative treatment. Eighteen cases were followed up 19 months to 7 years, with an average of 5.7 years. All patients had no complications of deep vein thrombosis, deep infection, and prosthesis loosening. X-ray films showed that bone healing was achieved in all cases at 6 months. At last follow-up, the TFA was (4.8±1.8)°, showing significant difference when compared with preoperative value (t=62.61, P=0.00). The HSS score was 87.2±10.5 and the KSS lateral stability score was 12.4±3.1, all showing significant differences when compared with preoperative scores (t= —33.35, P=0.00; t= —6.83, P=0.00). ConclusionSliding osteotomy of medial femur condyle is effective for correcting severe valgus knee deformity during TKA. Satisfactory joint function and stability may be achieved.
This article shows a new design of telerehabilitation system for balance function assessment and training in our laboratory. The system is based on C/S network architecture, and realizes the telecommunication through socket network communication technology. It implements the teletransmission of training data and assessment report of sit-down and stand-up, online communication between doctors and patients, and doctors' management of patient information. This system realizes remote evaluation and telerehabilitation of patients, and brings great convenience for the patients.
Neuromuscular electrical stimulation (NMES) has been proven to promote human balance, but research on its impact on motor ability mainly focuses on external physical analysis, with little analysis on the intrinsic neural regulatory mechanisms. This study, for the first time, investigated the effects of NMES on cortical activity and cortico-muscular functional coupling (CMFC) during standing balance. Twelve healthy subjects were recruited in bilateral NMES training, with each session consisting of 60 electrically induced isometric contractions. Electroencephalogram (EEG) signals, electromyogram (EMG) signals, and center of pressure (COP) signals of the foot sole were collected before stimulation, two weeks after stimulation, and four weeks after stimulation while the subjects maintained standing balance. The results showed that NMES training improved subjects' postural stability during standing balance. Additionally, based on the EMG power spectral density (PSD), the κ frequency band was defined, and EEG-EMG time-frequency maximal information coefficients (TFMIC) were calculated. It was found that NMES enhanced functional connectivity between the cortex and lower limb muscles, with varying degrees of increase in β-κ and γ-κ frequency band CMFC after stimulation. Furthermore, sample entropy (SE) of EEG signals also increased after training. The results of this study confirm that NMES training can enhance CMFC and brain activation during standing balance. This study, from the perspective of physiological electrical signals, validates the effectiveness of NMES for balance training and provides objective assessment metrics for the training effects of NMES.
This article presents the design of a treadmill of comprehensive training experiment for rats. The treadmill is composed of six tracks and two of them were designed as conventional plane, two were designed to swing right and left, and two were designed to swing back and forth. The power was provided by six motors. The MSP430F149 is used as core to adjust the swing rate and the grade of electric shock. The IAR for MSP430 is used to design the software. The speed of the six tracks could be adjusted between 0 and 30 m/min. The swing tracks of back and forth can be swung for 3-25 times per minute and the swing tracks of right and left for 3-32 times. The electric shock can be divided into three levels, i.e. strong, middle, and weak level for each track. The digital comprehensive training treadmill can meet different training needs, and provide experimental data for mechanism research of some related diseases.
The present study was aimed at the optimal solution of the main muscular force distribution in the lower extremity during standing balance of human. The movement musculoskeletal system of lower extremity was simplified to a physical model with 3 joints and 9 muscles. Then on the basis of this model, an optimum mathematical model was built up to solve the problem of redundant muscle forces. Particle swarm optimization (PSO) algorithm is used to calculate the single objective and multi-objective problem respectively. The numerical results indicated that the multi-objective optimization could be more reasonable to obtain the distribution and variation of the 9 muscular forces. Finally, the coordination of each muscle group during maintaining standing balance under the passive movement was qualitatively analyzed using the simulation results obtained.