An Integrated Musculoskeletal-Finite-Element Model to Evaluate Effects of Load Carriage on the Tibia During Walking

Xu, Chun Hua; Silder, Amy; Ju, Zhang; Hughes, Julie M.; Unnikrishnan, Ginu; Reifman, Jaques; Rakesh, V.

doi:10.1115/1.4034216

Cited by 29 publications

(34 citation statements)

References 47 publications

(56 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Knowledge of the internal musculoskeletal forces acting on the knee joint during dynamic functional movements has significant potential for informing injury and degenerative disease prevention strategies, 48 improving the outcomes of orthopedic treatments, 31 enhancing implant designs, 3,24 and validating computational model predictions. 18,38 Since the 1970s, multibody musculoskeletal models of increasing complexity have been proposed to predict such internal knee joint loading conditions.…”

Section: Introductionmentioning

confidence: 99%

The Capacity of Generic Musculoskeletal Simulations to Predict Knee Joint Loading Using the CAMS-Knee Datasets

et al. 2020

View full text Add to dashboard Cite

Musculoskeletal models enable non-invasive estimation of knee contact forces (KCFs) during functional movements. However, the redundant nature of the musculoskeletal system and uncertainty in model parameters necessitates that model predictions are critically evaluated. This study compared KCF and muscle activation patterns predicted using a scaled generic model and OpenSim static optimization tool against in vivo measurements from six patients in the CAMS-knee datasets during level walking and squatting. Generally, the total KCFs were under-predicted (RMS: 47.55%BW, R 2 : 0.92) throughout the gait cycle, but substiantially over-predicted (RMS: 105.7%BW, R 2 : 0.81) during squatting. To understand the underlying etiology of the errors, muscle activations were compared to electromyography (EMG) signals, and showed good agreement during level walking. For squatting, however, the muscle activations showed large descrepancies especially for the biceps femoris long head. Errors in the predicted KCF and muscle activation patterns were greatest during deep squat. Hence suggesting that the errors mainly originate from muscle represented at the hip and an associated muscle co-contraction at the knee. Furthermore, there were substaintial differences in the ranking of subjects and activities based on peak KCFs in the simulations versus measurements. Thus, future simulation study designs must account for subject-specific uncertainties in musculoskeletal predictions.

show abstract

Section: Introductionmentioning

confidence: 99%

The Capacity of Generic Musculoskeletal Simulations to Predict Knee Joint Loading Using the CAMS-Knee Datasets

et al. 2020

View full text Add to dashboard Cite

show abstract

“…The predicted muscle activations are compared to the EMG data measured by Winter 44 and Xu et al 45 during a normal walking cycle ( Figure 6). The predicted and measured muscle activations had some similarities.…”

Section: Muscle Activationsmentioning

confidence: 99%

Musculoskeletal multibody dynamics simulation of the contact mechanics and kinematics of a natural knee joint during a walking cycle

Chen

Hua

et al. 2018

Proc Inst Mech Eng H

View full text Add to dashboard Cite

Detailed knowledge of the in vivo loading and kinematics in the knee joint is essential to understand its normal functions and the aetiology of osteoarthritis. Computer models provide a viable non-invasive solution for estimating joint loading and kinematics during different physiological activities. However, the joint loading and kinematics of the tibiofemoral and patellofemoral joints during a gait cycle were not typically investigated concurrently in previous computational simulations. In this study, a natural knee architecture was incorporated into a lower extremity musculoskeletal multibody dynamics model based on a force-dependent kinematics approach to investigate the contact mechanics and kinematics of a natural knee joint during a walking cycle. Specifically, the contact forces between the femoral/tibial articular cartilages and menisci and between the femoral and tibial/patellar articular cartilages were quantified. The contact forces and kinematics of the tibiofemoral and patellofemoral joints and the muscle activations and ligament forces were predicted simultaneously with a reasonable level of accuracy. The developed musculoskeletal multibody dynamics model with a natural knee architecture can serve as a potential platform for assisting clinical decision-making and postoperative rehabilitation planning.

show abstract

“…The differences between the average lengths, obtained without applying the patches, detected at three observation times (3,45,90 minutes of exercise, blue columns), under the different conditions mentioned (Figures 2,3 and 4), show not significant statistically differences. In the graph of Figure 2, it is appreciable a small significant difference in L3, (p> 0.05), between the observation with the patch (red column) and the control (without patch).…”

Section: Resultsmentioning

confidence: 87%

“…The natural physiological activities of the human organism, and animal in general, are mediated by physical fields, which are referable to only four types of fundamental forces: gravitational, electromagnetic, strong and weak nuclear [3].…”

Section: Introductionmentioning

confidence: 99%

Improvement of Postural Reprogramming by a Nanotechnology Device

Summa¹

2018

IJBMR

View full text Add to dashboard Cite

The acquisition by man of the upright posture marks a great achievement in its evolutionary path allowing it to integrate itself more efficiently with the environment in which it finds itself living, both in terms of the individual's ability to face a stressful situation and therefore in the life of relationships, both in terms of movement efficiency and muscle coordination, fine and precise demand in particular sports disciplines. Since it is well known the interaction between electromagnetic field and biological structures, electromagnetic devices that in some way can interact with the electromagnetic field of man may influence and improve some functions of the organism. The purpose of the following work is to demonstrate how the information recorded in a nanotechnology electromagnetic postural devices, can modulate the antigravity muscle tone, thus influencing the posture of the subjects, to whom the devices were applied, evaluating the changes in the pressure center by means of the static stabilometric examination. The postural setting of the subjects, examined before and after the application of nanotechnological devices, was significantly improved. In conclusion, it is possible to hypothesize that the electromagnetic field has generated a rebalancing of ionic exchanges at the level of the cellular plasma membrane, with the consequent repolarization and normalization of the conductivity, which has influenced the activity of the nervous system. The results of this experimental work tend to confirm the potential that quantum physics can reserve in the field of medicine.

show abstract

An Integrated Musculoskeletal-Finite-Element Model to Evaluate Effects of Load Carriage on the Tibia During Walking

Cited by 29 publications

References 47 publications

The Capacity of Generic Musculoskeletal Simulations to Predict Knee Joint Loading Using the CAMS-Knee Datasets

The Capacity of Generic Musculoskeletal Simulations to Predict Knee Joint Loading Using the CAMS-Knee Datasets

Musculoskeletal multibody dynamics simulation of the contact mechanics and kinematics of a natural knee joint during a walking cycle

Improvement of Postural Reprogramming by a Nanotechnology Device

Contact Info

Product

Resources

About