Your search keyword '"Rues S"' showing total 6 results

1. Muscle and joint forces under variable equilibrium states of the mandible.

Author

Rues S, Lenz J, Türp JC, Schweizerhof K, and Schindler HJ

Subjects

Adaptation, Physiological physiology, Adult, Bicuspid physiology, Biomechanical Phenomena, Computer Simulation, Cuspid physiology, Dental Arch physiology, Electromyography, Feedback, Physiological physiology, Humans, Male, Masseter Muscle physiology, Models, Biological, Molar physiology, Muscle Strength physiology, Neck Muscles physiology, Pterygoid Muscles physiology, Temporal Muscle physiology, Tooth Loss physiopathology, Weight-Bearing physiology, Young Adult, Bite Force, Mandible physiology, Masticatory Muscles physiology, Temporomandibular Joint physiology, Tooth physiology

Abstract

It is well established that subjects without molars have reduced ability to comminute foods. However, epidemiological studies have indicated that the masticatory system is able to functionally adapt to the absence of posterior teeth. This supports the shortened dental arch concept which, as a prosthetic option, recommends no replacement of missing molars. Biomechanical modeling, however, indicates that using more anterior teeth will result in a larger temporomandibular joint load per unit of bite force. In contrast, changing bite from incisor to molar position increases the maximum possible bite force and reduces joint loads. There have been few attempts, however, to determine realistic joint loads and corresponding muscular effort during generation of occlusal forces similar to those used during chewing with intact or shortened dental arches. Therefore, joint and cumulative muscle loads generated by vertical bite forces of submaximum magnitude moving from canine to molar region, were calculated. Calculations were based on intraoral measurement of the feedback-controlled resultant bite force, simultaneous electromyograms, individual geometrical data of the skull, lines of action, and physiological cross-sectional areas of all jaw muscles. Compared to premolar and canine biting, bilateral and unilateral molar bites reduced cumulative muscle and joint loads in a range from 14% to 33% and 25% to 53%, respectively. During unilateral molar bites, the ipsilateral joints and contralateral muscles were about 20% less loaded than the opposing ones. In conclusion, unilateral or bilateral molar biting at chewing-like force ranges caused the least muscle and joint loading.

Published

2011

2. Influence of neck rotation and neck lateroflexion on mandibular equilibrium.

Author

Schindler HJ, Lenz J, Türp JC, Schweizerhof K, and Rues S

Subjects

Adult, Analysis of Variance, Biomechanical Phenomena, Dental Stress Analysis, Electromyography, Humans, Isometric Contraction, Male, Pliability, Posture, Torsion, Mechanical, Young Adult, Bite Force, Masticatory Muscles physiology, Neck Muscles physiology

Abstract

Neuromuscular interaction between neck and jaw muscles has been reported in several studies. However, the influence of experimentally modified posture of the neck on jaw muscle activity during isometric biting was not investigated so far. The aim of the present study was to test by the aid of simultaneous electromyographic and intraoral bite force measurements whether neck rotation and lateroflexion, in contrast to a straightforward neck position, change the isometric cocontraction patterns of masticatory muscles under identical submaximum bite forces of 50-200 N. Electric muscle activity of all masticatory muscles and changes of the reduction point (RP) of the resultant bite force vectors were examined. An anteroposterior displacement of the RPs could be observed for the rotated and lateroflexed neck position in comparison with the straightforward position. On the other hand, the results revealed no significant differences between bilateral muscle activation under the different test conditions. These findings suggest a force transmission between the neck and the masticatory system, but no essential activity changes in the masticatory muscles under short time posture modification of the neck.

Published

2010

3. Small unilateral jaw gap variations: equilibrium changes, co-contractions and joint forces.

Author

Schindler HJ, Lenz J, Türp JC, Schweizerhof K, and Rues S

Subjects

Adult, Analysis of Variance, Biomechanical Phenomena, Dental Prosthesis adverse effects, Dental Stress Analysis methods, Electromyography, Humans, Male, Malocclusion, Angle Class I physiopathology, Malocclusion, Angle Class II physiopathology, Young Adult, Bite Force, Masticatory Muscles physiology, Temporomandibular Joint physiology

Abstract

After complex prosthetic reconstructions, small differences in vertical distances between the left and right side of the jaw may occur during jaw closing, nevertheless providing bilateral tooth contacts in intercuspation by small deformations of the mandible. Their effects on the co-contraction of the masticatory muscles, the temporomandibular joint reaction forces, and the point of application of the resultant bite force vector in the maxillary occlusion plane - the so-called reduction point - have not been investigated, thus far simultaneously in one sample. The main goal of this study was to investigate variations of these measures in an experimental intercuspation simulated by one anterior and two posterior force transmission points.

Published

2009

4. Motor behavior of the jaw muscles during different clenching levels.

Author

Rues S, Schindler HJ, Türp JC, Schweizerhof K, and Lenz J

Subjects

Adult, Analysis of Variance, Biomechanical Phenomena, Dental Stress Analysis, Electrodes, Electromyography, Humans, Male, Motor Neurons physiology, Muscle Contraction, Neck Muscles physiology, Recruitment, Neurophysiological physiology, Signal Processing, Computer-Assisted, Transducers, Bite Force, Mastication physiology, Masticatory Muscles physiology, Temporomandibular Joint physiology

Abstract

The goals of this study were to investigate whether (i) muscle activities are affected by different feedback strategies, (ii) the balancing behavior of the neuromuscular system is influenced by different force levels, and (iii) axial loading of the posterior teeth is a realistic biomechanical conception. In 10 healthy subjects, all jaw muscles were recorded bilaterally. Intra-oral force transfer and force measurement were achieved by using a measuring device simulating natural maximum intercuspation. Under visual feedback-control, the subjects generated pure vertical and directionally unrestricted force vectors with identical force magnitude at different force levels. The force transmission characteristics under experimental occlusion were investigated by calculating the reduction point (RP) of the resultant bite force. Directionally unrestricted clenching revealed a higher activation of the musculature than pure vertical clenching and was also characterized by a distinct anterior force component. Under both test conditions, the RP moved towards a posterior position with increasing clenching forces. The results indicate an essential recruitment difference of the jaw muscles between the two clenching conditions. Pure axial loading of teeth seems to be impeded by the anterior force component during bilateral clenching. The posterior movement of the RP might prevent overloading of the temporomandibular joints and anterior teeth.

Published

2008

5. Jaw clenching: muscle and joint forces, optimization strategies.

Author

Schindler HJ, Rues S, Türp JC, Schweizerhof K, and Lenz J

Subjects

Adult, Analysis of Variance, Biofeedback, Psychology physiology, Elasticity, Electromyography, Humans, Male, Bite Force, Dental Stress Analysis, Masticatory Muscles physiology, Muscle Contraction physiology, Temporomandibular Joint physiology

Abstract

Realistic masticatory muscle and temporomandibular joint forces generated during bilateral jaw clenching are largely unknown. To determine which clenching directions load masticatory muscles and temporomandibular joints most heavily, we investigated muscle and joint forces based on feedback-controlled electromyograms of all jaw muscles, lines of action, geometrical data from the skull, and physiological cross-sectional areas acquired from the same individuals. To identify possible motor control strategies, we applied objective functions. The medial pterygoid turned out to be the most heavily loaded muscle for all bite directions. Biting with accentuated horizontal force components provoked the highest loading within the medial and lateral pterygoids. The largest joint forces were also found for these bite directions. Conversely, the lowest joint forces were detected during vertical biting. Additionally, joint forces with a clear posterior orientation were found. Optimization strategies with the elastic energy as objective function revealed the best fit with the calculated results.

Published

2007

6. Activity patterns of the masticatory muscles during feedback-controlled simulated clenching activities.

Author

Schindler HJ, Rues S, Türp JC, Schweizerhof K, and Lenz J

Subjects

Adult, Analysis of Variance, Biomechanical Phenomena, Dental Stress Analysis, Electromyography, Feedback, Functional Laterality physiology, Humans, Male, Reference Values, Bite Force, Masticatory Muscles physiology, Muscle Contraction physiology, Muscle Strength physiology

Abstract

In 10 normal subjects, the electromyographic (EMG) activities of the masseter, anterior and posterior temporalis, medial pterygoid, inferior lateral pterygoid, as well as the anterior digastric, were bilaterally recorded during clenching with various resulting force vectors. The intraoral force transfer was achieved with a three-component force transducer. The direction and magnitude of the force vectors were controlled by visual feedback. The goal of the study was to investigate how various clenching directions at constant magnitude of force influence the EMG activity in the masticatory muscles during gradual increase of the horizontal force component. Depending on the force direction and the individual muscle, an increase or decrease of activity was observed during clenching with increasing horizontal force components at constant magnitude of force. The inferior lateral pterygoid exhibited the highest activation (about 80% of maximal voluntary clenching) of all masticatory muscles. The medial pterygoid showed the greatest range of variation in activation behavior, and it was the most active muscle in relation to all clenching directions. In conclusion, the results show that with growing horizontal force components at constant magnitude of force, all muscles demonstrated an increase or decrease of activity in several clenching directions.

Published

2005