Your search keyword '"Sagl, Benedikt"' showing total 6 results

1. In vivo prediction of temporomandibular joint disc thickness and position changes for different jaw positions.

Author

Sagl B, Schmid-Schwap M, Piehslinger E, Kronnerwetter C, Kundi M, Trattnig S, and Stavness I

Subjects

Biomechanical Phenomena, Computer Simulation, Female, Humans, Joint Dislocations diagnostic imaging, Magnetic Resonance Imaging methods, Male, Temporomandibular Joint diagnostic imaging, Temporomandibular Joint Disc diagnostic imaging, Tomography, X-Ray Computed methods, Temporomandibular Joint anatomy & histology, Temporomandibular Joint Disc anatomy & histology, Temporomandibular Joint Disorders diagnostic imaging

Abstract

Temporomandibular joint disorders (TMD) are common dysfunctions of the masticatory region and are often linked to dislocation or changes of the temporomandibular joint (TMJ) disc. Magnetic resonance imaging (MRI) is the gold standard for TMJ imaging but standard clinical sequences do not deliver a sufficient resolution and contrast for the creation of detailed meshes of the TMJ disc. Additionally, bony structures cannot be captured appropriately using standard MRI sequences due to their low signal intensity. The objective of this study was to enable researchers to create high resolution representations of all structures of the TMJ and consequently investigate morphological as well as positional changes of the masticatory system. To create meshes of the bony structures, a single computed tomography (CT) scan was acquired. In addition, a high-resolution MRI sequence was produced, which is used to collect the thickness and position change of the disc for various static postures using bite blocks. Changes in thickness of the TMJ disc as well as disc translation were measured. The newly developed workflow successfully allows researchers to create high resolution models of all structures of the TMJ for various static positions, enabling the investigation of TMJ disc translation and deformation. Discs were thinnest in the lateral part and moved mainly anteriorly and slightly medially. The procedure offers the most comprehensive picture of disc positioning and thickness changes reported to date. The presented data can be used for the development of a biomechanical computer model of TMJ anatomy and to investigate dynamic and static loads on the components of the system, which could be useful for the prediction of TMD onset., (© 2019 Anatomical Society.)

Published

2019

2. The effect of tooth cusp morphology and grinding direction on TMJ loading during bruxism.

Author

Sagl, Benedikt, Schmid-Schwap, Martina, Piehslinger, Eva, Xiaohui Rausch-Fan, and Stavness, Ian

Subjects

BRUXISM, SLEEP bruxism, TEMPOROMANDIBULAR joint, MORPHOLOGY, JOINT diseases

Abstract

Increased mechanical loading of the temporomandibular joint (TMJ) is often connected with the onset and progression of temporomandibular joint disorders (TMD). The potential role of occlusal factors and sleep bruxism in the onset of TMD are a highly debated topic in literature, but ethical considerations limit in vivo examinations of this problem. The study aims to use an innovative in silico modeling approach to thoroughly investigate the connection between morphological parameters, bruxing direction and TMJ stress. A forward-dynamics tracking approach was used to simulate laterotrusive and mediotrusive tooth grinding for 3 tooth positions, 5 lateral inclination angles, 5 sagittal tilt angles and 3 force levels, giving a total of 450 simulations. Muscle activation patterns, TMJ disc von Mises stress as well as correlations between mean muscle activations and TMJ disc stress are reported. Computed muscle activation patterns agree well with previous literature. The results suggest that tooth inclination and grinding position, to a smaller degree, have an effect on TMJ loading. Mediotrusive bruxing computed higher loads compared to laterotrusive simulations. The strongest correlation was found for TMJ stress and mean activation of the superficial masseter. Overall, our results provide in silico evidence that TMJ disc stress is related to tooth morphology. [ABSTRACT FROM AUTHOR]

Published

2022

3. Effect of facet inclination and location on TMJ loading during bruxism: An in-silico study.

Author

Sagl, Benedikt, Schmid-Schwap, Martina, Piehslinger, Eva, Kundi, Michael, and Stavness, Ian

Subjects

*BRUXISM, *MOLARS, *TEMPOROMANDIBULAR disorders, *TEMPOROMANDIBULAR joint, *MASTICATORY muscles, *COMPUTER simulation, *STRAINS & stresses (Mechanics)

Abstract

[Display omitted] • Sheds new light on the important potential connection between tooth grinding and temporomandibular joint loading • Demonstrates a larger effect of grinding inclination than grinding position on TMJ loading • Creates a novel computer simulation of TMJ disc stress during dynamic tooth grinding tasks • Uses state-of-the-art in silico methods for a highly multidisciplinary investigation, which is not feasible in vivo • Presents a tracking simulation approach to work around the highly complicated recording of masticatory muscle EMG acquisition Functional impairment of the masticatory region can have significant consequences that range from a loss of quality of life to severe health issues. Increased temporomandibular joint loading is often connected with temporomandibular disorders, but the effect of morphological factors on joint loading is a heavily discussed topic. Due to the small size and complex structure of the masticatory region in vivo investigations of these connections are difficult to perform. We propose a novel in silico approach for the investigation of the effect of wear facet inclination and position on TMJ stress. We use a forward-dynamics tracking approach to simulate lateral bruxing on the canine and first molar using 6 different inclinations, resulting in a total of 12 simulated cases. By using a computational model, we control a single variable without interfering with the system. Muscle activation pattern, maximum bruxing force as well as TMJ disc stress are reported for all simulations. Muscle activation patterns and bruxing forces agree well with previously reported EMG findings and in vivo force measurements. The simulation results show that an increase in inclination leads to a decrease in TMJ loading. Wear facet position seems to play a smaller role with regard to bruxing force but might be more relevant for TMJ loading. Together these results suggest a possible effect of tooth morphology on TMJ loading during bruxism. [ABSTRACT FROM AUTHOR]

Published

2022

4. The effect of bolus properties on muscle activation patterns and TMJ loading during unilateral chewing.

Author

Sagl, Benedikt, Schmid-Schwap, Martina, Piehslinger, Eva, Yao, Hai, Rausch-Fan, Xiaohui, and Stavness, Ian

Subjects

BOLUS (Digestion), TEMPOROMANDIBULAR joint, MASTICATION, STRAINS & stresses (Mechanics), TEMPORALIS muscle, MASSETER muscle, TEMPOROMANDIBULAR disorders

Abstract

Mastication is a vital human function and uses an intricate coordination of muscle activation to break down food. Collection of detailed muscle activation patterns is complex and commonly only masseter and anterior temporalis muscle activation are recorded. Chewing is the orofacial task with the highest muscle forces, potentially leading to high temporomandibular joint (TMJ) loading. Increased TMJ loading is often associated with the onset and progression of temporomandibular disorders (TMD). Hence, studying TMJ mechanical stress during mastication is a central task. Current TMD self-management guidelines suggest eating small and soft pieces of food, but patient safety concerns inhibit in vivo investigations of TMJ biomechanics and currently no in silico model of muscle recruitment and TMJ biomechanics during chewing exists. For this purpose, we have developed a state-of-the-art in silico model, combining rigid body bones, finite element TMJ discs and line actuator muscles. To solve the problems regarding muscle activation measurement, we used a forward dynamics tracking approach, optimizing muscle activations driven by mandibular motion. We include a total of 256 different combinations of food bolus size, stiffness and position in our study and report kinematics, muscle activation patterns and TMJ disc von Mises stress. Computed mandibular kinematics agree well with previous measurements. The computed muscle activation pattern stayed stable over all simulations, with changes to the magnitude relative to stiffness and size of the bolus. Our biomedical simulation results agree with the clinical guidelines regarding bolus modifications as smaller and softer food boluses lead to less TMJ loading. The computed mechanical stress results help to strengthen the confidence in TMD self-management recommendations of eating soft and small pieces of food to reduce TMJ pain. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

5. A Dynamic Jaw Model With a Finite-Element Temporomandibular Joint.

Author

Sagl, Benedikt, Schmid-Schwap, Martina, Piehslinger, Eva, Kundi, Michael, and Stavness, Ian

Subjects

TEMPOROMANDIBULAR joint, DYNAMIC models, BIOCOMPUTERS, ELASTIC foundations, ARTICULAR cartilage

Abstract

The masticatory region is an important human motion system that is essential for basic human tasks like mastication, speech or swallowing. An association between temporomandibular disorders (TMDs) and high temporomandibular joint (TMJ) stress has been suggested, but in vivo joint force measurements are not feasible to directly test this assumption. Consequently, biomechanical computer simulation remains as one of a few means to investigate this complex system. To thoroughly examine orofacial biomechanics, we developed a novel, dynamic computer model of the masticatory system. The model combines a muscle driven rigid body model of the jaw region with a detailed finite element model (FEM) disk and elastic foundation (EF) articular cartilage. The model is validated using high-resolution MRI data for protrusion and opening that were collected from the same volunteer. Joint stresses for a clenching task as well as protrusive and opening movements are computed. Simulations resulted in mandibular positions as well as disk positions and shapes that agree well with the MRI data. The model computes reasonable disk stress patterns for dynamic tasks. Moreover, to the best of our knowledge this model presents the first ever contact model using a combination of EF layers and a FEM body, which results in a clear decrease in computation time. In conclusion, the presented model is a valuable tool for the investigation of the human TMJ and can potentially help in the future to increase the understanding of the masticatory system and the relationship between TMD and joint stress and to highlight potential therapeutic approaches for the restoration of orofacial function. [ABSTRACT FROM AUTHOR]

Published

2019

6. An in silico investigation of the effect of bolus properties on TMJ loading during mastication.

Author

Sagl, Benedikt, Schmid-Schwap, Martina, Piehslinger, Eva, Rausch-Fan, Xiaohui, and Stavness, Ian

Subjects

MASTICATION, BOLUS (Digestion), TEMPOROMANDIBULAR joint, TEMPOROMANDIBULAR disorders, COMPUTER simulation, PATIENT safety, BRUXISM

Abstract

Mastication is the motor task with the highest muscle activations of the jaw region, potentially leading to high temporomandibular joint (TMJ) loading. Since increased loading of the TMJ is associated with temporomandibular disorders (TMD), TMJ mechanics during chewing has potential clinical relevance in TMD treatment. TMD self-management guidelines suggest eating soft and small pieces of food to reduce TMJ pain. Since TMJ loading cannot be measured in vivo , due to patient safety restrictions, computer modeling is an important tool for investigations of the potential connection between TMJ loading and TMD. The objective of this study is to investigate the effect of food bolus variables on mechanical TMJ loading to help inform better self-management guidelines for TMD. A combined rigid-body-finite-element model of the jaw region was used to investigate the effect of bolus size, stiffness, and position. Mandibular motion and TMJ disc von Mises stress were reported. Computed mandibular motion generally agrees well with previous literature. Disc stress was higher during the closing phase of the chewing cycle and for the non-working side disc. Smaller and softer food boluses overall lead to less TMJ loading. The results reinforce current guidelines regarding bolus modifications and provide new potential guidelines for bolus positioning that could be verified through a future clinical trial. The paper presents a first in silico investigation of dynamic chewing with detailed TMJ stress for different bolus properties. The results help to strengthen the confidence in TMD self-management recommendations, potentially reducing pain levels of patients. [ABSTRACT FROM AUTHOR]

Published

2021