* Zobrazit nápovědu

Reset

MeSH: Masticatory Muscles-physiology

8 záznamů v Medvik Filtry

Článek

Implantáty v protetické funkci

Quintessenz. 2018 ; 27 (6) : 53-62.

Quintessenz (Praha)
ISSN 1210-017X
Medvik
Zdroj

Článek

The influence of the human TMJ eminence inclination on predicted masticatory muscle forces

Marková, Michala
Autor Marková, Michala Clinic of Masticatory Disorders, Removable Prosthodontics, Geriatric and Special Care Dentistry, University of Zürich, Plattenstrasse 11, 8032 Zürich, Switzerland Laboratory of Biomechanics, Department of Mechanics, Biomechanics and Mechatronics, Faculty of Mechanical Engineering, Czech Technical University in Prague, Technická 4, 16607 Prague 6, Czech Republic. Electronic address: Michala.Markova@zzm.uzh.ch
Gallo, Luigi M
Autor Gallo, Luigi M Clinic of Masticatory Disorders, Removable Prosthodontics, Geriatric and Special Care Dentistry, University of Zürich, Plattenstrasse 11, 8032 Zürich, Switzerland. Electronic address: luigi.gallo@zzm.uzh.ch

Human movement science. 2016 ; 49 (-) : 132-40. [pub] 20160701

Hum Mov Sci
ISSN 1872-7646
Medvik
Zdroj

Aim of this paper was to investigate the change in masticatory muscle forces and temporomandibular joint (TMJ) reaction forces simulated by inverse dynamics when thesteepness of the anterior fossa slope was varied. We used the model by de Zee et al. (2007) created in AnyBody™. The model was equipped with 24musculotendon actuators. Mandibular movement was governed by thetrajectory of theincisal point. The TMJ was modelled as a planar constraint canted 5°medially and thecaudal inclination relative to the occlusal plane was varied from 10° to 70°. Our models showed that for the two simulated movements (empty chewing and unilateral clenching) the joint reaction forces were smallest for the eminence inclination of 30° and 40° and highest for 70°. The muscle forces were relatively insensitive to change of the eminence inclination for the angles between 20° and 50°. This did not hold for the pterygoid muscle, for which the muscle forces increased continually with increasing fossa inclination. For empty chewing the muscle force reached smaller values than for clenching. During clenching, the muscle forces changed by up to 200N.

MeSH
dospělí MeSH
lidé MeSH
magnetická rezonanční tomografie MeSH
mandibula anatomie a histologie fyziologie MeSH
musculus pterygoideus fyziologie MeSH
počítačová rentgenová tomografie MeSH
síla skusu * MeSH
temporomandibulární kloub anatomie a histologie fyziologie MeSH
zubní modely MeSH
žvýkací svaly fyziologie MeSH
Check Tag
dospělí MeSH
lidé MeSH
mužské pohlaví MeSH
Publikační typ
časopisecké články MeSH

Článek online

Force ratio in masticatory muscles after total replacement of the temporomandibular joint

Acta of Bioengineering and Biomechanics. 2016 ; 18 (3) : 131-136.

Acta Bioeng Biomech
ISSN 1509-409X
Medvik
Zdroj

The temporomandibular (TM) joint is one of the most active joints in the human body, and any defect in this joint has a significant impact on the quality of life. The objective of this study was to analyze changes in the force ratio after TM joint replacement on contralateral TM joint loading. Implantation of an artificial TM joint often requires removal of 3 of the 4 masticatory muscles (activators). In order to perform true loading of the TM joint, loading during mastication was investigated. Input kinematic variables and mastication force were experimentally examined. The inverse dynamics approach and static optimization technique were used for solution of the redundant mechanism. Muscle forces, and reactions in the TM joint were calculated. We modified the model for several different tasks. The m. temporalis and m. masseter were removed individually and together and the forces of mastication on the TM joint were calculated for each variation. To evaluate the results, a parametric numerical FE analysis was created to compare the magnitude of the TM joint loading during the bite process for four different muscle resections. The results show an influence relative to the extent of muscle resection on contralateral TM joint loading in a total TM joint replacement. The biggest increase in the loading magnitude on the contralateral TM joint is most evident after m. masseter and m. temporalis resection. The results from all simulations support our hypothesis that the greater the extent of muscle resection the greater the magnitude of contralateral TM joint overloading.

MeSH
biomechanika MeSH
lidé MeSH
pohyb MeSH
temporomandibulární kloub fyziologie MeSH
žvýkací svaly fyziologie MeSH
žvýkání fyziologie MeSH
Check Tag
lidé MeSH
Publikační typ
časopisecké články MeSH

Článek online

Experimentální využití MRI - dat v detekci a simulaci myoskeletálních dysfunkcí
[Experimental implementation of MRI data in detection and simulation of myoskeletal dysfunction]

Rehabilitácia. 2005 ; Roč. 42 (č. 2) : s. 73-80.

ISSN 0375-0922
Medvik
Zdroj

Autoři článku chtějí touto cestou informovat širokou odbornou veřejnost o nestandardní možností využití magnetické rezonance (MRI) v detekci a simulaci myoskeletálních dysfunkci. Tato metoda se pro zobrazení morfologie i funkce začala hojně využívat od roku 1990 díky rychlým zobrazovacím sekvencím a rozvoji tzv. funkční, phase-contrast-MRI nebo cine-MRI. V této době se začala morfologická data využívat také v oblasti biomedicínského modelování (kinematiká svalů a kloubů). Prezentované studie si kladou za cíl objektivizovat a modelovat situace, se kterými se setkáváme v běžné klinické praxi (konkrétně dysfunkce svalů v oblasti pánve či temporomandibulámího kloubu). Tyto stavy jsou výsledkem změn mechanických poměrů v měkkých tkáních. Experimentální soubor tvoří subjekty, u nichž klinické vyšetření neprokázalo přítomnost patologických zrněn v dané oblasti. Pro detekci tvarových změn jsme zvolili dva hlavní přístupy. V prvním případě sledujeme dva stavy pomocí MRI. Podstatou je intraindividuální srovnání stavu před a po nastalé změně (stav fyziologický a patologický). Druhým přístupem je využití MRI dat jako vstupních parametrů pro simulaci myoskeletálních dysfunkcí pomocí matematického modelování. Potřeba jednoduchého zpracování MRI snímků v trojdimenziálním prostoru nás vedla k vytvoření speciálních postupů v programu MANUAL MATCHING (SCAN VIEW), v 3D CAD systému EDS/UNIGRAPHICS NX2 a v neposlední řadě k využití programu TRANSFER. Tyto softwarové programy umožňují velice rychlou a precisní interpretaci snímané oblasti a interaktivní aplikace v 3D prostoru. Dílčím výstupem našich experimentů je nalezení optimální sekvence MRI, ve které by měkké struktury byly ve vzájemně vysokém kontrastu (TI TFE, SS Imm). V této sekvenci lze snímat po Imm, což se jeví jako optimální vzhledem k přesnosti rozlišení.

Authors of the paper want inform broad spectrum of health professionals, as well as general public audience, about non standard application of MRI in detection and simulation of musculoskeletal dysfunction. This method has been frequently used for imaging of the function, as well as the structure, since 1990 due to fast imaging sequences and also thanks to development of functional phase-contrast-MRI or cine ñ MRI. At this time there has been also use of these morphological data in the area of biomedical simulation (kinematics of the muscles and joints). Presented papers claim to objectify and simulate situations, which we can frequently meet at everyday routine clinical practice (especially muscle dysfunction of the pelvic area or TMJ). These statuses are the results of mechanical changes in soft tissues. Experimental set is composed of subjects, whose clinical examination did not proof presence of any pathological changes. For detection of structural changes we have chosen two principal approaches. In the first case we monitor the status before and after intervention using MRI. The substance of this process is intraindividual comparison of two states (before and after the change, status physiological and pathological). Second approach is the use of data gained from MRI examination, as enter data for simulation of mathematical models of musculoskeletal dysfunction. Need of simple evaluation of the MRI scans in 3D environment has lead us to creation of the Special programs MANUAL MATCHING (SCAN VIEW) in 3D CAD system EDS/UNIGRAPHICS NX2 as well as using the program TRANSFER. These software programs enable very fast and precise interpretation of scanned area and interactive applications in 3D dimension. Partial outcome of our experiments is to find optimal sequence of MRI where desired structures would be in required contrast (T1 TFE, SS 1mm). In this sequence you can scan layers after 1mm what is optimal for high definition.