Internal Organization in the Human Jaw Muscles

Hannam, A.G.; McMillan, AS

doi:10.1177/10454411940050010301

Cited by 155 publications

(120 citation statements)

References 138 publications

(166 reference statements)

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“…This hypothesis predicts that variation in strain magnitude will be positively correlated with variation in strain rate, and not with variation in load time, chewing duty factor, or cycle time. Theoretical support for this hypothesis derives from considerations of the consequences of orderly recruitment of motor units, the primary mechanism for force modulation at low force amplitudes during mastication (Goldberg and Derfler, 1977;Hannam and McMillan, 1994;Scutter and Türker, 1998) and locomotion (Fournier and Sieck, 1988;Hennig and Lomo, 1987;Tansey et al, 1996). If the small motor neurons, which innervate small motor units consisting of slow twitch fibers, are recruited first, followed by progressively larger motor neurons and motor units consisting of faster fiber types, then increases in bite force will necessarily be achieved in a constant or decreasing time period.…”

Section: Hypothesesmentioning

confidence: 99%

“…In mammalian masticatory muscles, as in the locomotor muscles, force modulation at low force amplitudes appears to be predominantly via muscle fiber recruitment rather than rate modulation (Goldberg and Derfler, 1977;Hannam and McMillan, 1994;Scutter and Türker, 1998). Mammalian masticatory muscles are not uniform in their fiber types (Anapol and Herring, 2000;Herring, 1994;Maxwell et al, 1979;Wall et al, 2006;Wall et al, 2005), and a large number of studies suggest that smaller, slower motor units are recruited before larger, faster motor units (Clark et al, 1978;Desmedt and Godaux, 1979;Goldberg and Derfler, 1977;LevTov et al, 1993;Lund et al, 1979;Miles and Türker, 1986;Miles et al, 1987;van Eijden and Turkawski, 2001;Van Wessel et al, 2005;Wall et al, 2006;Wall et al, 2005;Yemm, 1977).…”

Section: Rate-modulation Of Bite Forcementioning

confidence: 99%

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Modulation of mandibular loading and bite force in mammals during mastication

Ross

Dharia

Herring

et al. 2007

Journal of Experimental Biology

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SUMMARY Modulation of force during mammalian mastication provides insight into force modulation in rhythmic, cyclic behaviors. This study uses in vivo bone strain data from the mandibular corpus to test two hypotheses regarding bite force modulation during rhythmic mastication in mammals: (1)that bite force is modulated by varying the duration of force production, or(2) that bite force is modulated by varying the rate at which force is produced. The data sample consists of rosette strain data from 40 experiments on 11 species of mammals, including six primate genera and four nonprimate species: goats, pigs, horses and alpacas. Bivariate correlation and multiple regression methods are used to assess relationships between maximum(ϵ1) and minimum (ϵ2) principal strain magnitudes and the following variables: loading time and mean loading rate from 5% of peak to peak strain, unloading time and mean unloading rate from peak to 5% of peak strain, chew cycle duration, and chew duty factor. Bivariate correlations reveal that in the majority of experiments strain magnitudes are significantly (P<0.001) correlated with strain loading and unloading rates and not with strain loading and unloading times. In those cases when strain magnitudes are also correlated with loading times,strain magnitudes are more highly correlated with loading rate than loading time. Multiple regression analyses reveal that variation in strain magnitude is best explained by variation in loading rate. Loading time and related temporal variables (such as overall chew cycle time and chew duty factor) do not explain significant amounts of additional variance. Few and only weak correlations were found between strain magnitude and chew cycle time and chew duty factor. These data suggest that bite force modulation during rhythmic mastication in mammals is mainly achieved by modulating the rate at which force is generated within a chew cycle, and less so by varying temporal parameters. Rate modulation rather than time modulation may allow rhythmic mastication to proceed at a relatively constant frequency, simplifying motor control computation.)

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Section: Hypothesesmentioning

confidence: 99%

Section: Rate-modulation Of Bite Forcementioning

confidence: 99%

Modulation of mandibular loading and bite force in mammals during mastication

Ross

Dharia

Herring

et al. 2007

Journal of Experimental Biology

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“…The masseter muscle shows a very high ATPase activity for contracting very quickly and forcefully participating in a wide variety of functional activities of the stomatognathic system including mastication, swallowing and speech (28,29). This diversity of functions requires coordination of motor output elements of the neuromuscular system with appropriate activation of tongue, facial and oropharyngeal muscles (23).…”

Section: Introductionmentioning

confidence: 99%

Expression of muscle-specific integrins in masseter muscle fibers during malocclusion disease

Cutroneo

Piancino

Ramieri

et al. 2012

International Journal of Molecular Medicine

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Abstract.Integrins are heterodimeric cell surface membrane proteins linking the extracellular matrix to actin. α7B integrin is detected in proliferating and adult myofibers, whereas α7A plays a role in regenerating muscle fibers with a minor function in mature muscle fibers. The expression levels of β1A appear to be very low, whereas β1D appears to be the predominant integrin form in mature muscle. Considering the important features of masseter muscle we have studied integrin expression in masseter muscle specimens of surgical patients with posterior right crossbite and comparing them to left side masseter muscle specimens. Our results showed that the expression of integrins was significantly lower in the crossbite side muscle. Furthermore, the most important finding is that β1A is clearly detectable in adult masseter muscle. This behavior could be due to the particular composition of masseter, since it contains hybrid fibers showing the capacity to modify the contractile properties to optimize the energy efficiency or the action of the muscle during contraction. Moreover, masseter is characterized by a high turnover of muscle fibers producing a regeneration process. This may indicate a longer time to heal, justifying the loss of β1D and the consequential increase of β1A. Thus, our data provide the first suggestion that integrins in masseter muscle play a key role regulating the functional activity of muscle and allowing the optimization of contractile forces.

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“…Van Eijden et ai., 1988) (which themselves are also oversimplified and do not account for their full mechanical effect due to complex internal architecture; Hannam and McMillan, 1994). Due to the spatial anatomic complexity of the masticatory muscles and the dental as well as temporomandibular joint (TMI) surfaces, the mandibular force system can be defined as being non-coplanar and non-concurrent-that is, a system in which the force vectors neither lie in the same plane nor intersect at a unique location.…”

Section: Introductionmentioning

confidence: 99%

Modeling the Mechanical Behavior of the Jaws and Their Related Structures By Finite Element (Fe) Analysis

Korioth

Versluis

1997

Critical Reviews in Oral Biology & Medicine

177

121

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In this paper, we provide a review of mechanical finite element analyses applied to the maxillary and/or mandibular bone with their associated natural and restored structures. It includes a description of the principles and the relevant variables involved, and their critical application to published finite element models ranging from three-dimensional reconstructions of the jaws to detailed investigations on the behavior of natural and restored teeth, as well as basic materials science. The survey revealed that many outstanding FE approaches related to natural and restored dental structures had already been done 10-20 years ago. Several three-dimensional mandibular models are currently available, but a more realistic correlation with physiological chewing and biting tasks is needed. Many FE models lack experimentally derived material properties, sensitivity analyses, or validation attempts, and yield too much significance to their predictive, quantitative outcome. A combination of direct validation and, most importantly, the complete assessment of methodical changes in all relevant variables involved in the modeled system probably indicates a good FE modeling approach. A numerical method for addressing mechanical problems is a powerful contemporary research tool. FE analyses can provide precise insight into the complex mechanical behavior of natural and restored craniofacial structures affected by three-dimensional stress fields which are still very difficult to assess otherwise.

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Internal Organization in the Human Jaw Muscles

Cited by 155 publications

References 138 publications

Modulation of mandibular loading and bite force in mammals during mastication

Modulation of mandibular loading and bite force in mammals during mastication

Expression of muscle-specific integrins in masseter muscle fibers during malocclusion disease

Modeling the Mechanical Behavior of the Jaws and Their Related Structures By Finite Element (Fe) Analysis

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