A Biomechanical Modeling Study of the Effects of the Orbicularis Oris Muscle and Jaw Posture on Lip Shape

Stavness, Ian; Nazari, Mohammad Ali; Perrier, Michel; Demolin, Didier

doi:10.1044/1092-4388(2012/12-0200)

Cited by 38 publications

(20 citation statements)

References 22 publications

(32 reference statements)

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“…The idea that human vocal tract variation biases phonological systems has been around for a long time (e.g., Vendryès 1902;Meillet 1937;Darlington 1947;Zipf 1949;Brosnahan 1961;Allott 1994), but, given the incredible causal complexity behind the organization of phonological systems, coupled with the perceived potential racist connotations, substantial proof has been wanting. Recent developments in vocal tract imaging, large scale typological data analysis, and biomechanical modeling suggest that a revisitation of this hypothesis is warranted (e.g., Stavness et al 2013;Dediu et al 2017), especially as more data are emerging which show that individual differences in phonetic behavior are linked with anatomical variation (Brunner et al 2009;Weirich & Fuchs 2011;Stone et al 2012).…”

Section: Vocal Tract Variation and Sound Changementioning

confidence: 99%

Pushes and pulls from below: Anatomical variation, articulation and sound change

Dediu

Moisik

2019

Glossa: A Journal of General Linguistics

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This paper argues that inter-individual and inter-group variation in language acquisition, perception, processing and production, rooted in our biology, may play a largely neglected role in sound change. We begin by discussing the patterning of these differences, highlighting those related to vocal tract anatomy with a foundation in genetics and development. We use our ArtiVarK database, a large multi-ethnic sample comprising 3D intraoral optical scans, as well as structural, static and real-time MRI scans of vocal tract anatomy and speech articulation, to quantify the articulatory strategies used to produce the North American English /r/ and to statistically show that anatomical factors seem to influence these articulatory strategies. Building on work showing that these alternative articulatory strategies may have indirect coarticulatory effects, we propose two models for how biases due to variation in vocal tract anatomy may affect sound change. The first involves direct overt acoustic effects of such biases that are then reinterpreted by the hearers, while the second is based on indirect coarticulatory phenomena generated by acoustically covert biases that produce overt "at-a-distance" acoustic effects. This view implies that speaker communities might be "poised" for change because they always contain pools of "standing variation" of such biased speakers, and when factors such as the frequency of the biased speakers in the community, their positions in the communicative network or the topology of the network itself change, sound change may rapidly follow as a self-reinforcing network-level phenomenon, akin to a phase transition. Thus, inter-speaker variation in structured and dynamic communicative networks may couple the initiation and actuation of sound change.

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Section: Vocal Tract Variation and Sound Changementioning

confidence: 99%

Pushes and pulls from below: Anatomical variation, articulation and sound change

Dediu

Moisik

2019

Glossa: A Journal of General Linguistics

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“…Functional prediction using virtual surgery is complex and involves several aspects of patient-specific anatomical geometry, biomechanical tissue properties, branching and distribution pattern of the nervous system and the muscle activation signals that control a particular function. Biomechanical modelling, including the muscular system, in the oral and oropharyngeal region, has been the subject of ongoing research [10, 16, 18, 23]. …”

Section: Introductionmentioning

confidence: 99%

Predicting 3D lip movement using facial sEMG: a first step towards estimating functional and aesthetic outcome of oral cancer surgery

Eskes

Alphen

Smeele

et al. 2016

Med Biol Eng Comput

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In oral cancer, loss of function due to surgery can be unacceptable, designating the tumour as functionally inoperable. Other curative treatments can then be considered. Currently, predictions of these functional consequences are subjective and unreliable. We want to create patient-specific models to improve and objectify these predictions. A first step was taken by controlling a 3D lip model with volunteer-specific sEMG activities. We focus on the lips first, because they are essential for speech, oral food transport, and facial mimicry. Besides, they are more accessible to measurements than intraoral organs. 3D lip movement and corresponding sEMG activities are measured in five healthy volunteers, who performed 19 instructions repeatedly, to create a quantitative lip model by establishing the relationship between sEMG activities of eight facial muscles bilaterally on the input side and the corresponding 3D lip displacements on the output side. The relationship between 3D lip movement and sEMG activities was accommodated in a state-space model. A good relationship between sEMG activities and 3D lip movement was established with an average root mean square error of 2.43 mm for the first-order system and 2.46 mm for the second-order system. This information can be incorporated into biomechanical models to further personalise functional outcome assessment after treatment.

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“…An additional isochoric term is included in the strain energy function, to account for lateral normal stiffness. Figure 5 illustrates such muscle action with the deformations induced by the activation of the orbicularis oris peripheral muscle which is a sphincter muscle running around the lips and responsible for lip protrusion (Nazari et al, 2011b ;Stavness et al, 2013)). The idea is to use such a model to predict the aesthetic and functional consequences of maxillary and mandible bone repositioning.…”

Section: 2mentioning

confidence: 99%

Soft Tissue Finite Element Modeling and Calibration of the Material Properties in the Context of Computer-Assisted Medical Interventions

Payan

2016

Material Parameter Identification and Inverse Problems in Soft Tissue Biomechanics

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International audienceThis chapter aims at illustrating how patient-specific models of human organs / soft tissues can be implemented into Finite Element (FE) packages. First is addressed the question of the generation of patient-specific FE models compatible with the clinical constraints. Then is discussed the calibration of the material properties, with choices that should be done between calibrations based on ex vivo or in vivo tissues loadings. The example of computer assisted maxillofacial surgery is addressed and results based on patients' data are provided

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A Biomechanical Modeling Study of the Effects of the Orbicularis Oris Muscle and Jaw Posture on Lip Shape

Cited by 38 publications

References 22 publications

Pushes and pulls from below: Anatomical variation, articulation and sound change

Pushes and pulls from below: Anatomical variation, articulation and sound change

Predicting 3D lip movement using facial sEMG: a first step towards estimating functional and aesthetic outcome of oral cancer surgery

Soft Tissue Finite Element Modeling and Calibration of the Material Properties in the Context of Computer-Assisted Medical Interventions

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