Sage Journals: Discover world-class research

Abstract

Objective

The influence of gravity on the velopharyngeal structures in children is unknown. The purpose of this study is to compare the velopharyngeal mechanism in the upright and supine positions while at rest and during sustained speech production in children between 4 and 8 years old.

Methods

A 0.6 Tesla open-type, multipositional magnetic resonance imaging scanner was used to image subjects in the upright and supine positions. The scanning protocol included a T2 fluid attenuation inversion recovery and an oblique coronal turbo spin echo scan with short scanning durations (7.9 seconds) to enable visualization of the velopharyngeal anatomy during rest and production of sustained /i/ and /s/.

Results

The magnetic resonance imaging protocol used for this study enabled successful visualization of the velopharyngeal anatomy in the sagittal and oblique coronal planes at rest and during sustained phonation of /i/ and /s/. Positional differences demonstrated a small nonsignificant (P > .05) variation for velar measures (length, thickness, and height), retrovelar space, and levator veli palatini measures (length and angles of origin).

Conclusions

Gravity had a negligible effect on velar length, velar thickness, velar height, retrovelar space, levator muscle length, and levator angles of origin. Supine imaging data can be translated to an upright activity such as speech. This is the first study to provide normative levator muscle lengths for children between 4 and 8 years old. Upright imaging may be a promising tool for difficult-to-test populations.

Keywords

children levator MRI upright and supine imaging velopharyngeal mechanism

Get full access to this article

View all access options for this article.

References

Badin

, Bailly

, Revéret

, Bacin

, Segebarth

, Savariaux

Three-dimensional linear articulatory modeling of tongue, lips, and face based on MRI and video images. J Phon. 2002; 30: 533–553.

Buchaillard

, Perrier

A biomechanical model of cardinal vowel production: muscle activations and the impact of gravity on tongue positioning. J Acoust Soc Am. 2009; 126: 2033–2051.

Ettema

S.L.

, Kuehn

D.P.

, Perlman

A.L.

, Alperin

Magnetic resonance imaging of the levator veli palatini muscle during speech. Cleft Palate Craniofac J. 2002; 39: 130–144.

Hoit

Influence of body position on breathing and its implications for the evaluation and treatment of speech and voice disorders. J Voice. 1994; 09: 341–347.

Ingman

, Nieminen

, Hurmerinta

Cephalometric comparison of pharyngeal changes in subjects with upper airway resistance syndrome or obstructive sleep apnea in upright and supine positions. Eur J Orthod. 2004; 26: 321–326.

Kitamura

, Takemoto

, Honda

, Shimada

, Fujimoto

Difference in vocal tract shape between upright and supine postures: observations by an open-type MRI scanner. Acoust Sci Technol. 2005; 26: 465–468.

Kuehn

D.P.

, Ettema

S.L.

, Goldwasser

M.S.

, Barkmeier

J.C.

Magnetic resonance imaging of the levator veli palatini muscle before and after primary palatoplasty. Cleft Palate Craniofac J. 2004; 41: 584–592.

Kuehn

D.P.

, Ettema

S.L.

, Goldwasser

M.S.

, Barkmeier

J.C.

, Wachtel

J.M.

Magnetic resonance imaging in the evaluation of occult submucous cleft palate. Cleft Palate Craniofac J. 2000; 38: 421–431.

Moon

, Canady

Effects of gravity on velopharyngeal muscle activity during speech. Cleft Palate Craniofac J. 1995; 32: 371–375.

10.

Perry

J.L.

Anatomy and physiology of the velopharyngeal mechanism. Semin Speech Lang. 2011a; 32: 83–92.

11.

Perry

J.L.

Variations in velopharyngeal structures between upright and supine positions using upright magnetic resonance imaging. Cleft Palate Craniofac J. 2011b; 48: 123–133.

12.

Perry

J.L.

, Bae

, Kuehn

D.P.

Effect of posture on deglutitive biomechanics in healthy individuals. Dysphagia. 2012; 27: 70–80.

13.

Perry

J.L.

, Kuehn

, Sutton

, Gamage

Anthropometric analysis of the velopharynx and related craniometric dimensions in three adult populations using MRI. Cleft Palate Craniofac J. 2013 in press.

14.

Perry

J.L.

, Kuehn

D.P.

, Sutton

B.P.

, Goldwasser

M.S.

, Jerez

A.D.

Craniometric and velopharyngeal assessment of infants with and without cleft palate. J Craniofac Surg. 2011; 22: 499–503.

15.

Stone

, Stock

, Bunin

, Kumar

, Epstein

Comparison of speech production in the upright and supine position. J Acoust Soc Am. 2007; 122: 532–541.

16.

Sutthiprapaporn

, Tanimoto

, Ohtsuka

, Nagasaki

, Lida

, Katsumata

Positional changes of oropharyngeal structures due to gravity in the upright and supine positions. Dentomaxillofac Radiol. 2008; 37: 130–136.

17.

Tian

, Yin

, Li

, Zhao

, Zheng

, Shi

Magnetic resonance imaging assessment of velopharyngeal structures in Chinese children after primary palatal repair. J Craniofac Surg. 2010a; 21: 568–577.

18.

Tian

, Yin

, Redett

Magnetic resonance imaging assessment of the velopharyngeal mechanism at rest and during speech in Chinese adults and children. J Speech Lang Hear Res. 2010b; 53: 1595–1615.

Effects of Gravity on the Velopharyngeal Structures in Children Using Upright Magnetic Resonance Imaging

Abstract

Objective

Methods

Results

Conclusions

Keywords

Get full access to this article

References