Advertisement
Research Article| Volume 33, ISSUE 5, P611-619, September 2019

Quantitative Measurement of the Three-dimensional Structure of the Vocal Folds and Its Application in Identifying the Type of Cricoarytenoid Joint Dislocation

Published:August 23, 2018DOI:https://doi.org/10.1016/j.jvoice.2018.02.024
Quantitative Measurement of the Three-dimensional Structure of the Vocal Folds and Its Application in Identifying the Type of Cricoarytenoid Joint Dislocation
Previous ArticleThe Effects of Stress Type, Vowel Identity, Baseline f0, and Loudness on the Relative Fundamental Frequency of Individuals With Healthy Voices
Next ArticleComparative Anatomy of Pig Arytenoid Cartilage and Human Arytenoid Cartilage

      Summary

      Objective

      The objective of this study was to quantitatively measure the three-dimensional (3D) structure of the vocal folds in normal subjects and in patients with different types of cricoarytenoid dislocation. We will analyze differences in parameters between the groups and also determine if any morphologic parameters possess utility in distinguishing the type and the degree of cricoarytenoid dislocation.

      Study Design

      This retrospective study was conducted using university hospital data.

      Methods

      Subjects' larynges were scanned using dual-source computed tomography (CT). The normal subjects were divided into deep-inhalation and phonation groups, and patients with cricoarytenoid joint dislocation were divided into anterior-dislocation and posterior-dislocation groups. Membranous vocal fold length and width were measured directly on the thin-section CT images. Vocal fold and airway 3D models were constructed using Mimics software and used in combination to measure vocal fold thickness, subglottal convergence angle, and oblique angle of the vocal folds.

      Results

      The phonation group displayed a greater vocal fold width, greater oblique angle, thinner vocal folds, and a smaller subglottal convergence angle than those of the deep-inhalation group (P < 0.05). The anterior-dislocation group displayed a smaller oblique angle and subglottal convergence angle than the posterior-dislocation group (P < 0.05).

      Conclusions

      The 3D structure of the vocal folds during deep inhalation and phonation can be accurately measured using dual-source CT and laryngeal 3D reconstruction. As the anterior-dislocation group yielded negative values for the oblique angle and the posterior-dislocation group yielded positive values, the oblique angle of the vocal folds may possess utility for distinguishing the type and for quantitatively determining the degree of cricoarytenoid dislocation.

      Key Words

      To read this article in full you will need to make a payment

      Purchase one-time access:

      Academic & Personal: 24 hour online accessCorporate R&D Professionals: 24 hour online access
      One-time access price info
      • For academic or personal research use, select 'Academic and Personal'
      • For corporate R&D use, select 'Corporate R&D Professionals'

      Subscribe:

      Subscribe to Journal of Voice
      Already a print subscriber? Claim online access
      Already an online subscriber? Sign in
      Register: Create an account
      Institutional Access: Sign in to ScienceDirect

      References

        • Patel R.
        • Dailey S.
        • Bless D.
        Comparison of high-speed digital imaging with stroboscopy for laryngeal imaging of glottal disorders.
        Ann Otol Rhinol Laryngol. 2008; 117: 413-424
        View in Article
        • Khoddami S.M.
        • Nakhostin A.N.
        • Izadi F.
        • et al.
        The assessment methods of laryngeal muscle activity in muscle tension dysphonia: a review.
        Sci World J. 2013; 2013: 77-87
        View in Article
        • Poburka B.J.
        A new stroboscopy rating form.
        J Voice. 1999; 13: 403-413
        View in Article
        • Krausert C.R.
        • Olszewski A.E.
        • Taylor L.N.
        • et al.
        Mucosal wave measurement and visualization techniques.
        J Voice. 2011; 25: 395-405
        View in Article
        • Berry D.A.
        • Montequin D.W.
        • Chan R.W.
        • et al.
        An investigation of cricoarytenoid joint mechanics using simulated muscle forces.
        J Voice. 2003; 17: 47-62
        View in Article
        • Deguchi S.
        • Kawahara Y.
        • Takahashi S.
        Cooperative regulation of vocal fold morphology and stress by the cricothyroid and thyroarytenoid muscles.
        J Voice. 2011; 25: e255-e263
        View in Article
        • Saigusa H.
        • Kokawa T.
        • Aino I.
        • et al.
        Arytenoid dislocation: a new diagnostic and treatment approach.
        J Nippon Med Sch Nippon Ika Daigaku zasshi. 2003; 70: 382
        View in Article
        • Rubin A.D.
        • Hawkshaw M.J.
        • Moyer C.A.
        • et al.
        Arytenoid cartilage dislocation: a 20-year experience.
        J Voice. 2006; 19: 687-701
        View in Article
        • Zhuang P.
        • Nemcek S.
        • Surender K.
        • et al.
        Differentiating arytenoid dislocation and recurrent laryngeal nerve paralysis by arytenoid movement in laryngoscopic video.
        Otolaryngol Head Neck Surg. 2013; 149: 451
        View in Article
        • Thayer S.R.
        • David B.I.
        • Spiegel J.R.
        Arytenoid dislocation: diagnosis and treatment.
        Laryngoscope. 1994; 104: 1353-1361
        View in Article
        • Xu X.
        • Wang J.
        • Devine E.E.
        • et al.
        The potential role of subglottal convergence angle and measurement.
        J Voice. 2017; 31 (116–e1)
        View in Article
        • Hollien H.
        Vocal fold dynamics for frequency change.
        J Voice. 2014; 28: 395-405
        View in Article
        • Komorn R.M.
        • Smith C.P.
        • Erwin J.R.
        Acute laryngeal injury with short-term endotracheal anesthesia.[J].
        Laryngoscope. 1973; 83: 683-690
        View in Article
        • Norris B.K.
        • Schweinfurth J.M.
        Arytenoid dislocation: an analysis of the contemporary literature.
        Laryngoscope. 2011; 121: 142-146
        View in Article
        • Wang Q.
        • Liang L.
        • Liu Y.
        • et al.
        Quantitative analysis of the visor-like vertical motion of the cricoarytenoid joint in the living subject.
        J Voice. 2016; 30: 354
        View in Article
        • Mau T.
        Three-dimensional morphometric analysis of cricoarytenoid subluxation.
        J Voice. 2012; 26: 133-136
        View in Article
        • Boresi A.P.
        • Chong K.P.
        • Lee J.D.
        Elasticity in Engineering Mechanics.
        3rd ed. Wiley, Hoboken2010: 65
        View in Article
        • Sataloff R.T.
        Voice Science.
        Plural Publishing, Inc., San Diego2005: 178-180
        View in Article

      Article info

      Publication history

      Published online: August 23, 2018
      Accepted: February 28, 2018

      Footnotes

      Disclosure: This study was supported by the National Natural Science Foundation of China, item number 81371080.

      Identification

      DOI: https://doi.org/10.1016/j.jvoice.2018.02.024

      Copyright

      © 2018 The Voice Foundation. Published by Elsevier Inc. All rights reserved.

      ScienceDirect

      Access this article on ScienceDirect

      The content on this site is intended for healthcare professionals.


      We use cookies to help provide and enhance our service and tailor content. To update your cookie settings, please visit the Cookie Preference Center for this site.
      Copyright © 2023 Elsevier Inc. except certain content provided by third parties.


      RELX