← Back to Search
Effect Of Superior Laryngeal Nerve Stimulation On Phonation In An In Vivo Canine Model.
G. Berke, D. M. Moore, B. Gerratt, D. Hanson, M. Natividad
Published 1989 · Medicine
Download PDFAnalyze on Scholarcy
We investigated the effect of variation in superior laryngeal nerve stimulation (SLNS) on vocal fold vibration. Photoglottography (PGG), electroglottography (EGG), and subglottic pressure (Psub) were measured in seven mongrel dogs using an in vivo canine model of phonation. The PGG, EGG, and Psub signals were examined at three SLNS frequencies (100 Hz, 130 Hz, and 160 Hz) using a constant rate of air flow. Increasing SLNS, which causes a contraction of the cricothyroid muscle, produced a marked increase in Fo, little change in Psub, an increase in the open quotient, and a decrease in the closed quotient of the glottal cycle.
This paper references
Structure of the vocal fold in normal and disease states. Anatomical and physical studies
M Hirano (1981)
Stimmphysiologische Untersuchungen an einem Kehlkopfmodell
E Mueller (1938)
Physiology and pathology of the cricothyroid muscle
G. Arnold (1961)
Synthesis of voiced sounds from a two-mass model of the vocal cords
K. Ishizaka (1972)
Measurement of viscoelastic properties in live tissue, in Titze IR, Scherer RC (eds): Vocal Fold Physiology
AL Perlman (1983)
Laryngeal vibrations: a comparison between high-speed filming and glottographic techniques.
T. Baer (1983)
Glottographic measures of laryngeal function in individuals with abnormal motor control
BR Gerratt (1987)
Sound Film: The Larynx and Voice--The Function of the Normal Larynx
P Moore (1956)
Vocal fold vibration in excised larynges: View with an x-ray stroboscope and an ultra-high-speed camera, in Bless DM, Abbs JH (edsf: Vocal Fold Physiology
S Fukuda H. Saito S. Kitihara (1983)
Morphological structure of the vocal cord as a vibrator and its variations.
M. Hirano (1974)
Vibratory patterns of the human vocal cords during variations in frequency and intensity
BH Hildebrand (1976)
A critical review of electroglottography.
D. Childers (1985)
Measurement of viscoelastic properties in live tissue
AL Perlman (1983)
A method for studying the vibratory movements of the vocal cords: a preliminary report.
B. Sonesson (1959)
Pressure measurements during speech production using semiconductor miniature pressure transducers: impact on models for speech production.
B. Cranen (1985)
Vocal fry as a phonational register.
H. Hollien (1968)
Electromyographic investigation of intrinsic laryngeal muscles in humans
K Faaborg-Anderson (1957)
The function of laryngeal muscles in regulating fundamental frequency and intensity of phonation.
M. Hirano (1968)
Laryngeal dynamics associated with voice frequency change.
T. Shipp (1971)
The effect of laryngeal nerve stimulation on phonation: a glottographic study using an in vivo canine model.
D. M. Moore (1988)
Laryngeal modeling: Theoretical, in vitro, in vivo
Gerald S. Berke (1987)
Glottographic measures of laryngeal function in individuals with abnormal motor control . in Harris K . Sasaki C
BR Gerratt (1987)
An experimental model to test the effect of change in tension and mass on laryngeal vibration
GS Berke (1986)
Experimental studies on vocal pitch and intensity in phonation
H. J. Rubin (1963)
Physiological mechanisms of phonation: tension of the vocal fold muscle.
M. Hast (1966)
This paper is referenced by
Superior laryngeal nerve paresis and paralysis.
G. Dursun (1996)
Effects of driving pressure and laryngeal nerve stimulation on in a constant pressure model recurrent glottic vibration
Andrew Verneuil (2004)
Experiments on Analysing Voice Production: Excised (Human, Animal) and In Vivo (Animal) Approaches.
M. Döllinger (2011)
Long-term Results with Hydroxylapatite Middle Ear Implants
R. A. Goldenberg (2000)
Phonatory characteristics of excised pig, sheep, and cow larynges.
F. Alipour (2008)
Long-term model of induced canine phonation
R. Paniello (1998)
Characteristics of an In Vivo Canine Model of Phonation With a Constant Air Pressure Source
S. Nasri (1996)
Hydroxylapatite Ossicular Replacement Prostheses: A Four-Year Experience
R. A. Goldenberg (1992)
A Pressure-Regulated Model of Normal and Pathologic Phonation
S. Nasri (1994)
Current Use of Implants in Middle Ear Surgery
R. A. Goldenberg (2001)
Total Ossiculoplasty: Advantages of Two-Point Stabilization Technique
L. Berenholz (2012)
Evaluation of Hydroxyapatite Ossicular Chain Prostheses
R. Pasha (2000)
Passive Middle Ear Implants
K. Schwager (2014)
Combination thyroplasty and the "twisted larynx:" combined type IV and type I thyroplasty for superior laryngeal nerve weakness.
S. Nasseri (2000)
Function of the Thyroarytenoid Muscle in a Canine Laryngeal Model
Hong-Shik Choi (1994)
Voice aerodynamics following office‐based hyaluronate injection laryngoplasty
Yu-Cheng Pei (2019)
Effect of Superior Laryngeal Nerve on Vocal Fold Function: An in Vivo Canine Model
D. Slavit (1991)
Non-invasive documentation of primate voice production using electroglottography
C. T. Herbst (2018)
Die mikrobielle Situation an Implantatoberflächen
G. Tuschewitzki (1992)
Intraoperative neural monitoring in thyroid surgery: lessons learned from animal studies.
C. Wu (2016)
Ossiculoplasty with the use of autografts and synthetic prosthetic materials: a comparison of results in 165 cases.
A. Nikolaou (1992)
Nonlinear analyses of elicited modal, raised, and pressed rabbit phonation.
S. Awan (2014)
Malleus Relocation in Ossicular Reconstruction: Managing the Anteriorly Positioned Malleus: Results in a Series of 268 Cases
R. Vincent (2004)
Comparison of the Mechanical Performance of Ossiculoplasty Using a Prosthetic Malleus-to-Stapes Head with a Tympanic Membrane-to-Stapes Head Assembly in a Human Cadaveric Middle Ear Model
M. Bance (2004)
Reversibility of Medialization Laryngoplasty an Experimental Study
R. Paniello (1997)
Effects of Driving Pressure and Recurrent Laryngeal Nerve Stimulation on Glottic Vibration in a Constant Pressure Model
A. Verneuil (1996)
Impact of Cricothyroid Muscle Contraction on Vocal Fold Vibration: Experimental Study with High-Speed Videoendoscopy.
Camila Cristina Ishikawa (2017)
Lessons from animal studies on recurrent laryngeal nerve monitoring
Antonia Catalfamo (2019)