Detalhe da pesquisa
1.
Trilayered Hydrogel Scaffold for Vocal Fold Tissue Engineering.
Biomacromolecules
; 23(11): 4469-4480, 2022 11 14.
Artigo
em Inglês
| MEDLINE | ID: mdl-36286235
2.
Reaction kinetics of dual setting α-tricalcium phosphate cements.
J Mater Sci Mater Med
; 27(1): 1, 2016 Jan.
Artigo
em Inglês
| MEDLINE | ID: mdl-26610924
3.
Influence and interactions of laryngeal adductors and cricothyroid muscles on fundamental frequency and glottal posture control.
J Acoust Soc Am
; 135(4): 2052-64, 2014 Apr.
Artigo
em Inglês
| MEDLINE | ID: mdl-25235003
4.
Development of a glottal area index that integrates glottal gap size and open quotient.
J Acoust Soc Am
; 133(3): 1656-66, 2013 Mar.
Artigo
em Inglês
| MEDLINE | ID: mdl-23464035
5.
Neuromuscular control of fundamental frequency and glottal posture at phonation onset.
J Acoust Soc Am
; 131(2): 1401-12, 2012 Feb.
Artigo
em Inglês
| MEDLINE | ID: mdl-22352513
6.
Variability in the relationships among voice quality, harmonic amplitudes, open quotient, and glottal area waveform shape in sustained phonation.
J Acoust Soc Am
; 132(4): 2625-32, 2012 Oct.
Artigo
em Inglês
| MEDLINE | ID: mdl-23039455
7.
A Tissue Engineered Construct for Laryngeal Regeneration: A Proof-of-Concept Device Design Study.
Laryngoscope
; 132 Suppl 9: S1-S11, 2022 06.
Artigo
em Inglês
| MEDLINE | ID: mdl-35084750
8.
High Speed Video Observations of Vocal Fold Kinematics While Playing a Clarinet.
J Voice
; 2021 Sep 11.
Artigo
em Inglês
| MEDLINE | ID: mdl-34521588
9.
On the acoustical relevance of supraglottal flow structures to low-frequency voice production.
J Acoust Soc Am
; 128(6): EL378-83, 2010 Dec.
Artigo
em Inglês
| MEDLINE | ID: mdl-21218861
10.
Graded activation of the intrinsic laryngeal muscles for vocal fold posturing.
J Acoust Soc Am
; 127(4): EL127-33, 2010 Apr.
Artigo
em Inglês
| MEDLINE | ID: mdl-20369979
11.
Ex vivo perfused larynx model of phonation: preliminary study.
Ann Otol Rhinol Laryngol
; 116(11): 866-70, 2007 Nov.
Artigo
em Inglês
| MEDLINE | ID: mdl-18074674
12.
Physical mechanisms of phonation onset: a linear stability analysis of an aeroelastic continuum model of phonation.
J Acoust Soc Am
; 122(4): 2279-95, 2007 Oct.
Artigo
em Inglês
| MEDLINE | ID: mdl-17902864
13.
Hydration mechanism of partially amorphized ß-tricalcium phosphate.
Acta Biomater
; 54: 429-440, 2017 05.
Artigo
em Inglês
| MEDLINE | ID: mdl-28288934
14.
Differential roles for the thyroarytenoid and lateral cricoarytenoid muscles in phonation.
Laryngoscope
; 125(12): 2772-7, 2015 Dec.
Artigo
em Inglês
| MEDLINE | ID: mdl-26198167
15.
Calorimetry investigations of milled α-tricalcium phosphate (α-TCP) powders to determine the formation enthalpies of α-TCP and X-ray amorphous tricalcium phosphate.
Acta Biomater
; 23: 338-346, 2015 Sep.
Artigo
em Inglês
| MEDLINE | ID: mdl-26026302
16.
Influence of asymmetric recurrent laryngeal nerve stimulation on vibration, acoustics, and aerodynamics.
Laryngoscope
; 124(11): 2544-50, 2014 Nov.
Artigo
em Inglês
| MEDLINE | ID: mdl-24913182
17.
Posterior cricoarytenoid muscle dynamics in canines and humans.
Laryngoscope
; 124(10): 2363-7, 2014 Oct.
Artigo
em Inglês
| MEDLINE | ID: mdl-24781959
18.
Effect of amorphous phases during the hydraulic conversion of α-TCP into calcium-deficient hydroxyapatite.
Acta Biomater
; 10(9): 3931-41, 2014 Sep.
Artigo
em Inglês
| MEDLINE | ID: mdl-24681375
19.
Phonatory effects of type I thyroplasty implant shape and depth of medialization in unilateral vocal fold paralysis.
Laryngoscope
; 124(12): 2791-6, 2014 Dec.
Artigo
em Inglês
| MEDLINE | ID: mdl-25046146
20.
Effects of asymmetric superior laryngeal nerve stimulation on glottic posture, acoustics, vibration.
Laryngoscope
; 123(12): 3110-6, 2013 Dec.
Artigo
em Inglês
| MEDLINE | ID: mdl-23712542