A Naito1, S Niimi. 1. Department of Otolaryngology of the University of Tokyo, Japan. akira-tky@umin.u-tokyo.ac.jp
Abstract
OBJECTIVES: To develop a system capable of observing the larynx during various body movements and to investigate the relation between upper limb movements and laryngeal closure, often referred as "airtrapping." STUDY DESIGN: An endoscope capable of observing the larynx during various body movements was developed and the laryngeal state was monitored during these movements in three subjects. The output of 12 subjects' forearms was recorded with and without laryngeal closure. RESULTS: The larynx was observable even during extreme exercises such as horizontal bar exercises and vault exercises. Laryngeal closure was almost always seen during the beginning of maximum effort of the upper limbs. During constant effort, the state of the larynx varied. When the output of the upper limbs was compared with and without laryngeal closure, there was an average of 20% power loss. CONCLUSIONS: This study suggests four possible uses for this system. 1) The system could be useful to evaluate laryngeal disorders during exercise such as exercise-induced laryngomalacia. 2) The results could be used to improve the pushing exercise, a voice therapy technique. 3) The status of patients with incomplete laryngeal closure in connection with the upper limbs could be evaluated more thoroughly. 4) The technique and equipment could be used to observe the larynges during normal vocal processes that require body movement.
OBJECTIVES: To develop a system capable of observing the larynx during various body movements and to investigate the relation between upper limb movements and laryngeal closure, often referred as "airtrapping." STUDY DESIGN: An endoscope capable of observing the larynx during various body movements was developed and the laryngeal state was monitored during these movements in three subjects. The output of 12 subjects' forearms was recorded with and without laryngeal closure. RESULTS: The larynx was observable even during extreme exercises such as horizontal bar exercises and vault exercises. Laryngeal closure was almost always seen during the beginning of maximum effort of the upper limbs. During constant effort, the state of the larynx varied. When the output of the upper limbs was compared with and without laryngeal closure, there was an average of 20% power loss. CONCLUSIONS: This study suggests four possible uses for this system. 1) The system could be useful to evaluate laryngeal disorders during exercise such as exercise-induced laryngomalacia. 2) The results could be used to improve the pushing exercise, a voice therapy technique. 3) The status of patients with incomplete laryngeal closure in connection with the upper limbs could be evaluated more thoroughly. 4) The technique and equipment could be used to observe the larynges during normal vocal processes that require body movement.
Authors: Katarina Norlander; Pernille M Christensen; Robert C Maat; Thomas Halvorsen; John Helge Heimdal; Staffan Morén; Niels Rasmussen; Leif Nordang Journal: Eur Arch Otorhinolaryngol Date: 2015-09-08 Impact factor: 2.503
Authors: Maria Vollsæter; Trine Stensrud; Robert Maat; Thomas Halvorsen; Ola Drange Røksund; Astrid Sandnes; Hege Clemm Journal: Front Pediatr Date: 2022-01-03 Impact factor: 3.418