Your search keyword '"LARYNGECTOMEES"' showing total 252 results

251. Design and test of a new tracheostoma valve based on inhalation

Author

Gijsbertus Jacob Verkerke, Harm K. Schutte, A.A. Geertsema, Cornelis W. Boonstra, and Extremities Pain and Disability (EXPAND)

Subjects

REHABILITATION, Acoustics, Airflow, Airway resistance, Tracheostomy, Phonation, Pressure, Medicine, Humans, Resistance coefficient, Expiration, Polycarboxylate Cement, Inhalation, business.industry, LARYNGECTOMEES, Air, Respiration, Quiet breathing, General Medicine, Equipment Design, Otorhinolaryngology, Anesthesia, Breathing, AERODYNAMIC CHARACTERISTICS, Surgery, business, Larynx, Artificial

Abstract

Background: Tracheostoma valves are used to make hand-free speaking possible for persons who have undergone a laryngectomy. Objective: To design and test a new tracheostoma valve to improve existing tracheostoma valves. Methods: The tracheostoma valve closes by means of strong inhalation so that all the air that is exhaled is available for phonation. The device automatically stays in the "speaking position" until the patient deliberately changes the device to the "breathing position" by a fast expiration. If all the air that has been exhaled has been consumed during phonation, the patient can inhale again, without changing the device, because a small valve automatically opens, thus allowing phonation without time limits. An experimental setup with a computer-based acquisition program was used to measure the pressure at which the valve opened and the flow at which the valve closed. The pressure and flow needed to open and close the magnetic adjustable valve were measured for different positions and contained in the computer through a data acquisition program. Also, the airflow resistance coefficients for inhaling and exhaling were measured. Results: The airflow necessary to close the tracheostoma valve ranges from 1.6 to 3.8 Us. The opening pressure of the valve ranges from 1 to 7 kPa. The airflow resistance coefficient is 290 Pa . s(2) . L-2 for inhalation and 430 Pa . s(2) . L-2 for er;halation. Conclusions: The device appears to function well in physiological ranges and is optimally adjustable. The airflow resistance coefficient lies in the range of the entire airway resistance (120-470 Pa . s(2) . L-2) in quiet breathing.

252. Impact of various small sound source signals on voice conversion accuracy in speech communication aid for laryngectomees

Author

Hiroshi Saruwatari, Keigo Nakamura, Kiyohiro Shikano, and Tomoki Toda

Subjects

geography, geography.geographical_feature_category, voice conversion, Computer science, Speech recognition, speaking aid, laryngectomees, sound sources, Voice analysis, Power (physics), Silence, medicine.anatomical_structure, Vocal folds, medicine, Pulse wave, Speech communication, Sound (geography)

Abstract

We proposed a speaking aid system using statistical voice conversion for laryngectomees, whose vocal folds have been removed. This paper investigates the influence of various small sound sources on the voice conversion accuracy. Spectral envelopes and power of sound sources are controlled independently. In total 8 different kinds of sound source signals, e.g. pulse train, sierra wave and so on, are examined. Results of objective and subjective evaluations demonstrate that for voice conversion, sound sources with various spectral envelopes and power in a large degree are acceptable unless the power of them is comparable to that of silence parts., INTERSPEECH2007: 8th Annual Conference of the International Speech Communication Association, August 27-31, 2007, Antwerp, Belgium.