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New Swallowing Evaluation Using Piezoelectricity In Normal Individuals

Yuichiro Sogawa, S. Kimura, Toru Harigai, N. Sakurai, Akira Toyosato, Taro Nishikawa, M. Inoue, A. Murasawa, N. Endo
Published 2015 · Medicine

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This study aimed to elucidate the relationship between the piezoelectric waveform latency, hyoid bone movement, surface electromyogram (sEMG), and the pharyngeal transit time (PTT) during swallowing. Forty-one healthy subjects were divided into three age groups: younger (20–39 years, n = 8), middle-aged (40–59 years, n = 9), and older (60–79 years, n = 24). Motion analysis of the hyoid bone using videofluorography (VF), waveform analysis of the front neck using piezoelectric films, and sEMG of the suprahyoid muscle group were performed simultaneously. Latencies of the three movement phases were defined as upward (VFS1), forward (VFS2), and returning to starting position (VFS3). The three phases of the piezoelectric waveform—from wave initiation of the negative wave to the start of the second deep negative wave; from the start of the second deep negative wave to the start of the last positive wave (SLPW); and from the SLPW to the end of the last positive wave—were defined as PS1, PS2, and PS3, respectively. VFS1-3 and PS1-3 were significantly correlated. VFS1 and PS1 latencies were significantly longer with thick liquid than with thin liquid. VFS2, PS1, and PS2 latencies were longer in the older group than in the other two groups. The start of PS1 was nearly equal to those of sEMG and VFS1. Bolus arrival time in the valleculae was statistically equal to the end of the PS1 with both thin and thick liquids. To establish the swallowing screening using Piezoelectric film, further investigation is necessary in the dysphagia patients.
This paper references
10.1590/S0004-28032011000300008
Possible interaction of gender and age on human swallowing behavior.
R. Dantas (2011)
10.3109/00016487809121474
Electromyogram of the tensor tympani muscle in man during swallowing.
B. Salén (1978)
10.1159/000029344
Severe Barium Sulfate Aspirationinto the Lung: Clinical Presentation, Prognosis and Therapy
I. Tamm (1999)
10.1152/AJPGI.1989.257.5.G748
Opening mechanisms of the human upper esophageal sphincter.
I. J. Cook (1989)
10.1143/JJAP.8.975
The Piezoelectricity of Poly (vinylidene Fluoride)
H. Kawai (1969)
10.3390/s121216673
Influence of Parasitic Capacitance on Output Voltage for Series-Connected Thin-Film Piezoelectric Devices
K. Kanda (2012)
10.1177/000348940211100710
Acoustic Signature of the Normal Swallow: Characterization by Age, Gender, and Bolus Volume
J. Cichero (2002)
10.1007/s00455-002-0064-5
Hyoid Motion During Swallowing: Factors Affecting Forward and Upward Displacement
R. Ishida (2002)
10.1097/00004424-198605000-00009
The normal movements of the hyoid bone during swallow.
O. Ekberg (1986)
10.1152/AJPGI.1990.258.5.G675
Effect of swallowed bolus variables on oral and pharyngeal phases of swallowing.
R. Dantas (1990)
10.1021/nl8010484
Mechanical-electrical triggers and sensors using piezoelectric micowires/nanowires.
J. Zhou (2008)
10.5555/URI:PII:000399939290028U
Dysphagia following stroke: quantitative evaluation of pharyngeal transit times.
E. Johnson (1992)
10.1007/s00455-010-9323-z
Normal Swallowing Acoustics Across Age, Gender, Bolus Viscosity, and Bolus Volume
Scott R. Youmans (2010)
10.1001/ARCHOTOL.127.10.1224
Hyoid movement during swallowing in older patients with dysphagia.
K. Kendall (2001)
Intrinsic fibre architecture and attachments of the human epiglottis and their contributions to the mechanism of deglutition.
D. Vandaele (1995)
10.1007/s00405-007-0507-6
Fiberoptic endoscopic evaluation of swallowing in intensive care unit patients
G. Hafner (2007)
10.4321/S1130-01082004000200005
Approaching oropharyngeal dysphagia.
P. Clavé (2004)
10.2186/PRP.6.272
A Relation Between the Piezoelectric Pulse Transducer Waveforms and Food Bolus Passage during Pharyngeal Phase of Swallow
Akira Toyosato (2007)
10.1016/j.jpor.2008.08.008
Newly developed sensor sheet for measuring tongue pressure during swallowing.
K. Hori (2009)
10.1016/S0301-5629(96)00158-5
Evaluation of normal and abnormal hyoid bone movement during swallowing by use of ultrasound duplex-Doppler imaging.
B. Sonies (1996)
10.1097/00020840-199812000-00008
Evaluation and treatment of swallowing disorders
J. Logemann (1983)
10.1093/gerona/glr251
Epidemiology and management of common pulmonary diseases in older persons.
Kathleen M. Akgün (2012)
10.1016/S0016-5085(99)70144-7
AGA technical review on management of oropharyngeal dysphagia.
I. Cook (1999)
10.1044/SASD8.2.18
Book Reviews: The Neuroscientific Principles of Swallowing and Dysphagia
K. Brewster (1999)
10.1152/japplphysiol.90485.2008
Correspondence between food consistency and suprahyoid muscle activity, tongue pressure, and bolus transit times during the oropharyngeal phase of swallowing.
H. Taniguchi (2008)
10.1007/BF02406274
Durational aspects of the oral-pharyngeal phase of swallow in normal adults
B. Sonies (2006)
10.4103/0028-3886.60395
Quantitative videofluoroscopic analysis of penetration-aspiration in post-stroke patients.
Li Bingjie (2010)
10.3109/14417040008996802
The Neuroscientific Principles of Swallowing and Dysphagia
A. Miller (2000)
Manual for the videofluorographic study of swallowing
J. Logemann (1986)
10.1007/PL00021291
Inter- and Intrajudge Reliability for Videofluoroscopic Swallowing Evaluation Measures
G. McCullough (2014)
10.1097/PHM.0b013e318269d935
Oropharyngeal Transition of the Bolus in Post-Stroke Patients
Taeok Park (2013)
10.1007/BF02493469
Coordination of mastication and swallowing
J. Palmer (2006)
10.2186/PRP.4.1
Evaluation of Swallowing Function Using Ultrasound Diagnostic Methods
Tamachi Matsumi (2005)
Evalu - ation of swallowing function using ultrasound diagnostic meth
H Matsumi (2005)
10.1044/JSLHR.4305.1264
Temporal and biomechanical characteristics of oropharyngeal swallow in younger and older men.
J. Logemann (2000)
10.5555/URI:PII:000399939390277H
Aspiration pneumonia in stroke.
E. Johnson (1993)
10.1007/s00455-011-9340-6
Effect of Posture on Deglutitive Biomechanics in Healthy Individuals
J. Perry (2011)
10.1007/s004550010004
Timing of Events in Normal Swallowing: A Videofluoroscopic Study
Katherine A. Kendall (2000)
10.1097/01.MCG.0000159272.88974.54
Dysphagia in aging.
S. Achem (2005)
10.1111/joor.12060
Effects of the bolus volume on hyoid movements in normal individuals.
N. Ueda (2013)
10.1007/s00455-007-9135-y
Maximum Hyoid Displacement in Normal Swallowing
Young-sun Kim (2007)
10.1007/s00455-002-0070-7
Effects of Systematic Bolus Viscosity and Volume Changes on Hyoid Movement Kinematics
G. Chi-Fishman (2002)
Introduction to adult swallowing disorders
M. Crary (2003)
Oropharyngeal dysphagia—a team approach to prevent and treat complications
P Clavé (2005)
10.1007/s12194-010-0107-9
Sonographic assessment of hyoid bone movement during swallowing: a study of normal adults with advancing age
K. Yabunaka (2011)
10.2209/TDCPUBLICATION.43.199
Experimental device for detecting laryngeal movement during swallowing.
S. Abe (2002)



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