A novel automated detection system for swallowing sounds during eating and speech under everyday conditions

Fukuike, C.; Kodama, Naoki; Manda, Yosuke; Hashimoto, Yuki; Sugimoto, Kyoko; Hirata, Atsutoshi; Pan, Qing; Maeda, Naoto; Minagi, Shogo

doi:10.1111/joor.12264

Cited by 12 publications

(18 citation statements)

References 23 publications

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“…Less invasive methods to assess specific aspects of dysphagia have been investigated in previous studies such as ultrasonography to assess soft tissue function [30], manometry to assess pressure generation and propagation from the oral cavity through the esophagus [31], [32], and electromyography to assess the timing and sequence of muscle activation [33]. Cervical auscultation (CA) which uses stethoscopes to observe sounds emanating from the pharyngeal mechanism to infer about swallow physiology [16], [34]–[41], enables an examiner to “hear”a swallow, however it has been shown repeatedly to provide inconsistent information leading to subjective interpretations by the examiner due limitations of the human auditory system and to variations in instrument design since stethoscopes are not designed to transmit pharyngeal sounds [42], [43]. Despite its poor precision in clinical practice, CA has intrigued investigators including ourselves with interests in signal processing, who hypothesize that the acoustic-vibratory information arising from oropharyngeal physiology contains useful diagnostic clues as to the nature of dysphagia.…”

Section: Introductionmentioning

confidence: 99%

High-Resolution Cervical Auscultation Signal Features Reflect Vertical and Horizontal Displacements of the Hyoid Bone During Swallowing

Rebrion

Zhang

Khalifa

et al. 2019

IEEE J. Transl. Eng. Health Med.

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Millions of people across the globe suffer from swallowing difficulties, known as dysphagia, which can lead to malnutrition, pneumonia, and even death. Swallowing cervical auscultation, which has been suggested as a noninvasive screening method for dysphagia, has not been associated yet with any physical events. In this paper, we have compared the hyoid bone displacement extracted from the videofluoroscopy images of 31 swallows to the signal features extracted from the cervical auscultation recordings captured with a tri-axial accelerometer and a microphone. First, the vertical displacement of the anterior part of the hyoid bone is related to the entropy rate of the superior–inferior swallowing vibrations and to the kurtosis of the swallowing sounds. Second, the vertical displacement of the posterior part of the hyoid bone is related to the bandwidth of the medial–lateral swallowing vibrations. Third, the horizontal displacements of the posterior and anterior parts of the hyoid bone are related to the spectral centroid of the superior–inferior swallowing vibrations and to the peak frequency of the medial–lateral swallowing vibrations, respectively. At last, the airway protection scores and the command characteristics were associated with the vertical and horizontal displacements, respectively, of the posterior part of the hyoid bone. Additional associations between the patients’ characteristics and auscultations’ signals were also observed. The hyoid bone maximal displacement is a cause of swallowing vibrations and sounds. High-resolution cervical auscultation may offer a noninvasive alternative for dysphagia screening and additional diagnostic information.

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Section: Introductionmentioning

confidence: 99%

High-Resolution Cervical Auscultation Signal Features Reflect Vertical and Horizontal Displacements of the Hyoid Bone During Swallowing

Rebrion

Zhang

Khalifa

et al. 2019

IEEE J. Transl. Eng. Health Med.

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“…Dry (saliva) swallowing identification featured in the majority of wearable systems that assessed swallowing [ 19 ]. For non-swallowing, Skowronski et al [ 30 ] proposed a non-swallowing protocol with tasks including yawning, sniffing, tongue movement, humming, throat clearing, coughing, and speech, while Fukuike et al [ 22 ] added gargling, sighing, and sipping tea. Talking, reading, and speech have not been standardized in previous studies, though they might be examined by machine learning.…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, the protocol design is devoted to a computer-aided dysphagia screening tool using wearable technology and machine learning techniques or other classifier algorithms. In such a case, the signals of sensors corresponding to each swallowing maneuver can either be manually labelled by the professional watching the video recording, or be labelled by asking the participant to press a button or pedal during the swallowing episode [ 21 , 22 ]. The tasks during the assessment phase can be repeated according to the need for data augmentation.…”

Section: Methodsmentioning

confidence: 99%

A Comprehensive Assessment Protocol for Swallowing (CAPS): Paving the Way towards Computer-Aided Dysphagia Screening

Lim

Lai

et al. 2023

IJERPH

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Dysphagia is one of the most common problems among older adults, which might lead to aspiration pneumonia and eventual death. It calls for a feasible, reliable, and standardized screening or assessment method to prompt rehabilitation measures and mitigate the risks of dysphagia complications. Computer-aided screening using wearable technology could be the solution to the problem but is not clinically applicable because of the heterogeneity of assessment protocols. The aim of this paper is to formulate and unify a swallowing assessment protocol, named the Comprehensive Assessment Protocol for Swallowing (CAPS), by integrating existing protocols and standards. The protocol consists of two phases: the pre-test phase and the assessment phase. The pre-testing phase involves applying different texture or thickness levels of food/liquid and determining the required bolus volume for the subsequent assessment. The assessment phase involves dry (saliva) swallowing, wet swallowing of different food/liquid consistencies, and non-swallowing (e.g., yawning, coughing, speaking, etc.). The protocol is designed to train the swallowing/non-swallowing event classification that facilitates future long-term continuous monitoring and paves the way towards continuous dysphagia screening.

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“…Therefore, swallowing sound recorded at site 11 could be used in future studies to provide functional information concerning the rhinopharynx. In previous studies, a ready‐made laryngeal microphone was used to detect swallowing sound . This microphone was attached to the position over the lateral border of the trachea immediately inferior to the cricoid cartilage, as recommended by Takahashi et al .…”

Section: Discussionmentioning

confidence: 99%

Validation of the optimal site in the neck region for detecting swallowing sounds

Pan

Maeda

Manda

et al. 2016

J of Oral Rehabilitation

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Recently, the swallowing sound has been used to detect swallowing events non-invasively. A previous study, using an accelerometer, showed that the site over the lateral border of the trachea immediately inferior to the cricoid cartilage was the optimal site for detecting swallowing sounds. However, the optimal site for detection of the swallowing sound using a microphone remains undetermined. To validate the optimal site in the neck region for detecting swallowing sounds. Fourteen healthy subjects (mean age, 27·6 ± 2·2 years; seven male and seven female) participated in this study. Twenty condenser microphones were attached to 20 sites on the left neck surface to detect swallowing sounds. Participants were instructed to swallow five different stimuli three times as follows: Resting saliva, 1 and 5 mL of Japanese tea, and 1 and 5 mL of yoghurt. Mean relative peak intensity was used to indicate the magnitude of the swallowing sound. Sound spectrograms were used to illustrate differences in the properties of swallowing sounds. Mean relative peak intensity number was highest in sites at the inferior border of the mandible just above the sternocleidomastoid muscle (site 11) and sites over the lateral border of the trachea immediately inferior to the cricoid cartilage (site 8). Comparison of spectrograms showed a greater density distribution of higher frequency components at site 11 compared with site 8. These results indicate that the inferior border of the mandible just above the sternocleidomastoid muscle is the optimal site for the detection of swallowing sounds.

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A novel automated detection system for swallowing sounds during eating and speech under everyday conditions

Cited by 12 publications

References 23 publications

High-Resolution Cervical Auscultation Signal Features Reflect Vertical and Horizontal Displacements of the Hyoid Bone During Swallowing

High-Resolution Cervical Auscultation Signal Features Reflect Vertical and Horizontal Displacements of the Hyoid Bone During Swallowing

A Comprehensive Assessment Protocol for Swallowing (CAPS): Paving the Way towards Computer-Aided Dysphagia Screening

Validation of the optimal site in the neck region for detecting swallowing sounds

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