Review of Audiovestibular Symptoms Following Exposure to Acoustic and Electromagnetic Energy Outside Conventional Human Hearing

Lubner, Rory J.; Kondamuri, Neil; Knoll, Renata M.; Ward, Bryan K.; Littlefield, Philip D.; Rodgers, Derek B.; Abdullah, Kalil G.; Remenschneider, Aaron K.; Kozin, Elliott D.

doi:10.3389/fneur.2020.00234

Cited by 15 publications

(7 citation statements)

References 89 publications

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“…Active solutions could have negative consequences or long-term health effects, which physicians have not yet directly investigated. Some studies suggest the need for extensive research on standard technology used in wearables, such as radiation sources/waves around the body (e.g., WiFi and ultrasound) [46,47,48,49,50]. While it may seem overly cautious or unrealistic at this stage of wearable technology, we want to maintain our effort to reduce the exposure of our volunteers and ourselves to signals that have not yet proven to be risk-free.…”

Section: Facial Monitoring With Wearablesmentioning

confidence: 99%

InMyFace: Inertial and Mechanomyography-Based Sensor Fusion for Wearable Facial Activity Recognition

Bello¹,

Marin²,

Suh³

et al. 2023

Preprint

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Recognizing facial activity is a well-understood (but non-trivial) computer vision problem. However, reliable solutions require a camera with a good view of the face, which is often unavailable in wearable settings. Furthermore, in wearable applications, where systems accompany users throughout their daily activities, a permanently running camera can be problematic for privacy (and legal) reasons. This work presents an alternative solution based on the fusion of wearable inertial sensors, planar pressure sensors, and acoustic mechanomyography (muscle sounds). The sensors were placed unobtrusively in a sports cap to monitor facial muscle activities related to facial expressions. We present our integrated wearable sensor system, describe data fusion and analysis methods, and evaluate the system in an experiment with thirteen subjects from different cultural backgrounds (eight countries) and both sexes (six women and seven men). In a one-model-per-user scheme and using a late fusion approach, the system yielded an average F1 score of 85.00% for the case where all sensing modalities are combined. With a cross-user validation and a one-model-for-all-user scheme, an F1 score of 79.00% was obtained for thirteen participants (six females and seven males). Moreover, in a hybrid fusion (cross-user) approach and six classes, an average F1 score of 82.00% was obtained for eight users. The results are competitive with state-of-the-art non-camera-based solutions for a cross-user study. In addition, our unique set of participants demonstrates the inclusiveness and generalizability of the approach.

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Section: Facial Monitoring With Wearablesmentioning

confidence: 99%

InMyFace: Inertial and Mechanomyography-Based Sensor Fusion for Wearable Facial Activity Recognition

Bello¹,

Marin²,

Suh³

et al. 2023

Preprint

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“…“Cavitation noise” refers to a series of reactions that lead to bubble growth, oscillation, and rupture when ultrasonic waves propagate through a medium. When the cavitation bubble bursts, the energy stored inside is released, and noise is generated [ 124 ]. Workers who have worked in ultrasound for a long time may develop a disturbance of the auditory nerve and characterize a range of symptoms, including headache, nausea, vomiting, fatigue, and temporary tinnitus, known as “ultrasound disease.” Iversen believes that ultrasound-induced hearing loss is due to the activation of the vestibular otolithic organs by acoustic radiation forces [ 125 ].…”

Section: Shortcomings and Perspectives Of Ultrasound Technologymentioning

confidence: 99%

Use of Ultrasonic Cleaning Technology in the Whole Process of Fruit and Vegetable Processing

Zhou

Sarpong²,

Zhou³

2022

Foods

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In an era of rapid technological development, ultrasound technology is being used in a wide range of industries. The use of ultrasound technology in fruit and vegetable processing to improve production efficiency and product quality has been an important research topic. The cleaning of whole fresh fruits and vegetables is an important part of fruit and vegetable processing. This paper discusses the development process of components of the ultrasonic equipment, the application of ultrasonic technology in fruit and vegetable cleaning, and the research advances in ultrasonic cleaning technology. Moreover, the feasibility of ultrasonication of fruits and vegetables for cleaning from the perspectives of microbial inactivation, commodity storage, and sensory analysis were discussed. Finally, the paper identified the inevitable disadvantages of cavitation noise, erosion, and tissue damage in fruit and vegetable processing and points out the future directions of ultrasonic fruit and vegetable cleaning technology.

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“…Lin ( 3 ) suggested a “tissue-injuring level” of 20 Pa for intracranial pressures based on a conventionally accepted threshold of 120 dB re 20 μPa for noise-induced hearing loss due to damage to hair cells in the cochlea. Lubner et al described a variety of audiovestibular symptoms from ultrasound exposures above 20 kHz, for example “complaints of fatigue, buzzing, nausea, and headaches” in workers from an ultrasonic cleaning bath (115 dB at 40 kHz), with “mixed conclusions” about permanent audiovestibular damage from ultrasound exposures ( 10 ). Peak acoustic pressures shown in Table 1 far exceed these levels, but differences in exposures are considerable.…”

Section: Thresholds For Perception and Adverse Effectsmentioning

confidence: 99%

Can the Microwave Auditory Effect Be “Weaponized”?

Foster

Garrett

Ziskin

2021

Front. Public Health

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Review of Audiovestibular Symptoms Following Exposure to Acoustic and Electromagnetic Energy Outside Conventional Human Hearing

Cited by 15 publications

References 89 publications

InMyFace: Inertial and Mechanomyography-Based Sensor Fusion for Wearable Facial Activity Recognition

InMyFace: Inertial and Mechanomyography-Based Sensor Fusion for Wearable Facial Activity Recognition

Use of Ultrasonic Cleaning Technology in the Whole Process of Fruit and Vegetable Processing

Can the Microwave Auditory Effect Be “Weaponized”?

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