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Department of
Biomedical Engineering

Researchers from the Department Develop a New Cost Effective Approach to Evaluate Sleep Disorders

19 Mar' 2015
BGU researchers have developed a groundbreaking approach to determine sleep quality using their new breath sound analysis (BSA). This is less expensive and invasive than current polysomnography (PSG) technology, according to a new study published on PLOS One OnlineThe article also appears on F1000 Primewhich, aided by more than 5,000 international faculty members, identifies and recommends important articles in biology and medical research publications.

“One of the main goals of sleep medicine today is to improve early diagnosis and treatment of the "flood” of subjects presenting with sleep disorders,” says Prof. Yaniv Zigel Ph.D., head of the Biomedical Signal Processing Research Lab in BGU’s Department of Biomedical Engineering 

"We’ve developed a non-contact ‘breathing sound analysis’ algorithm that provides a reliable estimation of whole-night sleep evaluation for detection of sleep quality, snoring severity and Obstructive Sleep Apnea (OSA). It has the potential to reduce the cost and management of sleep disorders compared to PSG, the current standard of treatment, and could be used at home.”

PSG requires a full night sleep center stay and subjects are connected to numerous electrodes and sensors that are attached to the patient to acquire signals and data from electroencephalography (EEG), electrooculography (EOG), electromyography (EMG), and electrocardiography (ECG) tests. The data is processed and visually examined or mathematically transformed manually in order to reveal insights about sleep/wake states and many aspects of physiology. “This procedure is time-consuming, tedious and costly due to complexity and the need for technical expertise; the market is begging for a better solution,” says Eliran Dafna who conducted this study as part of his Ph.D. research.
 

In the study, the researchers measured whole-night breathing sounds from 150 patients using both ambient microphones and PSG simultaneously at a sleep laboratory. The system was trained on 80 subjects and a validation study was blindly performed on the additional 70 subjects. A set of acoustic features quantifying breathing patterns was developed to distinguish between sleep and wake segments. Sleep quality parameters were calculated based on the sleep/wake classifications and compared with PSG for validity.  

When comparing sleep quality parameters, there were only minor average differences in the measurements between PSG and BSA. Measuring 150,000 individual time segments (epochs), the BSA epoch-by-epoch accuracy rate for the validation study was 83.3 percent with 92.2 percent sensitivity measuring sleep as sleep. 

“The results showed that sleep/wake activity and sleep quality parameters can be reliably estimated solely using breathing sound analysis,” says Prof. Ariel Tarasiuk of BGU’s Department of Physiology and Neurobiology and head of the Sleep-Wake Disorders Unit, at Soroka University Medical Center. “This study highlights the potential of this innovative approach to measure sleep in research and clinical circumstances. Clearly, the transition of this technology to at-home sleep evaluation depends on third party reimbursements for the use of home study equipment.” 

The Biomedical Signal Processing Research Laboratory was established in 2007 by Prof. Yaniv Zigel. The lab's team are experts in physiological signal processing and pattern recognition. The Unit for the Study and Diagnosis of Sleep Disorders was established in 1994 by Prof. Ariel Tarasiuk. The unit's team of experts evaluate sleep disorders in children and adults and operates in conjunction with specialists in respiratory diseases, neurology, ENT, and gastrointestinal diseases.



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