2020
DOI: 10.2147/mder.s279521
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<p>Physiological Vibration Acceleration (Phybrata) Sensor Assessment of Multi-System Physiological Impairments and Sensory Reweighting Following Concussion</p>

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Cited by 6 publications
(28 citation statements)
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References 187 publications
(295 reference statements)
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“…We recently introduced physiological vibration acceleration (phybrata) sensing [58], a non-invasive balance and neurophysiological impairment assessment tool that utilizes a head-mounted accelerometer to detect the contributions of individual physiological systems to a phenomenon that is unique to a head-mounted sensor-the biomechanical stabilization of the head and eyes as the reference platform that the body relies on for balance and movement. The phybrata sensor attaches behind the ear using a small disposable adhesive and testing simply requires the patient to stand still for 20 s with their eyes open (Eo), and again for 20 s with their eyes closed (Ec).…”
Section: Phybrata Sensingmentioning
confidence: 99%
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“…We recently introduced physiological vibration acceleration (phybrata) sensing [58], a non-invasive balance and neurophysiological impairment assessment tool that utilizes a head-mounted accelerometer to detect the contributions of individual physiological systems to a phenomenon that is unique to a head-mounted sensor-the biomechanical stabilization of the head and eyes as the reference platform that the body relies on for balance and movement. The phybrata sensor attaches behind the ear using a small disposable adhesive and testing simply requires the patient to stand still for 20 s with their eyes open (Eo), and again for 20 s with their eyes closed (Ec).…”
Section: Phybrata Sensingmentioning
confidence: 99%
“…During this static balance testing, the phybrata sensor uses a microelectromechanical system (MEMS)-based inertial motion unit (IMU) to detect microscopic involuntary motions of the body, both normal motions characteristic of healthy individuals and pathological motions caused by physiological impairments that impact balance and postural stability. As we previously described in detail [58], the direct measurement of acceleration motions at the head allows the phybrata sensor to detect signal components with a much wider range of frequencies compared to motion sensors mounted elsewhere on the body, which in turn allows impairments to individual physiological systems (CNS, PNS, sensory, musculoskeletal) to be identified, quantified, and monitored using the unique biomechanical vibrational signature of each system, and reveals the sensory reweighting across multiple physiological systems that is triggered by impairment to any single physiological system. Although many wearable motion sensors contain both an accelerometer and a gyroscope, accelerometers are significantly more power-efficient than gyroscopes [59], and the use of a single accelerometer in the phybrata sensor makes it more practical for long-term activity monitoring [60,61].…”
Section: Phybrata Sensingmentioning
confidence: 99%
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