Novel sensing technology in fall risk assessment in older adults: a systematic review

Sun, Ruopeng; Sosnoff, Jacob J.

doi:10.1186/s12877-018-0706-6

Cited by 135 publications

(132 citation statements)

References 49 publications

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“…The possibility of using the Wii Balance Board (WBB) to estimate whether the player is at an increased falling risk has been identified [4]. However, related publications mention the need for additional studies, particularly in finding direct relationships between sensor data and clinically meaningful fall risk estimation methods.…”

Section: Introductionmentioning

confidence: 99%

Fall Risk Prediction via Classification of Lower Extremity Strength in Older Adults with Exergame-Collected Data

Becker

García-Agúndez

Müller

et al. 2020

Preprint

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Objective: The goal of this article is to present and evaluate a sensor-based falling risk estimation system. The system consists of an array of Wii Balance Boards (WBB) and an exergame that estimates if the player is at an increased falling risk by predicting the result of the 30 Second Sit-To-Stand Test (30CST).Methods: 16 participants recruited at a nursing home performed the 30CST and then played the exergame as often as desired during a period of two weeks. For each session, features related to how they walk and stand on the WBBs while playing the exergame were collected. Different classifier algorithms were used to predict the result of the 30CST on a binary basis (able or unable to maintain physical independence). Results: We achieved a maximum accuracy of 91% when attempting to estimate if the player’s 30CST score will be over or under a threshold of 12 points using a Logistic Model Tree. We also believe it is feasible to predict age- and sex-adjusted cutoff scores. Conclusion: An array of WBBs seems to be a viable solution to estimate lower extremity strength and with it the falling risk. In addition, data extracted while playing may form a basis to perform a general screening to identify elderly at an increased falling risk.

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Section: Introductionmentioning

confidence: 99%

Fall Risk Prediction via Classification of Lower Extremity Strength in Older Adults with Exergame-Collected Data

Becker

García-Agúndez

Müller

et al. 2020

Preprint

View full text Add to dashboard Cite

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“…Even though such standardized tests are relatively easy to conduct, it is still underutilized and not routinely integrated into clinical practice. Partially due to clinicians' time constraints and competing medical priorities, lack of access to lab-grade advanced testing equipment (such as motion 2 of 12 capture device, force platform), as well as lack of clinical expertise [9], thus limiting access to fall risk screening in the community dwelling older adults. Consequently, older adults remain unaware of their individual fall risk, appropriate fall prevention approaches and at elevated risk of falls.…”

Section: Introductionmentioning

confidence: 99%

“…With the recent advancement in sensing technology, sensor-based fall risk assessment that can efficiently capture and analyze quantitative mobility data have received a growing interest for its portability, accessibility and inexpensiveness [9,10]. More specifically, the use of wearable sensors (inertial measurement unit, IMU) for mobility-related tracking has been the focus of these work, in which miniature accelerometers and/or gyroscopes were used to quantify movement pattern/abnormality by various time and frequency parameters [9,11].…”

Section: Introductionmentioning

confidence: 99%

The Validity of a Mixed Reality-Based Automated Functional Mobility Assessment

Sun

Sosnoff²

2019

Preprint

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Functional mobility assessments (i.e., Timed Up and Go) are commonly used clinical tools for mobility and fall risk screening in the aging population. In this work, we proposed a new Mixed Reality (MR)-based assessment that utilized a Microsoft HoloLensTM headset to automatically lead and track the performance of functional mobility tests, and subsequently evaluated its validity in comparison with reference inertial sensors. Twenty-two healthy adults (10 older, 12 young) participated in this study. An automated functional mobility assessment app was developed based on the HoloLens platform. Mobility performance was recorded with the headset built-in sensor and validated with reference inertial sensor (Opal, APDM) taped on the headset and lower back. Results indicate vertical kinematic measures by HoloLens was in good agreement with the reference sensor (Normalized RMSE ~ 10%). Additionally, the HoloLens-based test completion time was in perfect agreement with clinical standard stopwatch measure. Overall, our preliminary investigation indicates that it is possible to use an MR headset to automatically guide users to complete common mobility tests with good measurement accuracy, thus it has great potential to provide objective and efficient sensor-based mobility assessment.

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“…Further, using the machine-learning classifiers such as SVM, decision tree, and neural network, can classify and identify different behaviors including stalling, walking, running, and etc., which can achieve a recognition accuracy about 95% [17,18] . When combined with geographic information, the method is widely used in caring for the old and the young, and for sports pattern recognition [19][20][21][22] . In the field of automobile driving, accelerometers, and gyroscopes are widely used in driving style and driving safety recognition [23][24][25] , such as sudden acceleration, sudden braking, speeding, and sharply turning [24,26,27] .…”

Section: Introduction mentioning

confidence: 99%

Behavior modelling and sensing for machinery operations using smartphone’s sensor data: A case study of forage maize sowing

Wu¹,

Chen²,

Wang³

et al. 2019

International Journal of Agricultural and Biological Engineering

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Large-scale agricultural machinery cooperatives require technical statistic report of agricultural machinery operations to improve the efficiency of fleet management. This research proposed a smartphone-based solution to build the behavior model for agricultural machinery operations by using the embedded sensors including the GNSS, the accelerometer, and the microphone. The whole working process of agricultural machinery operation was divided into four stages: preparation, operation, U-turn, and transfer, each of which may contain the behaviors of stalling and idling. Field experiments were carried out by skilled operators, whose operations were typical agricultural machinery operations that could be used to extract behavior features. Butterworth low-pass filter was used to smooth the output from the accelerometer. Then, the operating data were collected through an APP when sowing the forage maize as a case study. Four stages of machinery operation can be preliminarily classified by using GNSS speed, while the identification of behaviors such as sudden acceleration and longtime idling that may increase fuel consumption, reduce machinery life, or decrease the working efficiency, requires extra information such as acceleration and sound intensity. The results showed that the jerk of accelerating can describe the severity of the sudden acceleration, the standard deviation of forward acceleration can reflect the smoothness of operation, the upward acceleration can be used to identify behaviors of stalling and idling, and the sound intensity during idling can capture the behavior of goosing the throttle. Further, the operating behavior figure can be drawn based on the above parameters. In conclusion, this research constructed several behavior models of agricultural machinery and operators by using smartphone's sensor data and established the base of the online assessing and scoring system for agricultural machinery operations. modelling and sensing for machinery operations using smartphone's sensor data: a case study of forage maize sowing. Int J Agric & Biol Eng, 2019; 12(6): 66-74. Biographies: Caicong Wu, PhD, Associate Professor, research interest: location-based service of farm machinery, Email: wucc@cau.edu.cn; Zhibo Chen, PhD candidate, research interest: location-based service of farm machinery, Email: bobodi@qq.com; Dongxu Wang, Master candidate, research interest: location-based service of farm machinery, Email: dongxu_wang@ cau.edu.cn; Zhihong Kou, Master candidate, research interest: location-based service of farm machinery, Email: 603040848@qq.com; Yaping Cai, PhD candidate, research interest: mobile information collection, Email: caicai_pku@ 163.com.

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Novel sensing technology in fall risk assessment in older adults: a systematic review

Cited by 135 publications

References 49 publications

Fall Risk Prediction via Classification of Lower Extremity Strength in Older Adults with Exergame-Collected Data

Fall Risk Prediction via Classification of Lower Extremity Strength in Older Adults with Exergame-Collected Data

The Validity of a Mixed Reality-Based Automated Functional Mobility Assessment

Behavior modelling and sensing for machinery operations using smartphone’s sensor data: A case study of forage maize sowing

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