Abstract
The ability to perform sit-to-stand (STS) transfers has a significant impact on the functional mobility of an individual. Wearable technology has the potential to enable the objective, long-term monitoring of STS transfers during daily life. However, despite several recent efforts, most algorithms for detecting STS transfers rely on multiple sensing modalities or device locations and have predominantly been used for assessment during the performance of prescribed tasks in a lab setting. A novel wavelet-based algorithm for detecting STS transfers from data recorded using an accelerometer on the lower back is presented herein. The proposed algorithm is independent of device orientation and was validated on data captured in the lab from younger and older healthy adults as well as in people with Parkinson’s disease (PwPD). The algorithm was then used for processing data captured in free-living conditions to assess the ability of multiple features extracted from STS transfers to detect age-related group differences and assess the impact of monitoring duration on the reliability of measurements. The results show that performance of the proposed algorithm was comparable or significantly better than that of a commercially available system (precision: vs. in healthy adults) and a previously published algorithm (precision: vs. in persons with Parkinson’s disease). Moreover, features extracted from STS transfers at home were able to detect age-related group differences at a higher level of significance compared to data captured in the lab during the performance of prescribed tasks. Finally, simulation results showed that a monitoring duration of 3 days was sufficient to achieve good reliability for measurement of STS features. These results point towards the feasibility of using a single accelerometer on the lower back for detection and assessment of STS transfers during daily life. Future work in different patient populations is needed to evaluate the performance of the proposed algorithm, as well as assess the sensitivity and reliability of the STS features.
Highlights
The ability to perform a sit-to-stand (STS) transfer is altered due to aging as well as impairments associated with conditions like knee osteoarthritis, Parkinson’s disease, stroke, sarcopenia, and multiple sclerosis [1,2]
Sensors 2020, 20, 6618 widely used, performance tests like the 5-times (5x) sit-to-stand test, 30-s chair stand test, timed up and go (TUG), Tinetti performance oriented mobility assessment (POMA), Berg balance test and Egress test that are routinely used for assessing mobility [5]
Results show that the proposed method outperforms two reference methods, with slightly better performance than the proprietary APDM method in the healthy adults and significantly better performance than an Inertial measurement units (IMUs)-based method in the people with Parkinson’s disease (PwPD)
Summary
The ability to perform a sit-to-stand (STS) transfer is altered due to aging as well as impairments associated with conditions like knee osteoarthritis, Parkinson’s disease, stroke, sarcopenia, and multiple sclerosis [1,2]. Sensors 2020, 20, 6618 widely used, performance tests like the 5-times (5x) sit-to-stand test, 30-s chair stand test, timed up and go (TUG), Tinetti performance oriented mobility assessment (POMA), Berg balance test and Egress test that are routinely used for assessing mobility [5]. Information captured during these assessments can help clinicians identify deficits (e.g., strength, balance), risk-factors (e.g., fall risk [6,7]), disease progression, and possible treatment effects
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