Your search keyword '"Kim Delbaere"' showing total 5 results

1. Remote timed up and go evaluation from activities of daily living reveals changing mobility after surgery

Author

Kim Delbaere, Sietse M. Rispens, Martin Stevens, Harmke Nijboer, Jildou Hoogland, Gabriele Spina, Matthew A. Brodie, Janneke Annegarn, Salvatore Saporito, and Public Health Research (PHR)

Subjects

SELECTION, Male, medicine.medical_specialty, Activities of daily living, Time Factors, Physiology, Arthroplasty, Replacement, Hip, Movement, 0206 medical engineering, Biomedical Engineering, Biophysics, Wearable computer, 02 engineering and technology, wearable, 03 medical and health sciences, 0302 clinical medicine, Quality of life, TOTAL HIP, ACCELEROMETER, Physiology (medical), Activities of Daily Living, medicine, Humans, Frail elderly, OLDER-PEOPLE, hip arthroplasty, Aged, Monitoring, Physiologic, FALL RISK, Home environment, business.industry, Middle Aged, 020601 biomedical engineering, Gait, Test (assessment), Surgery, timed up and go, hospital discharge, VARIABILITY, PHYSICAL-ACTIVITY, DAILY-LIFE, RELIABILITY, Quality of Life, Female, business, human activities, GAIT, 030217 neurology & neurosurgery, Timed up and go

Abstract

BACKGROUND Mobility impairment is common in older adults and negatively influences the quality of life. Mobility level may change rapidly following surgery or hospitalization in the elderly. The timed up and go (TUG) is a simple, frequently used clinical test for functional mobility; however, TUG requires supervision from a trained clinician, resulting in infrequent assessments. Additionally, assessment by TUG in clinic settings may not be completely representative of the individual's mobility in their home environment. OBJECTIVE In this paper, we introduce a method to estimate TUG from activities detected in free-living, enabling continuous remote mobility monitoring without expert supervision. The method is used to monitor changes in mobility following total hip arthroplasty (THA). METHODS Community-living elderly (n = 239, 65-91 years) performed a standardized TUG in a laboratory and wore a wearable pendant device that recorded accelerometer and barometric sensor data for at least three days. Activities of daily living (ADLs), including walks and sit-to-stand transitions, and their related mobility features were extracted and used to develop a regularized linear model for remote TUG test estimation. Changes in the remote TUG were evaluated in orthopaedic patients (n = 15, 55-75 years), during 12-weeks period following THA. MAIN RESULTS In leave-one-out-cross-validation (LOOCV), a strong correlation (ρ = 0.70) was observed between the new remote TUG and standardized TUG times. Test-retest reliability of 3-days estimates was high (ICC = 0.94). Compared to week 2 post-THA, remote TUG was significantly improved at week 6 (11.7 ± 3.9 s versus 8.0 ± 1.8 s, p

Published

2019

2. Disentangling the health benefits of walking from increased exposure to falls in older people using remote gait monitoring and multi-dimensional analysis

Author

Matthew A. Brodie, Stephen R. Lord, Rainer Wieching, Yoshiro Okubo, Kim Delbaere, and Janneke Annegarn

Subjects

Male, medicine.medical_specialty, Activities of daily living, Physiology, Biomedical Engineering, Biophysics, Psychological intervention, Poison control, Suicide prevention, Risk Assessment, Occupational safety and health, 03 medical and health sciences, Wearable Electronic Devices, 0302 clinical medicine, Physical medicine and rehabilitation, Physiology (medical), Injury prevention, Medicine, Humans, 030212 general & internal medicine, Gait, Aged, Monitoring, Physiologic, Aged, 80 and over, business.industry, Insurance Benefits, Remote Sensing Technology, Physical therapy, Accidental Falls, Female, business, 030217 neurology & neurosurgery, Independent living

Abstract

Falls and physical deconditioning are two major health problems for older people. Recent advances in remote physiological monitoring provide new opportunities to investigate why walking exercise, with its many health benefits, can both increase and decrease fall rates in older people. In this paper we combine remote wearable device monitoring of daily gait with non-linear multi-dimensional pattern recognition analysis; to disentangle the complex associations between walking, health and fall rates. One week of activities of daily living (ADL) were recorded with a wearable device in 96 independent living older people prior to completing 6 months of exergaming interventions. Using the wearable device data; the quantity, intensity, variability and distribution of daily walking patterns were assessed. At baseline, clinical assessments of health, falls, sensorimotor and physiological fall risks were completed. At 6 months, fall rates, sensorimotor and physiological fall risks were re-assessed. A non-linear multi-dimensional analysis was conducted to identify risk-groups according to their daily walking patterns. Four distinct risk-groups were identified: The Impaired (93% fallers), Restrained (8% fallers), Active (50% fallers) and Athletic (4% fallers). Walking was strongly associated with multiple health benefits and protective of falls for the top performing Athletic risk-group. However, in the middle of the spectrum, the Active risk-group, who were more active, younger and healthier were 6.25 times more likely to be fallers than their Restrained counterparts. Remote monitoring of daily walking patterns may provide a new way to distinguish Impaired people at risk of falling because of frailty from Active people at risk of falling from greater exposure to situations were falls could occur, but further validation is required. Wearable device risk-profiling could help in developing more personalised interventions for older people seeking the health benefits of walking without increasing their risk of falls.

Published

2016

3. A comparison of activity classification in younger and older cohorts using a smartphone

Author

Michael B. Del Rosario, Matthew A. Brodie, Ying Liu, Kejia Wang, Kim Delbaere, Jingjing Wang, Stephen R. Lord, Nigel H. Lovell, and Stephen J. Redmond

Subjects

Male, medicine.medical_specialty, Activities of daily living, Time Factors, Physiology, Statistics as Topic, Biomedical Engineering, Biophysics, Monitoring, Ambulatory, Sitting, Cross-validation, Cohort Studies, Young Adult, Physical medicine and rehabilitation, Physiology (medical), Activities of Daily Living, medicine, Pressure, Humans, Simulation, Aged, 80 and over, business.industry, Decision tree learning, Data Collection, Triaxial accelerometer, Decision Trees, Reproducibility of Results, Confidence interval, Activity classification, Cohort, Female, business, Algorithms, Cell Phone

Abstract

Automatic recognition of human activity is useful as a means of estimating energy expenditure and has potential for use in fall detection and prediction. The emergence of the smartphone as a ubiquitous device presents an opportunity to utilize its embedded sensors, computational power and data connectivity as a platform for continuous health monitoring. In the study described herein, 37 older people (83.9 ± 3.4 years) performed a series of activities of daily living (ADLs) while a smartphone (containing a triaxial accelerometer, triaxial gyroscope and barometric pressure sensor) was placed in the front pocket of their trousers. These results are compared to a similar trial conducted previously in which 20 young people (21.9 ± 1.65 years) were asked to perform the same ADLs using the same smartphone (again in the front pocket of their trousers).In each trial, the participants were asked to perform several activities (standing, sitting, lying, walking on level ground, up and down staircases, and riding an elevator up and down) in a free-living environment. During each acquisition session, the internal sensor signals were recorded and subsequently used to develop activity classifiers based on a decision tree algorithm that classified ADL in epochs of ~1.25 s. When training and testing with the younger cohort, using a leave-one-out cross validation procedure, a total classification sensitivity of 80.9% ± 9.57% ([Formula: see text] = 0.75 ± 0.12) was obtained. Retraining and testing on the older cohort, again using cross validation, gives a comparable total class sensitivity of 82.0% ± 8.88% ([Formula: see text] =0.74 ± 0.12).When trained with the younger group and tested on the older group, a total class sensitivity of 69.2% ± 24.8% (95% confidence interval [69.6%, 70.6%]) and [Formula: see text] = 0.60 ± 0.27 (95% confidence interval [0.58, 0.59]) was obtained. When trained on the older group and tested on the younger group, a total class sensitivity of 80.5% ± 6.80% (95% confidence interval [79.0%, 80.6%]) and [Formula: see text] = 0.74 ± 0.08 (95% confidence interval [0.73, 0.75]) was obtained.An instance of the decision tree classifier developed was implemented on the smartphone as a software application. It was capable of performing real-time activity classification for a period of 17 h on a single battery charge, illustrating that smartphone technology provides a viable platform on which to perform long-term activity monitoring.

Published

2014

4. Remote timed up and go evaluation from activities of daily living reveals changing mobility after surgery.

Author

Salvatore Saporito, Matthew Andrew Brodie, Kim Delbaere, Jildou Hoogland, Harmke Nijboer, Sietse Menno Rispens, Gabriele Spina, Martin Stevens, and Janneke Annegarn

Subjects

FRAIL elderly, ACTIVITIES of daily living, TOTAL hip replacement, OLDER people, STATISTICAL reliability, HOME environment

Abstract

Background: Mobility impairment is common in older adults and negatively influences the quality of life. Mobility level may change rapidly following surgery or hospitalization in the elderly. The timed up and go (TUG) is a simple, frequently used clinical test for functional mobility; however, TUG requires supervision from a trained clinician, resulting in infrequent assessments. Additionally, assessment by TUG in clinic settings may not be completely representative of the individual’s mobility in their home environment. Objective: In this paper, we introduce a method to estimate TUG from activities detected in free-living, enabling continuous remote mobility monitoring without expert supervision. The method is used to monitor changes in mobility following total hip arthroplasty (THA). Methods: Community-living elderly (n  =  239, 65–91 years) performed a standardized TUG in a laboratory and wore a wearable pendant device that recorded accelerometer and barometric sensor data for at least three days. Activities of daily living (ADLs), including walks and sit-to-stand transitions, and their related mobility features were extracted and used to develop a regularized linear model for remote TUG test estimation. Changes in the remote TUG were evaluated in orthopaedic patients (n  =  15, 55–75 years), during 12-weeks period following THA. Main results: In leave-one-out-cross-validation (LOOCV), a strong correlation (ρ  =  0.70) was observed between the new remote TUG and standardized TUG times. Test-retest reliability of 3-days estimates was high (ICC  =  0.94). Compared to week 2 post-THA, remote TUG was significantly improved at week 6 (11.7  ±  3.9 s versus 8.0  ±  1.8 s, p   <  0.001), with no further change at 12-weeks (8.1  ±  3.9 s, p   =  0.37). Significance: Remote TUG can be estimated in older adults using 3-days of ADLs data recorded using a wearable pendant. Remote TUG has discriminatory potential for identifying frail elderly and may provide a convenient way to monitor changes in mobility in unsupervised settings. [ABSTRACT FROM AUTHOR]

Published

2019

5. Disentangling the health benefits of walking from increased exposure to falls in older people using remote gait monitoring and multi-dimensional analysis.

Author

Matthew A Brodie, Yoshiro Okubo, Janneke Annegarn, Rainer Wieching, Stephen R Lord, and Kim Delbaere

Subjects

ACCIDENTAL falls in old age, GAIT in humans, PHYSICAL training & conditioning, PATIENT monitoring, ACTIVITIES of daily living

Abstract

Falls and physical deconditioning are two major health problems for older people. Recent advances in remote physiological monitoring provide new opportunities to investigate why walking exercise, with its many health benefits, can both increase and decrease fall rates in older people. In this paper we combine remote wearable device monitoring of daily gait with non-linear multi-dimensional pattern recognition analysis; to disentangle the complex associations between walking, health and fall rates. One week of activities of daily living (ADL) were recorded with a wearable device in 96 independent living older people prior to completing 6 months of exergaming interventions. Using the wearable device data; the quantity, intensity, variability and distribution of daily walking patterns were assessed. At baseline, clinical assessments of health, falls, sensorimotor and physiological fall risks were completed. At 6 months, fall rates, sensorimotor and physiological fall risks were re-assessed. A non-linear multi-dimensional analysis was conducted to identify risk-groups according to their daily walking patterns. Four distinct risk-groups were identified: The Impaired (93% fallers), Restrained (8% fallers), Active (50% fallers) and Athletic (4% fallers). Walking was strongly associated with multiple health benefits and protective of falls for the top performing Athletic risk-group. However, in the middle of the spectrum, the Active risk-group, who were more active, younger and healthier were 6.25 times more likely to be fallers than their Restrained counterparts. Remote monitoring of daily walking patterns may provide a new way to distinguish Impaired people at risk of falling because of frailty from Active people at risk of falling from greater exposure to situations were falls could occur, but further validation is required. Wearable device risk-profiling could help in developing more personalised interventions for older people seeking the health benefits of walking without increasing their risk of falls. [ABSTRACT FROM AUTHOR]

Published

2017