Digital Biomarkers of Physical Frailty and Frailty Phenotypes Using Sensor-Based Physical Activity and Machine Learning

Remote monitoring of physical frailty is important to personalize care for slowing down the frailty process and/or for the healthy recovery of older adults following acute or chronic stressors. Taking the Fried frailty criteria as a reference to determine physical frailty and frailty phenotypes (slowness, weakness, exhaustion, inactivity), this study aimed to explore the benefit of machine learning to determine the least number of digital biomarkers of physical frailty measurable from a pendant sensor during activities of daily living. Two hundred and fifty-nine older adults were classified into robust or pre-frail/frail groups based on the physical frailty assessments by the Fried frailty criteria. All participants wore a pendant sensor at the sternum level for 48 h. Of seventeen sensor-derived features extracted from a pendant sensor, fourteen significant features were used for machine learning based on logistic regression modeling and a recursive feature elimination technique incorporating bootstrapping. The combination of percentage time standing, percentage time walking, walking cadence, and longest walking bout were identified as optimal digital biomarkers of physical frailty and frailty phenotypes. These findings suggest that a combination of sensor-measured exhaustion, inactivity, and speed have potential to screen and monitor people for physical frailty and frailty phenotypes.

[1]  T. Strandberg,et al.  Frailty in elderly people , 2007, The Lancet.

[2]  Javad Razjouyan,et al.  Wearable Sensors and the Assessment of Frailty among Vulnerable Older Adults: An Observational Cohort Study , 2018, Sensors.

[3]  Michael Schwenk,et al.  Frailty and Technology: A Systematic Review of Gait Analysis in Those with Frailty , 2013, Gerontology.

[4]  I. McDowell,et al.  A global clinical measure of fitness and frailty in elderly people , 2005, Canadian Medical Association Journal.

[5]  Jenny Ploeg,et al.  Interventions to prevent or reduce the level of frailty in community-dwelling older adults: a scoping review of the literature and international policies , 2017, Age and ageing.

[6]  N. Fedarko The biology of aging and frailty. , 2011, Clinics in geriatric medicine.

[7]  J. Mandrekar Receiver operating characteristic curve in diagnostic test assessment. , 2010, Journal of thoracic oncology : official publication of the International Association for the Study of Lung Cancer.

[8]  Eftim Zdravevski,et al.  Literature on Wearable Technology for Connected Health: Scoping Review of Research Trends, Advances, and Barriers , 2019, Journal of medical Internet research.

[9]  Chiu-Hsieh Hsu,et al.  Frailty assessment in older adults using upper-extremity function: index development , 2017, BMC Geriatrics.

[10]  L. Fried,et al.  Frailty in older adults: evidence for a phenotype. , 2001, The journals of gerontology. Series A, Biological sciences and medical sciences.

[11]  Xiaodong Li,et al.  Iterated feature selection algorithms with layered recurrent neural network for software fault prediction , 2019, Expert Syst. Appl..

[12]  Bijan Najafi,et al.  Digital Biomarker Representing Frailty Phenotypes: The Use of Machine Learning and Sensor-Based Sit-to-Stand Test , 2021, Sensors.

[13]  Andrew P. Bradley,et al.  The use of the area under the ROC curve in the evaluation of machine learning algorithms , 1997, Pattern Recognit..

[14]  Matteo Cesari,et al.  Frailty consensus: a call to action. , 2013, Journal of the American Medical Directors Association.

[15]  Stephen Kirk,et al.  The Wearables Revolution: Is Standardization a Help or a Hindrance?: Mainstream technology or just a passing phase? , 2014, IEEE Consumer Electronics Magazine.

[16]  D A Bennett,et al.  Change in Frailty and Risk of Death in Older Persons , 2009, Experimental aging research.

[17]  S. Conroy,et al.  Managing frailty as a long-term condition. , 2015, Age and ageing.

[18]  Michael Schwenk,et al.  Wearable Sensor-Based In-Home Assessment of Gait, Balance, and Physical Activity for Discrimination of Frailty Status: Baseline Results of the Arizona Frailty Cohort Study , 2014, Gerontology.

[19]  M. Kenward,et al.  An Introduction to the Bootstrap , 2007 .

[20]  Barry R Greene,et al.  Frailty status can be accurately assessed using inertial sensors and the TUG test. , 2014, Age and ageing.

[21]  Ignacio Ara,et al.  Frailty is associated with objectively assessed sedentary behaviour patterns in older adults: Evidence from the Toledo Study for Healthy Aging (TSHA) , 2017, PloS one.

[22]  Bijan Najafi,et al.  Assessing Upper Extremity Motion: An Innovative Method to Identify Frailty , 2015, Journal of the American Geriatrics Society.

[23]  Z. Ademi,et al.  Global Incidence of Frailty and Prefrailty Among Community-Dwelling Older Adults , 2019, JAMA Network Open.

[24]  N. Sirven,et al.  Screening for frailty: older populations and older individuals , 2016, Public Health Reviews.

[25]  Kamiar Aminian,et al.  Quantification of everyday motor function in a geriatric population. , 2007, Journal of rehabilitation research and development.

[26]  Bijan Najafi,et al.  Postural Transitions during Activities of Daily Living Could Identify Frailty Status: Application of Wearable Technology to Identify Frailty during Unsupervised Condition , 2017, Gerontology.

[27]  W. Zhu,et al.  Making bootstrap statistical inferences: a tutorial. , 1997, Research quarterly for exercise and sport.

[28]  K. Rockwood,et al.  Frailty in older adults: Implications for end-of-life care , 2013, Cleveland Clinic Journal of Medicine.

[29]  Kenneth Rockwood,et al.  The association between sedentary behaviour, moderate-vigorous physical activity and frailty , 2014 .

[30]  Bijan Najafi,et al.  Toward Using a Smartwatch to Monitor Frailty in a Hospital Setting: Using a Single Wrist-Wearable Sensor to Assess Frailty in Bedbound Inpatients , 2017, Gerontology.

[31]  F. S. Orlandi,et al.  Instruments for the detection of frailty syndrome in older adults: A systematic review , 2019, PloS one.

[32]  R. Varadhan,et al.  Frailty in Older Adults: A Nationally Representative Profile in the United States. , 2015, The journals of gerontology. Series A, Biological sciences and medical sciences.

[33]  J. Walston,et al.  Frailty Screening and Interventions: Considerations for Clinical Practice. , 2018, Clinics in geriatric medicine.

[34]  K. Walters,et al.  Prevalence of frailty and prefrailty among community-dwelling older adults in low-income and middle-income countries: a systematic review and meta-analysis , 2018, BMJ Open.

[35]  Christina K. Nguyen,et al.  Toward Remote Assessment of Physical Frailty Using Sensor-based Sit-to-stand Test. , 2021, The Journal of surgical research.

[36]  Jacob Cohen Statistical Power Analysis for the Behavioral Sciences , 1969, The SAGE Encyclopedia of Research Design.

[37]  G. Kojima Frailty as a Predictor of Emergency Department Utilization among Community-Dwelling Older People: A Systematic Review and Meta-Analysis. , 2019, Journal of the American Medical Directors Association.

[38]  Figen Tokuçoğlu Monitoring Physical Activity with Wearable Technologies. , 2018, Noro psikiyatri arsivi.

[39]  Xiaodan Niu,et al.  Impacts of frailty on health care costs among community-dwelling older adults: A meta-analysis of cohort studies. , 2021, Archives of gerontology and geriatrics.

[40]  E. Hoogendijk,et al.  Frailty measurement in research and clinical practice: A review. , 2016, European journal of internal medicine.

[41]  Job G. Godino,et al.  Frailty assessment instruments: Systematic characterization of the uses and contexts of highly-cited instruments , 2016, Ageing Research Reviews.

[42]  Julius Griškevičius,et al.  Wearable Sensors Technology as a Tool for Discriminating Frailty Levels During Instrumented Gait Analysis , 2020 .

[43]  Q. Xue The frailty syndrome: definition and natural history. , 2011, Clinics in geriatric medicine.

[44]  P. Lachenbruch Statistical Power Analysis for the Behavioral Sciences (2nd ed.) , 1989 .