Real-World Gait Detection Using a Wrist-Worn Inertial Sensor: Validation Study

Felix Kluge; Yonatan E Brand; M Encarna Micó-Amigo; Stefano Bertuletti; Ilaria D'Ascanio; Eran Gazit; Tecla Bonci; Cameron Kirk; Arne Küderle; Luca Palmerini; Anisoara Paraschiv-Ionescu; Francesca Salis; Abolfazl Soltani; Martin Ullrich; Lisa Alcock; Kamiar Aminian; Clemens Becker; Philip Brown; Joren Buekers; Anne-Elie Carsin; Marco Caruso; Brian Caulfield; Andrea Cereatti; Lorenzo Chiari; Carlos Echevarria; Bjoern Eskofier; Jordi Evers; Judith Garcia-Aymerich; Tilo Hache; Clint Hansen; Jeffrey M Hausdorff; Hugo Hiden; Emily Hume; Alison Keogh; Sarah Koch; Walter Maetzler; Dimitrios Megaritis; Martijn Niessen; Or Perlman; Lars Schwickert; Kirsty Scott; Basil Sharrack; David Singleton; Beatrix Vereijken; Ioannis Vogiatzis; Alison Yarnall; Lynn Rochester; Claudia Mazzà; Silvia Del Din; Arne Mueller

doi:10.2196/50035

Real-World Gait Detection Using a Wrist-Worn Inertial Sensor: Validation Study

JMIR Form Res. 2024 May 1:8:e50035. doi: 10.2196/50035.

Authors

Felix Kluge¹, Yonatan E Brand², M Encarna Micó-Amigo³, Stefano Bertuletti⁴, Ilaria D'Ascanio⁵, Eran Gazit⁶, Tecla Bonci⁷, Cameron Kirk³, Arne Küderle⁸, Luca Palmerini^{5

9}, Anisoara Paraschiv-Ionescu¹⁰, Francesca Salis⁴, Abolfazl Soltani¹⁰, Martin Ullrich⁸, Lisa Alcock^{3

11}, Kamiar Aminian¹⁰, Clemens Becker^{12

13}, Philip Brown¹⁴, Joren Buekers^{15

16

17}, Anne-Elie Carsin^{15

16

17}, Marco Caruso⁴, Brian Caulfield^{18

19}, Andrea Cereatti⁴, Lorenzo Chiari^{5

9}, Carlos Echevarria^{3

20}, Bjoern Eskofier⁸, Jordi Evers²¹, Judith Garcia-Aymerich^{15

16

17}, Tilo Hache¹, Clint Hansen²², Jeffrey M Hausdorff^{6

23

24

25

26}, Hugo Hiden¹⁴, Emily Hume²⁷, Alison Keogh^{18

19}, Sarah Koch^{15

16

17}, Walter Maetzler²², Dimitrios Megaritis²⁷, Martijn Niessen²¹, Or Perlman^{2

23}, Lars Schwickert¹², Kirsty Scott⁷, Basil Sharrack^{28

29}, David Singleton^{18

19}, Beatrix Vereijken³⁰, Ioannis Vogiatzis²⁷, Alison Yarnall^{3

11

14}, Lynn Rochester^{3

11

14}, Claudia Mazzà⁷, Silvia Del Din^{3

11}, Arne Mueller¹

Affiliations

¹ Novartis Biomedical Research, Novartis Pharma AG, Basel, Switzerland.
² Department of Biomedical Engineering, Tel Aviv University, Tel Aviv, Israel.
³ Translational and Clinical Research Institute, Faculty of Medical Sciences, Newcastle University, Newcastle upon Tyne, United Kingdom.
⁴ Department of Electronics and Telecommunications, Politecnico di Torino, Turin, Italy.
⁵ Department of Electrical, Electronic and Information Engineering, University of Bologna, Bologna, Italy.
⁶ Center for the Study of Movement, Cognition and Mobility, Neurological Institute, Tel Aviv Sourasky Medical Center, Tel Aviv, Israel.
⁷ Department of Mechanical Engineering and Insigneo Institute for In Silico Medicine, The University of Sheffield, Sheffield, United Kingdom.
⁸ Machine Learning and Data Analytics Lab, Department of Artificial Intelligence in Biomedical Engineering, Friedrich-Alexander-Universität Erlangen-Nürnberg, Erlangen, Germany.
⁹ Health Sciences and Technologies-Interdepartmental Center for Industrial Research (CIRI-SDV), University of Bologna, Bologna, Italy.
¹⁰ Laboratory of Movement Analysis and Measurement, Ecole Polytechnique Federale de Lausanne, Lausanne, Switzerland.
¹¹ National Institute for Health and Care Research (NIHR) Newcastle Biomedical Research Centre (BRC), Newcastle University and The Newcastle upon Tyne Hospitals NHS Foundation Trust, Newcastle upon Tyne, United Kingdom.
¹² Robert Bosch Gesellschaft für Medizinische Forschung, Stuttgart, Germany.
¹³ Unit Digitale Geriatrie, Universitätsklinikum Heidelberg, Heidelberg, Germany.
¹⁴ The Newcastle upon Tyne Hospitals NHS Foundation Trust, Newcastle upon Tyne, United Kingdom.
¹⁵ Barcelona Institute for Global Health (ISGlobal), Barcelona, Spain.
¹⁶ Universitat Pompeu Fabra, Barcelona, Spain.
¹⁷ CIBER Epidemiología y Salud Pública (CIBERESP), Madrid, Spain.
¹⁸ Insight Centre for Data Analytics, University College Dublin, Dublin, Ireland.
¹⁹ School of Public Health, Physiotherapy and Sports Science, University College Dublin, Dublin, Ireland.
²⁰ Newcastle upon Tyne Hospitals NHS Foundation Trust, Newcastle upon Tyne, United Kingdom.
²¹ McRoberts BV, The Hague, Netherlands.
²² Department of Neurology, University Medical Center Schleswig-Holstein Campus Kiel, Kiel, Germany.
²³ Sagol School of Neuroscience, Tel Aviv University, Tel Aviv, Israel.
²⁴ Department of Physical Therapy, Faculty of Medical & Health Sciences, Tel Aviv University, Tel Aviv, Israel.
²⁵ Rush Alzheimer's Disease Center, Rush University Medical Center, Chicago, IL, United States.
²⁶ Department of Orthopaedic Surgery, Rush Medical College, Chicago, IL, United States.
²⁷ Department of Sport, Exercise and Rehabilitation, Northumbria University Newcastle, Newcastle upon Tyne, United Kingdom.
²⁸ Department of Neuroscience, The University of Sheffield, Sheffield, United Kingdom.
²⁹ Sheffield NIHR Translational Neuroscience BRC, Sheffield Teaching Hospitals NHS Foundation Trust, Sheffield, United Kingdom.
³⁰ Department of Neuromedicine and Movement Science, Norwegian University of Science and Technology, Trondheim, Norway.

PMID: 38691395
DOI: 10.2196/50035

Abstract

Background: Wrist-worn inertial sensors are used in digital health for evaluating mobility in real-world environments. Preceding the estimation of spatiotemporal gait parameters within long-term recordings, gait detection is an important step to identify regions of interest where gait occurs, which requires robust algorithms due to the complexity of arm movements. While algorithms exist for other sensor positions, a comparative validation of algorithms applied to the wrist position on real-world data sets across different disease populations is missing. Furthermore, gait detection performance differences between the wrist and lower back position have not yet been explored but could yield valuable information regarding sensor position choice in clinical studies.

Objective: The aim of this study was to validate gait sequence (GS) detection algorithms developed for the wrist position against reference data acquired in a real-world context. In addition, this study aimed to compare the performance of algorithms applied to the wrist position to those applied to lower back-worn inertial sensors.

Methods: Participants with Parkinson disease, multiple sclerosis, proximal femoral fracture (hip fracture recovery), chronic obstructive pulmonary disease, and congestive heart failure and healthy older adults (N=83) were monitored for 2.5 hours in the real-world using inertial sensors on the wrist, lower back, and feet including pressure insoles and infrared distance sensors as reference. In total, 10 algorithms for wrist-based gait detection were validated against a multisensor reference system and compared to gait detection performance using lower back-worn inertial sensors.

Results: The best-performing GS detection algorithm for the wrist showed a mean (per disease group) sensitivity ranging between 0.55 (SD 0.29) and 0.81 (SD 0.09) and a mean (per disease group) specificity ranging between 0.95 (SD 0.06) and 0.98 (SD 0.02). The mean relative absolute error of estimated walking time ranged between 8.9% (SD 7.1%) and 32.7% (SD 19.2%) per disease group for this algorithm as compared to the reference system. Gait detection performance from the best algorithm applied to the wrist inertial sensors was lower than for the best algorithms applied to the lower back, which yielded mean sensitivity between 0.71 (SD 0.12) and 0.91 (SD 0.04), mean specificity between 0.96 (SD 0.03) and 0.99 (SD 0.01), and a mean relative absolute error of estimated walking time between 6.3% (SD 5.4%) and 23.5% (SD 13%). Performance was lower in disease groups with major gait impairments (eg, patients recovering from hip fracture) and for patients using bilateral walking aids.

Conclusions: Algorithms applied to the wrist position can detect GSs with high performance in real-world environments. Those periods of interest in real-world recordings can facilitate gait parameter extraction and allow the quantification of gait duration distribution in everyday life. Our findings allow taking informed decisions on alternative positions for gait recording in clinical studies and public health.

Trial registration: ISRCTN Registry 12246987; https://www.isrctn.com/ISRCTN12246987.

International registered report identifier (irrid): RR2-10.1136/bmjopen-2021-050785.

Keywords: Mobilise-D; accelerometer; digital health; digital mobility outcomes; inertial measurement unit; validation; walking; wearable sensor.

©Felix Kluge, Yonatan E Brand, M Encarna Micó-Amigo, Stefano Bertuletti, Ilaria D'Ascanio, Eran Gazit, Tecla Bonci, Cameron Kirk, Arne Küderle, Luca Palmerini, Anisoara Paraschiv-Ionescu, Francesca Salis, Abolfazl Soltani, Martin Ullrich, Lisa Alcock, Kamiar Aminian, Clemens Becker, Philip Brown, Joren Buekers, Anne-Elie Carsin, Marco Caruso, Brian Caulfield, Andrea Cereatti, Lorenzo Chiari, Carlos Echevarria, Bjoern Eskofier, Jordi Evers, Judith Garcia-Aymerich, Tilo Hache, Clint Hansen, Jeffrey M Hausdorff, Hugo Hiden, Emily Hume, Alison Keogh, Sarah Koch, Walter Maetzler, Dimitrios Megaritis, Martijn Niessen, Or Perlman, Lars Schwickert, Kirsty Scott, Basil Sharrack, David Singleton, Beatrix Vereijken, Ioannis Vogiatzis, Alison Yarnall, Lynn Rochester, Claudia Mazzà, Silvia Del Din, Arne Mueller. Originally published in JMIR Formative Research (https://formative.jmir.org), 01.05.2024.