Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

At a glance: The STEP trials

A round-up of the STEP phase 3 clinical trials evaluating semaglutide for weight loss in people with overweight or obesity.
ADVANCED SEARCH
Log in
Top
Journal of NeuroEngineering and Rehabilitation
Published in: Journal of NeuroEngineering and Rehabilitation 1/2019

Open Access 01-12-2019 | Research

Rapid energy expenditure estimation for ankle assisted and inclined loaded walking

Authors: Patrick Slade, Rachel Troutman, Mykel J. Kochenderfer, Steven H. Collins, Scott L. Delp

Published in: Journal of NeuroEngineering and Rehabilitation | Issue 1/2019

Login to get access

Abstract

Background

Estimating energy expenditure with indirect calorimetry requires expensive equipment and several minutes of data collection for each condition of interest. While several methods estimate energy expenditure using correlation to data from wearable sensors, such as heart rate monitors or accelerometers, their accuracy has not been evaluated for activity conditions or subjects not included in the correlation process. The goal of our study was to develop data-driven models to estimate energy expenditure at intervals of approximately one second and demonstrate their ability to predict energetic cost for new conditions and subjects. Model inputs were muscle activity and vertical ground reaction forces, which are measurable by wearable electromyography electrodes and pressure sensing insoles.

Methods

We developed models that estimated energy expenditure while walking (1) with ankle exoskeleton assistance and (2) while carrying various loads and walking on inclines. Estimates were made each gait cycle or four second interval. We evaluated the performance of the models for three use cases. The first estimated energy expenditure (in Watts) during walking conditions for subjects with some subject specific training data available. The second estimated all conditions in the dataset for a new subject not included in the training data. The third estimated new conditions for a new subject.

Results

The mean absolute percent errors in estimated energy expenditure during assisted walking conditions were 4.4%, 8.0%, and 8.1% for the three use cases, respectively. The average errors in energy expenditure estimation during inclined and loaded walking conditions were 6.1%, 9.7%, and 11.7% for the three use cases. For models not using subject-specific data, we evaluated the ability to order the magnitude of energy expenditure across conditions. The average percentage of correctly ordered conditions was 63% for assisted walking and 87% for incline and loaded walking.

Conclusions

We have determined the accuracy of estimating energy expenditure with data-driven models that rely on ground reaction forces and muscle activity for three use cases. For experimental use cases where the accuracy of a data-driven model is sufficient and similar training data is available, standard indirect calorimetry could be replaced. The models, code, and datasets are provided for reproduction and extension of our results.
Literature
1.
2.
Torburn L, Powers CM, Guiterrez R, Perry J. Energy expenditure during ambulation in dysvascular and traumatic below-knee amputees: a comparison of five prosthetic feet. J Rehabil Res Dev. 1995; 32:111–9.PubMed
3.
Brouwer B, Parvataneni K, Olney SJ. A comparison of gait biomechanics and metabolic requirements of overground and treadmill walking in people with stroke. Clin Biomech. 2009; 24(9):729–34.CrossRef
4.
Zhang J, Fiers P, Witte KA, Jackson RW, Poggensee KL, Atkeson CG, Collins SH. Human-in-the-loop optimization of exoskeleton assistance during walking. Science. 2017; 356(6344):1280–4.PubMedCrossRef
5.
Felt W, Selinger JC, Donelan MJ, Remy DC. Body-in-the-loop: Optimizing device parameters using measures of instantaneous energetic cost. PLoS ONE. 2015; 10(8).PubMedPubMedCentralCrossRef
6.
Kim M, Ding Y, Malcolm P, Speeckaert J, Siviy CJ, Walsh CJ, Kuindersma S. Human-in-the-loop Bayesian optimization of wearable device parameters. PLoS ONE. 2017; 12(9):1–15.
7.
Ding Y, Kim M, Kuindersma S, Walsh CJ. Human-in-the-loop optimization of hip assistance with a soft exosuit during walking. Sci Robot. 2018; 3(15):eaar5438.CrossRef
8.
Holdy KE. Monitoring energy metabolism with indirect calorimetry: Instruments, interpretation, and clinical application. Nutr Clin Pract. 2004; 19(5):447–54.PubMedCrossRef
9.
Selinger JC, Donelan MJ. Estimating instantaneous energetic cost during non-steady-state gait. J Appl Physiol. 2014; 117(11):1406–15.PubMedCrossRef
10.
Krustrup P, Jones AM, Wilkerson DP, Calbet JA, Bangsbo J. Muscular and pulmonary O 2 uptake kinetics during moderate-and high-intensity sub-maximal knee-extensor exercise in humans. J Physiol. 2009; 587(8):1843–56.PubMedPubMedCentralCrossRef
11.
12.
Van der Walt W, Wyndham C. An equation for prediction of energy expenditure of walking and running. J Appl Physiol. 1973; 34(5):559–63.PubMedCrossRef
13.
Pandolf K, Haisman M, Goldman R. Metabolic energy expenditure and terrain coefficients for walking on snow. Ergonomics. 1976; 19(6):683–90.PubMedCrossRef
14.
Duggan A, Haisman M. Prediction of the metabolic cost of walking with and without loads. Ergonomics. 1992; 35(4):417–26.PubMedCrossRef
15.
Donelan JM, Kram R, Kuo AD. Mechanical work for step-to-step transitions is a major determinant of the metabolic cost of human walking. J Exp Biol. 2002; 205(23):3717–27.PubMed
16.
Kuo AD. Energetics of actively powered locomotion using the simplest walking model. J Biomech Eng. 2002; 124(1):113–20.PubMedCrossRef
17.
18.
Umberger BR, Gerritsen KG, Martin PE. A model of human muscle energy expenditure. Comput Methods Biomech Biomed Eng. 2003; 6(2):99–111.CrossRef
19.
Delp SL, Anderson FC, Arnold AS, Loan P, Habib A, John CT, Guendelman E, Thelen DG. Opensim: Open-source software to create and analyze dynamic simulations of movement. IEEE Trans Biomed Eng. 2007; 54(11):1940–50.PubMedCrossRef
20.
Uchida TK, Seth A, Pouya S, Dembia CL, Hicks JL, Delp SL. Simulating ideal assistive devices to reduce the metabolic cost of running. PLoS ONE. 2016; 11(9):1–19.CrossRef
21.
Dembia CL, Silder A, Uchida TK, Hicks JL, Delp SL. Simulating ideal assistive devices to reduce the metabolic cost of walking with heavy loads. PloS ONE. 2017; 12(7):1–25.CrossRef
22.
Montoye HJ, Washburn R, Servais S, Ertl A, Webster JG, Nagle FJ. Estimation of energy expenditure by a portable accelerometer. Med Sci Sports Exerc. 1983; 15(5):403–7.PubMedCrossRef
23.
Swartz AM, Strath SJ, Bassett DR, O’brien WL, King GA, Ainsworth BE. Estimation of energy expenditure using CSA accelerometers at hip and wrist sites. Med Sci Sports Exerc. 2000; 32(9):450–6.CrossRef
24.
Crouter SE, Churilla JR, Bassett DR. Estimating energy expenditure using accelerometers. Eur J Appl Physiol. 2006; 98(6):601–12.PubMedCrossRef
25.
Heil DP. Predicting activity energy expenditure using the Actical activity monitor. Res Q Exerc Sport. 2006; 77(1):64–80.PubMedCrossRef
26.
Shcherbina A, Mattsson CM, Waggott D, Salisbury H, Christle JW, Hastie T, Wheeler MT, Ashley EA. Accuracy in wrist-worn, sensor-based measurements of heart rate and energy expenditure in a diverse cohort. J Personalized Med. 2017; 7(2):3.CrossRef
27.
Ceesay SM, Prentice AM, Day KC, Murgatroyd PR, Goldberg GR, Scott W, Spurr G. The use of heart rate monitoring in the estimation of energy expenditure: a validation study using indirect whole-body calorimetry. Br J Nutr. 1989; 61(2):175–86.PubMedCrossRef
28.
Brage S, Brage N, Franks PW, Ekelund U, Wong M-Y, Andersen LB, Froberg K, Wareham NJ. Branched equation modeling of simultaneous accelerometry and heart rate monitoring improves estimate of directly measured physical activity energy expenditure. J Appl Physiol. 2004; 96(1):343–51.PubMedCrossRef
29.
Montgomery PG, Green DJ, Etxebarria N, Pyne DB, Saunders PU, Minahan CL. Validation of heart rate monitor-based predictions of oxygen uptake and energy expenditure. J Strength Cond Res. 2009; 23(5):1489–95.PubMedCrossRef
30.
Wakeling JM, Blake OM, Wong I, Rana M, Lee SS. Movement mechanics as a determinate of muscle structure, recruitment and coordination. Phil Trans R Soc London Biol Sci. 2011; 366(1570):1554–64.CrossRef
31.
Silder A, Besier T, Delp SL. Predicting the metabolic cost of incline walking from muscle activity and walking mechanics. J Biomech. 2012; 45(10):1842–9.PubMedPubMedCentralCrossRef
32.
33.
Eston RG, Rowlands AV, Ingledew DK. Validity of heart rate, pedometry, and accelerometry for predicting the energy cost of children’s activities. J Appl Physiol. 1998; 84(1):362–71.PubMedCrossRef
34.
Brage S, Brage N, Franks P, Ekelund U, Wareham N. Reliability and validity of the combined heart rate and movement sensor actiheart. Eur J Clin Nutr. 2005; 59(4):561–70.PubMedCrossRef
35.
Ingraham KA, Ferris DP, Remy CD. Evaluating physiological signal salience for estimating metabolic energy cost from wearable sensors. J Appl Physiol. 2019; 126(3):717–29.PubMedCrossRef
36.
Vyas N, Farringdon J, Andre D, Stivoric JI. Machine learning and sensor fusion for estimating continuous energy expenditure. AI Mag. 2012; 33(2):55–66.CrossRef
37.
Jackson RW, Collins SH. An experimental comparison of the relative benefits of work and torque assistance in ankle exoskeletons. J Appl Physiol. 2015; 119(5):541–57.PubMedCrossRef
38.
Silder A, Delp SL, Besier T. Men and women adopt similar walking mechanics and muscle activation patterns during load carriage. J Biomech. 2013; 46(14):2522–8.PubMedCrossRef
39.
Tao W, Liu T, Zheng R, Feng H. Gait analysis using wearable sensors. Sensors. 2012; 12(2):2255–83.PubMedCrossRef
40.
Brockway J. Derivation of formulae used to calculate energy expenditure in man. Hum Nutr Clin Nutr. 1987; 41(6):463–71.PubMed
41.
Srivastava N, Hinton G, Krizhevsky A, Sutskever I, Salakhutdinov R. Dropout: A simple way to prevent neural networks from overfitting. J Mach Learn Res. 2014; 15(1):1929–58.
42.
43.
Koch M, Lunde L-K, Ernst M, Knardahl S, Veiersted KB. Validity and reliability of pressure-measurement insoles for vertical ground reaction force assessment in field situations. Appl Ergon. 2016; 53:44–51.PubMedCrossRef
44.
Sim T, Kwon H, Oh SE, Joo S-B, Choi A, Heo HM, Kim K, Mun JH. Predicting complete ground reaction forces and moments during gait with insole plantar pressure information using a wavelet neural network. J Biomech Eng. 2015; 137(9):091001.CrossRef
45.
Metadata
Title
Rapid energy expenditure estimation for ankle assisted and inclined loaded walking
Authors
Patrick Slade
Rachel Troutman
Mykel J. Kochenderfer
Steven H. Collins
Scott L. Delp
Publication date
01-12-2019
Publisher
BioMed Central
Published in
Journal of NeuroEngineering and Rehabilitation / Issue 1/2019
Electronic ISSN: 1743-0003
DOI
https://doi.org/10.1186/s12984-019-0535-7

Other articles of this Issue 1/2019

Journal of NeuroEngineering and Rehabilitation 1/2019 Go to the issue

Research

Evaluation of tremor interference with control of voluntary reaching movements in patients with Parkinson’s disease

Review

What is the impact of user affect on motor learning in virtual environments after stroke? A scoping review

Review

Need for mechanically and ergonomically enhanced tremor-suppression orthoses for the upper limb: a systematic review

Research

Bimanual coordination during a physically coupled task in unilateral spastic cerebral palsy children

Research

Actigraph assessment for measuring upper limb activity in unilateral cerebral palsy

Research

Voluntary control of wearable robotic exoskeletons by patients with paresis via neuromechanical modeling