Capturing the Cranio-Caudal Signature of a Turn with Inertial Measurement Systems: Methods, Parameters Robustness and Reliability

Background Turning is a challenging mobility task requiring coordination and postural stability. Optimal turning involves a cranio-caudal sequence (i.e., the head initiates the motion, followed by the trunk and the pelvis), which has been shown to be altered in patients with neurodegenerative diseases, such as Parkinson’s disease as well as in fallers and frails. Previous studies have suggested that the cranio-caudal sequence exhibits a specific signature corresponding to the adopted turn strategy. Currently, the assessment of cranio-caudal sequence is limited to biomechanical labs which use camera-based systems; however, there is a growing trend to assess human kinematics with wearable sensors, such as attitude and heading reference systems (AHRS), which enable recording of raw inertial signals (acceleration and angular velocity) from which the orientation of the platform is estimated. In order to enhance the comprehension of complex processes, such as turning, signal modeling can be performed. Aim The current study investigates the use of a kinematic-based model, the sigma-lognormal model, to characterize the turn cranio-caudal signature as assessed with AHRS. Methods Sixteen asymptomatic adults (mean age = 69.1 ± 7.5 years old) performed repeated 10-m Timed-Up-and-Go (TUG) with 180° turns, at varying speed. Head and trunk kinematics were assessed with AHRS positioned on each segments. Relative orientation of the head to the trunk was then computed for each trial and relative angular velocity profile was derived for the turn phase. Peak relative angle (variable) and relative velocity profiles modeled using a sigma-lognormal approach (variables: Neuromuscular command amplitudes and timing parameters) were used to extract and characterize the cranio-caudal signature of each individual during the turn phase. Results The methodology has shown good ability to reconstruct the cranio-caudal signature (signal-to-noise median of 17.7). All variables were robust to speed variations (p > 0.124). Peak relative angle and commanded amplitudes demonstrated moderate to strong reliability (ICC between 0.640 and 0.808). Conclusion The cranio-caudal signature assessed with the sigma-lognormal model appears to be a promising avenue to assess the efficiency of turns.

[2]  Ann Ashburn,et al.  A narrative review of turning deficits in people with Parkinson’s disease , 2015, Disability and rehabilitation.

[3]  Mark A Hollands,et al.  Differences in axial segment reorientation during standing turns predict multiple falls in older adults. , 2012, Gait & posture.

[4]  Kaat Desloovere,et al.  Head‐pelvis coupling is increased during turning in patients with Parkinson's disease and freezing of gait , 2013, Movement disorders : official journal of the Movement Disorder Society.

[5]  Gill Ginsburg,et al.  Human factors engineering: A tool for medical device evaluation in hospital procurement decision-making , 2005, J. Biomed. Informatics.

[6]  Christian O'Reilly,et al.  Recent developments in the study of rapid human movements with the kinematic theory: Applications to handwriting and signature synthesis , 2014, Pattern Recognit. Lett..

[7]  Kamiar Aminian,et al.  The instrumented timed up and go test: potential outcome measure for disease modifying therapies in Parkinson's disease , 2009, Journal of Neurology, Neurosurgery & Psychiatry.

[8]  Antonio I Cuesta-Vargas,et al.  Differences in trunk accelerometry between frail and non-frail elderly persons in functional tasks , 2014, BMC Research Notes.

[9]  R. Plamondon,et al.  Impact of the principal stroke risk factors on human movements. , 2011, Human movement science.

[10]  M. Ferrarin,et al.  Locomotor Function in the Early Stage of Parkinson's Disease , 2007, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[11]  Barriers and Facilitators to Using Knee Gait Analysis Report Findings in Physiotherapy Practice , 2012 .

[12]  Gammon M Earhart,et al.  A Kinematic and Electromyographic Analysis of Turning in People With Parkinson Disease , 2009, Neurorehabilitation and neural repair.

[13]  Réjean Plamondon,et al.  A kinematic theory of rapid human movements , 1995, Biological Cybernetics.

[14]  S. Keller-McNulty,et al.  Reliability , 2007, The SAGE Encyclopedia of Research Design.

[15]  M Rabuffetti,et al.  The association between impaired turning and normal straight walking in Parkinson's disease. , 2007, Gait & posture.

[16]  J. M. Rico-Martinez,et al.  A Simple Method for the Determination of Angular Velocity and Acceleration of a Spherical Motion Through Quaternions , 2000 .

[17]  Laurie A. King,et al.  The quality of turning in Parkinson’s disease: a compensatory strategy to prevent postural instability? , 2016, Journal of NeuroEngineering and Rehabilitation.

[18]  Paolo Mazzoleni,et al.  Locomotor Disorders in Patients at Early Stages of Parkinson's Disease: a Quantitative Analysis , 2006, 2006 International Conference of the IEEE Engineering in Medicine and Biology Society.

[19]  Qingguo Li,et al.  Concurrent validation of Xsens MVN measurement of lower limb joint angular kinematics , 2013, Physiological measurement.

[20]  F. Horak,et al.  Body-worn motion sensors detect balance and gait deficits in people with multiple sclerosis who have normal walking speed. , 2012, Gait & posture.

[21]  C. Blake,et al.  The reliability of the quantitative timed up and go test (QTUG) measured over five consecutive days under single and dual-task conditions in community dwelling older adults. , 2016, Gait & posture.

[22]  Réjean Plamondon,et al.  Time-dependence between upper arm muscles activity during rapid movements: observation of the proportional effects predicted by the kinematic theory. , 2013, Human movement science.

[23]  Patrick Boissy,et al.  The Use of Empirical Mode Decomposition-Based Algorithm and Inertial Measurement Units to Auto-Detect Daily Living Activities of Healthy Adults , 2016, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[24]  R. Plamondon,et al.  Kinematic characteristics of bidirectional delta-lognormal primitives in young and older subjects. , 2011, Human movement science.

[25]  Mahmoud El-Gohary,et al.  Continuous monitoring of turning in Parkinson's disease: Rehabilitation potential. , 2015, NeuroRehabilitation.

[26]  Patrick Boissy,et al.  Wavelet-based algorithm for auto-detection of daily living activities of older adults captured by multiple inertial measurement units (IMUs) , 2016, Physiological measurement.

[27]  Réjean Plamondon,et al.  A kinematic theory of rapid human movements: Part III. Kinetic outcomes , 1998, Biological Cybernetics.

[28]  Laurie A. King,et al.  Do Clinical Scales of Balance Reflect Turning Abnormalities in People With Parkinson's Disease? , 2012, Journal of neurologic physical therapy : JNPT.

[29]  Lori Ann Vallis,et al.  Strategies used by older adults to change travel direction. , 2007, Gait & posture.

[30]  A. E. Patla,et al.  Online steering: coordination and control of body center of mass, head and body reorientation , 1999, Experimental Brain Research.

[31]  E. Rocon,et al.  Locomotor training through a novel robotic platform for gait rehabilitation in pediatric population: short report , 2016, Journal of NeuroEngineering and Rehabilitation.

[32]  Réjean Plamondon,et al.  A kinematic theory of rapid human movement. Part IV: a formal mathematical proof and new insights , 2003, Biological Cybernetics.

[33]  J. Weir Quantifying test-retest reliability using the intraclass correlation coefficient and the SEM. , 2005, Journal of strength and conditioning research.

[34]  T. Hortobágyi,et al.  Multivariate Analyses and Classification of Inertial Sensor Data to Identify Aging Effects on the Timed-Up-and-Go Test , 2016, PloS one.

[35]  Patrick Boissy,et al.  Inertial Measures of Motion for Clinical Biomechanics: Comparative Assessment of Accuracy under Controlled Conditions - Effect of Velocity , 2013, PloS one.

[36]  Patrick Boissy,et al.  Autonomous Quality Control of Joint Orientation Measured with Inertial Sensors , 2016, Sensors.

[37]  Sean Pearson,et al.  Continuous Monitoring of Turning in Patients with Movement Disability , 2013, Sensors.

[38]  Réjean Plamondon,et al.  Linking brain stroke risk factors to human movement features for the development of preventive tools , 2014, Front. Aging Neurosci..

[39]  F. Horak,et al.  Continuous Monitoring of Turning Mobility and Its Association to Falls and Cognitive Function: A Pilot Study. , 2016, The journals of gerontology. Series A, Biological sciences and medical sciences.

[40]  R A Kenny,et al.  Early identification of declining balance in higher functioning older adults, an inertial sensor based method. , 2014, Gait & posture.

[41]  Réjean Plamondon,et al.  A New Algorithm and System for the Characterization of Handwriting Strokes with Delta-Lognormal Parameters , 2009, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[42]  F. Horak,et al.  Analyzing 180° turns using an inertial system reveals early signs of progression of parkinson's disease , 2009, 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[43]  Julia Wagner,et al.  Usability testing in the hospital , 2012 .

[44]  P Cappa,et al.  Experimental evaluation of indoor magnetic distortion effects on gait analysis performed with wearable inertial sensors , 2014, Physiological measurement.

[45]  Réjean Plamondon,et al.  Combining sigma-lognormal modeling and classical features for analyzing graphomotor performances in kindergarten children. , 2015, Human movement science.

[46]  Chris J. Bleakley,et al.  Accurate Orientation Estimation Using AHRS under Conditions of Magnetic Distortion , 2014, Sensors.

[47]  Réjean Plamondon,et al.  Development of a Sigma-Lognormal representation for on-line signatures , 2009, Pattern Recognit..

[48]  Patrick Boissy,et al.  Auto detection and segmentation of physical activities during a Timed-Up-and-Go (TUG) task in healthy older adults using multiple inertial sensors , 2015, Journal of NeuroEngineering and Rehabilitation.

[49]  Réjean Plamondon,et al.  Dynamic Signature Verification System Based on One Real Signature , 2018, IEEE Transactions on Cybernetics.

[50]  Réjean Plamondon,et al.  A kinematic theory of rapid human movements , 1995, Biological Cybernetics.

[51]  R. Plamondon,et al.  Characterization of bi-directional movement primitives and their agonist-antagonist synergy with the delta-lognormal model. , 2010, Motor control.

[52]  Martina Mancini,et al.  Objective biomarkers of balance and gait for Parkinson's disease using body‐worn sensors , 2013, Movement disorders : official journal of the Movement Disorder Society.

[53]  P. Marik,et al.  Narrative Review , 2012, Journal of intensive care medicine.

[54]  D. Roetenberg,et al.  Estimating Body Segment Orientation by Applying Inertial and Magnetic Sensing Near Ferromagnetic Materials , 2007, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[55]  Patrick Boissy,et al.  Inertial measurement systems for segments and joints kinematics assessment: towards an understanding of the variations in sensors accuracy , 2017, BioMedical Engineering OnLine.

[56]  R Plamondon,et al.  Speed/accuracy trade-offs in target-directed movements , 1997, Behavioral and Brain Sciences.

[57]  A. Plamondon,et al.  Optimization of inertial sensor-based motion capturing for magnetically distorted field applications. , 2014, Journal of biomechanical engineering.

[58]  F. Horak,et al.  Role of Body-Worn Movement Monitor Technology for Balance and Gait Rehabilitation , 2014, Physical Therapy.

[59]  Adrian Burns,et al.  An adaptive gyroscope-based algorithm for temporal gait analysis , 2010, Medical & Biological Engineering & Computing.

[60]  F. Horak,et al.  iTUG, a Sensitive and Reliable Measure of Mobility , 2010, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[61]  Michael I. Jordan,et al.  Are arm trajectories planned in kinematic or dynamic coordinates? An adaptation study , 1995, Experimental Brain Research.

[62]  Christian O'Reilly,et al.  The lognormal handwriter: learning, performing, and declining , 2013, Front. Psychol..

[63]  Jeffrey M. Hausdorff,et al.  Properties of the ‘Timed Up and Go’ Test: More than Meets the Eye , 2010, Gerontology.

[64]  Sakineh B Akram,et al.  Effect of walking velocity on segment coordination during pre-planned turns in healthy older adults. , 2010, Gait & posture.

[65]  Pietro Garofalo,et al.  First in vivo assessment of “Outwalk”: a novel protocol for clinical gait analysis based on inertial and magnetic sensors , 2009, Medical & Biological Engineering & Computing.

[66]  Terry K Koo,et al.  A Guideline of Selecting and Reporting Intraclass Correlation Coefficients for Reliability Research. , 2016, Journal Chiropractic Medicine.

[67]  N. A. Zakaria,et al.  Quantitative analysis of fall risk using TUG test , 2015, Computer methods in biomechanics and biomedical engineering.

[68]  Huosheng Hu,et al.  Human motion tracking for rehabilitation - A survey , 2008, Biomed. Signal Process. Control..