Multi-site identification and generalization of clusters of walking behaviors in individuals with chronic stroke and neurotypical controls

Background Walking patterns in stroke survivors are highly heterogeneous, which poses a challenge in systematizing treatment prescriptions for walking rehabilitation interventions. Objectives We used bilateral spatiotemporal and force data during walking to create a multi-site research sample to: (1) identify clusters of walking behaviors in people post-stroke and neurotypical controls and (2) determine the generalizability of these walking clusters across different research sites. We hypothesized that participants post-stroke will have different walking impairments resulting in different clusters of walking behaviors, which are also different from control participants. Methods We gathered data from 81 post-stroke participants across 4 research sites and collected data from 31 control participants. Using sparse K-means clustering, we identified walking clusters based on 17 spatiotemporal and force variables. We analyzed the biomechanical features within each cluster to characterize cluster-specific walking behaviors. We also assessed the generalizability of the clusters using a leave-one-out approach. Results We identified 4 stroke clusters: a fast and asymmetric cluster, a moderate speed and asymmetric cluster, a slow cluster with frontal plane force asymmetries, and a slow and symmetric cluster. We also identified a moderate speed and symmetric gait cluster composed of controls and participants post-stroke. The moderate speed and asymmetric stroke cluster did not generalize across sites. Conclusions Although post-stroke walking patterns are heterogenous, these patterns can be systematically classified into distinct clusters based on spatiotemporal and force data. Future interventions could target the key features that characterize each cluster to increase the efficacy of interventions to improve mobility in people post-stroke.

[1]  Gordon J. Berman,et al.  Discovering individual-specific gait signatures from data-driven models of neuromechanical dynamics , 2023, bioRxiv.

[2]  James M. Finley,et al.  Speed-dependent biomechanical changes vary across individual gait metrics post-stroke relative to neurotypical adults , 2022, bioRxiv.

[3]  Y. Kim,et al.  Pathological gait clustering in post-stroke patients using motion capture data. , 2022, Gait & posture.

[4]  L. Lisabeth,et al.  Ethnic Differences in Informal Caregiving After Stroke , 2021, Stroke.

[5]  James M. Finley,et al.  Different Biomechanical Variables Explain Within-Subjects Versus Between-Subjects Variance in Step Length Asymmetry Post-Stroke , 2021, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[6]  James M. Finley,et al.  Using Biofeedback to Reduce Step Length Asymmetry Impairs Dynamic Balance in People Poststroke , 2021, Neurorehabilitation and neural repair.

[7]  Dennis R. Louie,et al.  Brain activity during real-time walking and with walking interventions after stroke: a systematic review , 2021, Journal of neuroengineering and rehabilitation.

[8]  G. Torres-Oviedo,et al.  Augmenting propulsion demands during split-belt walking increases locomotor adaptation of asymmetric step lengths , 2020, Journal of NeuroEngineering and Rehabilitation.

[9]  Kristan A. Leech,et al.  Persons post-stroke improve step length symmetry by walking asymmetrically , 2020, Journal of NeuroEngineering and Rehabilitation.

[10]  Jennifer N. Jackson,et al.  National Institutes of Health Research Plan on Rehabilitation: Analysis and Progress. , 2020, Archives of physical medicine and rehabilitation.

[11]  T. Kesar,et al.  Comparison of the Immediate Effects of Audio, Visual, or Audiovisual Gait Biofeedback on Propulsive Force Generation in Able-Bodied and Post-stroke Individuals , 2020, Applied Psychophysiology and Biofeedback.

[12]  J. Nordvik,et al.  Implementation of High-Intensity Stepping Training During Inpatient Stroke Rehabilitation Improves Functional Outcomes , 2019, Stroke.

[13]  Rachel W. Jackson,et al.  Self-selected step length asymmetry is not explained by energy cost minimization in individuals with chronic stroke , 2019, Journal of NeuroEngineering and Rehabilitation.

[14]  G. Torres-Oviedo,et al.  Cerebral Contribution to the Execution, But Not Recalibration, of Motor Commands in a Novel Walking Environment , 2019, eNeuro.

[15]  R. Neptune,et al.  Paretic propulsion as a measure of walking performance and functional motor recovery post-stroke: A review. , 2019, Gait & posture.

[16]  Mathews Jacob,et al.  Bootstrapping estimates of stability for clusters, observations and model selection , 2018, Computational Statistics.

[17]  James M. Finley,et al.  Individual Differences in Locomotor Function Predict the Capacity to Reduce Asymmetry and Modify the Energetic Cost of Walking Poststroke , 2017, bioRxiv.

[18]  Kathleen O'Donnell,et al.  Reducing Circumduction and Hip Hiking During Hemiparetic Walking Through Targeted Assistance of the Paretic Limb Using a Soft Robotic Exosuit , 2017, American journal of physical medicine & rehabilitation.

[19]  J. Leskovec,et al.  Large-scale physical activity data reveal worldwide activity inequality , 2017, Nature.

[20]  T. Kesar,et al.  Effects of unilateral real-time biofeedback on propulsive forces during gait , 2017, Journal of NeuroEngineering and Rehabilitation.

[21]  L. Lisabeth,et al.  Mexican Americans Receive Less Intensive Stroke Rehabilitation Than Non-Hispanic Whites , 2017, Stroke.

[22]  M. Bowden,et al.  A systematic review of mechanisms of gait speed change post-stroke. Part 1: spatiotemporal parameters and asymmetry ratios , 2017, Topics in stroke rehabilitation.

[23]  G. Fulk,et al.  Predicting Home and Community Walking Activity Poststroke , 2017, Stroke.

[24]  J. Higginson,et al.  Mechanisms used to increase peak propulsive force following 12-weeks of gait training in individuals poststroke. , 2016, Journal of biomechanics.

[25]  J. Higginson,et al.  Baseline predictors of treatment gains in peak propulsive force in individuals poststroke , 2016, Journal of NeuroEngineering and Rehabilitation.

[26]  D. Reisman,et al.  The Split-Belt Walking Paradigm: Exploring Motor Learning and Spatiotemporal Asymmetry Poststroke. , 2015, Physical medicine and rehabilitation clinics of North America.

[27]  van der Lucas Woude,et al.  Effects of handrail hold and light touch on energetics, step parameters, and neuromuscular activity during walking after stroke , 2015, Journal of NeuroEngineering and Rehabilitation.

[28]  Amol M Karmarkar,et al.  Geographic and facility variation in inpatient stroke rehabilitation: multilevel analysis of functional status. , 2015, Archives of physical medicine and rehabilitation.

[29]  Jessica L. Allen,et al.  Forward propulsion asymmetry is indicative of changes in plantarflexor coordination during walking in individuals with post-stroke hemiparesis. , 2014, Clinical biomechanics.

[30]  Kelly A Danks,et al.  Repeated Split-Belt Treadmill Training Improves Poststroke Step Length Asymmetry , 2013, Neurorehabilitation and neural repair.

[31]  Chand T. John,et al.  Contributions of muscles to mediolateral ground reaction force over a range of walking speeds. , 2012, Journal of biomechanics.

[32]  J. Freburger,et al.  Disparities in Post-Acute Rehabilitation Care for Stroke , 2011, Archives of physical medicine and rehabilitation.

[33]  R. Neptune,et al.  Comparison of Motor Control Deficits During Treadmill and Overground Walking Poststroke , 2011, Neurorehabilitation and neural repair.

[34]  Richard R Neptune,et al.  Step length asymmetry is representative of compensatory mechanisms used in post-stroke hemiparetic walking. , 2011, Gait & posture.

[35]  Melvyn Roerdink,et al.  Understanding Inconsistent Step-Length Asymmetries Across Hemiplegic Stroke Patients , 2011, Neurorehabilitation and neural repair.

[36]  Robert Tibshirani,et al.  A Framework for Feature Selection in Clustering , 2010, Journal of the American Statistical Association.

[37]  Donald Neumann,et al.  Kinesiology of the Musculoskeletal System : Foundations for Rehabilitation , 2009 .

[38]  Melvyn Roerdink,et al.  On the Relative Contribution of the Paretic Leg to the Control of Posture After Stroke , 2009, Neurorehabilitation and neural repair.

[39]  P. Crenna,et al.  Quantitative comparison of five current protocols in gait analysis. , 2008, Gait & posture.

[40]  J S Higginson,et al.  Two simple methods for determining gait events during treadmill and overground walking using kinematic data. , 2008, Gait & posture.

[41]  C. Winstein,et al.  Effects of Task-Specific Locomotor and Strength Training in Adults Who Were Ambulatory After Stroke: Results of the STEPS Randomized Clinical Trial , 2007, Physical Therapy.

[42]  Christian Hennig,et al.  Cluster-wise assessment of cluster stability , 2007, Comput. Stat. Data Anal..

[43]  D. Reisman,et al.  Locomotor adaptation on a split-belt treadmill can improve walking symmetry post-stroke. , 2007, Brain : a journal of neurology.

[44]  Yong Yin,et al.  Similarity coefficient methods applied to the cell formation problem: A taxonomy and review , 2006 .

[45]  F. Zajac,et al.  Gait differences between individuals with post-stroke hemiparesis and non-disabled controls at matched speeds. , 2005, Gait & posture.

[46]  JoAnne K. Gronley,et al.  Use of cluster analysis for gait pattern classification of patients in the early and late recovery phases following stroke. , 2003, Gait & posture.

[47]  J. Eng,et al.  Symmetry in vertical ground reaction force is accompanied by symmetry in temporal but not distance variables of gait in persons with stroke. , 2003, Gait & posture.

[48]  S. Simon,et al.  Gait Pattern in the Early Recovery Period after Stroke* , 1996, The Journal of bone and joint surgery. American volume.

[49]  S. Olney,et al.  Hemiparetic gait following stroke. Part I: Characteristics , 1996 .

[50]  JoAnne K. Gronley,et al.  Classification of walking handicap in the stroke population. , 1995, Stroke.

[51]  W. Krzanowski,et al.  A Criterion for Determining the Number of Groups in a Data Set Using Sum-of-Squares Clustering , 1988 .

[52]  E Knutsson,et al.  Different types of disturbed motor control in gait of hemiparetic patients. , 1979, Brain : a journal of neurology.

[53]  J. Cutting,et al.  Recognizing friends by their walk: Gait perception without familiarity cues , 1977 .

[54]  Y. Handa,et al.  Assessment of motor function in hemiplegic patients using virtual cycling wheelchair , 2014 .

[55]  Chitralakshmi K. Balasubramanian,et al.  Relationship between step length asymmetry and walking performance in subjects with chronic hemiparesis. , 2007, Archives of physical medicine and rehabilitation.

[56]  R. Tibshirani Regression Shrinkage and Selection via the Lasso , 1996 .

[57]  Y. Benjamini,et al.  Controlling the false discovery rate: a practical and powerful approach to multiple testing , 1995 .

[58]  J. Perry,et al.  Gait Analysis , 2024 .

[59]  T Limbird,et al.  Electromyographic gait assessment, Part 2: Preliminary assessment of hemiparetic synergy patterns. , 1987, Journal of rehabilitation research and development.