Assessing the influence of a passive, upper extremity exoskeletal vest for tasks requiring arm elevation: Part II - "Unexpected" effects on shoulder motion, balance, and spine loading.

Adopting a new technology (exoskeletal vest designed to support overhead work) in the workplace can be challenging since the technology may pose unexpected safety and health consequences. A prototype exoskeletal vest was evaluated for potential unexpected consequences with a set of evaluation tests for: usability (especially, donning & doffing), shoulder range of motion (ROM), postural control, slip & trip risks, and spine loading during overhead work simulations. Donning/doffing the vest was easily done by a wearer alone. The vest reduced the max. shoulder abduction ROM by ∼10%, and increased the mean center of pressure velocity in the anteroposterior direction by ∼12%. However, vest use had minimal influences on trip-/slip-related fall risks during level walking, and significantly reduced spine loadings (up to ∼30%) especially during the drilling task. Use of an exoskeletal vest can be beneficial, yet the current evaluation tests should be expanded for more comprehensiveness, to enable the safe adoption of the technology.

[1]  Kari L Loverro,et al.  Location of minimum foot clearance on the shoe and with respect to the obstacle changes with locomotor task. , 2013, Journal of biomechanics.

[2]  M. Madigan,et al.  Age-related differences in peak joint torques during the support phase of single-step recovery from a forward fall. , 2005, The journals of gerontology. Series A, Biological sciences and medical sciences.

[3]  Darja Rugelj,et al.  The effect of load mass and its placement on postural sway. , 2011, Applied ergonomics.

[4]  Frank Krause,et al.  Exoskeletons for industrial application and their potential effects on physical work load , 2016, Ergonomics.

[5]  N. M. Blonien,et al.  COMPARISON OF JOINT KINEMATICS, JOINT KINETICS, AND EMG PATTERNS FOR TREADMILL VERSUS OVER-GROUND GAIT , 2006 .

[6]  T. Lockhart,et al.  The effects of 10% front load carriage on the likelihood of slips and falls. , 2008, Industrial health.

[7]  Masayoshi Kubo,et al.  Increased musculoskeletal stiffness during load carriage at increasing walking speeds maintains constant vertical excursion of the body center of mass. , 2003, Journal of biomechanics.

[8]  J. Hidler,et al.  Joint Moments Exhibited by Chronic Stroke Subjects While Walking with a Prescribed Physiological Gait Pattern , 2006, 2007 IEEE 10th International Conference on Rehabilitation Robotics.

[9]  J. Dufek,et al.  Kinematic and ground reaction force accommodation during weighted walking. , 2015, Human movement science.

[10]  S. Delp,et al.  Men and women adopt similar walking mechanics and muscle activation patterns during load carriage. , 2013, Journal of biomechanics.

[11]  S. Horgan,et al.  Solving the surgeon ergonomic crisis with surgical exosuit , 2017, Surgical Endoscopy.

[12]  Chang-Soo Han,et al.  The technical trend of the exoskeleton robot system for human power assistance , 2012 .

[13]  Frans C. T. van der Helm,et al.  Influence of attachment pressure and kinematic configuration on pHRI with wearable robots , 2009 .

[14]  Maury A. Nussbaum,et al.  Low back injury risks during construction with prefabricated (panelised) walls: effects of task and design factors , 2011, Ergonomics.

[15]  Maria Pia Cavatorta,et al.  Analysis of Exoskeleton Introduction in Industrial Reality: Main Issues and EAWS Risk Assessment , 2017, AHFE.

[16]  I. Kingma,et al.  Armed against falls: the contribution of arm movements to balance recovery after tripping , 2010, Experimental Brain Research.

[17]  Yijian Zhang,et al.  A Review of exoskeleton-type systems and their key technologies , 2008 .

[18]  Sudhakar Rajulu,et al.  An Ergonomic Evaluation of the Extravehicular Mobility Unit (EMU) Spacesuit Hard Upper Torso (HUT) Size Effect on Mobility, Strength, and Metabolic Performance , 2014 .

[19]  Xingda Qu,et al.  Effects of external loads on balance control during upright stance: experimental results and model-based predictions. , 2009, Gait & posture.

[20]  Xueke Wang,et al.  Biomechanical evaluation of exoskeleton use on loading of the lumbar spine. , 2018, Applied ergonomics.

[21]  T. Lockhart,et al.  Required coefficient of friction during turning at self-selected slow, normal, and fast walking speeds. , 2014, Journal of biomechanics.

[22]  Hae-Young Kim Statistical notes for clinical researchers: Evaluation of measurement error 1: using intraclass correlation coefficients , 2013, Restorative dentistry & endodontics.

[23]  D. Cicchetti,et al.  Developing criteria for establishing interrater reliability of specific items: applications to assessment of adaptive behavior. , 1981, American journal of mental deficiency.

[24]  Maury A. Nussbaum,et al.  Assessing the influence of a passive, upper extremity exoskeletal vest for tasks requiring arm elevation: Part I - "Expected" effects on discomfort, shoulder muscle activity, and work task performance. , 2018, Applied ergonomics.

[25]  D Ichbiah Jean 5487616 Method for designing an ergonomic one-finger keyboard and apparatus thereof , 1996 .

[26]  M. de Looze,et al.  The effects of a passive exoskeleton on muscle activity, discomfort and endurance time in forward bending work. , 2016, Applied ergonomics.

[27]  Bryan Buchholz,et al.  ISB recommendation on definitions of joint coordinate systems of various joints for the reporting of human joint motion--Part II: shoulder, elbow, wrist and hand. , 2005, Journal of biomechanics.

[28]  J P Bonde,et al.  Work related shoulder disorders: quantitative exposure-response relations with reference to arm posture , 2004, Occupational and Environmental Medicine.

[29]  Tzu-Hsien Lee,et al.  An investigation of stability limits while holding a load , 2003, Ergonomics.

[30]  A. Patla,et al.  Role of the unperturbed limb and arms in the reactive recovery response to an unexpected slip during locomotion. , 2003, Journal of neurophysiology.

[31]  Dhurjati Majumdar,et al.  Effects of military load carriage on kinematics of gait , 2010, Ergonomics.

[32]  B. E. Maki,et al.  Early activation of arm muscles follows external perturbation of upright stance , 1995, Neuroscience Letters.

[33]  B. E. Maki,et al.  Does the "eyes lead the hand" principle apply to reach-to-grasp movements evoked by unexpected balance perturbations? , 2011, Human movement science.

[34]  Motoki Kouzaki,et al.  Importance of body sway velocity information in controlling ankle extensor activities during quiet stance. , 2003, Journal of neurophysiology.

[35]  Jaap H van Dieën,et al.  Effects of constrained trunk movement on frontal plane gait kinematics. , 2016, Journal of biomechanics.

[36]  Kevin Desbrosses,et al.  Physiological consequences of using an upper limb exoskeleton during manual handling tasks. , 2018, Applied ergonomics.

[37]  Robert Bogue,et al.  Exoskeletons and robotic prosthetics: a review of recent developments , 2009, Ind. Robot.

[38]  M. Grabiner,et al.  Variation in trunk kinematics influences variation in step width during treadmill walking by older and younger adults. , 2010, Gait & posture.

[39]  Maury A. Nussbaum,et al.  An EMG-based model to estimate lumbar muscle forces and spinal loads during complex, high-effort tasks: Development and application to residential construction using prefabricated walls , 2011 .

[40]  T.E. Prieto,et al.  Measures of postural steadiness: differences between healthy young and elderly adults , 1996, IEEE Transactions on Biomedical Engineering.

[41]  Michael J Agnew,et al.  Ergonomic evaluation of a wearable assistive device for overhead work , 2014, Ergonomics.

[42]  R. Rittner,et al.  Exposure-response relationships for work-related neck and shoulder musculoskeletal disorders--Analyses of pooled uniform data sets. , 2016, Applied ergonomics.

[43]  M. P. Mcguigan,et al.  The role of arm movement in early trip recovery in younger and older adults. , 2008, Gait & posture.