Reduction in the metabolic cost of human walking gaits using quasi-passive upper body exoskeleton

The metabolic cost of walking in healthy individuals increases with spatiotemporal gait asymmetries. Pathological gait, such as post-stroke, often has asymmetry in step lengths and step times which may contribute to an increased energy cost. But paradoxically, enforcing step length symmetry does not reduce metabolic cost of post-stroke walking. The isolated and interacting costs of asymmetry in step times and step lengths remain unclear, because previous studies did not simultaneously enforce spatial and temporal gait asymmetries. Here, we delineate isolated costs of asymmetry in step times and step lengths in healthy human walking. We first show that the cost of step length asymmetry is predicted by the cost of taking two non-preferred step lengths (one short and one long), but that step time asymmetry adds an extra cost beyond the cost of non-preferred step times. The metabolic power of step time asymmetry is about 2.5 times greater than the cost of step length asymmetry. Furthermore, the costs are not additive when walking with asymmetric step times and step lengths: metabolic power of concurrent asymmetry in step lengths and step times is driven by the cost of step time asymmetry alone. The metabolic power of asymmetry is explained by positive mechanical power produced during single support phases to compensate for a net loss of center of mass power incurred during double support phases. These data may explain why metabolic cost remains invariant to step length asymmetry in post-stroke walking and suggests how effects of asymmetry on energy cost can be attenuated.

Download Full-text

An Approach to Human Walking Analysis Based on Balance, Symmetry and Stability Using COG, ZMP and CP

Applied Sciences ◽

10.3390/app10207307 ◽

2020 ◽

Vol 10 (20) ◽

pp. 7307

Author(s):

Seonghye Kim ◽

Toshiyuki Murakami

Keyword(s):

Personal Characteristic ◽

Center Of Gravity ◽

Lower Limbs ◽

Upper Body ◽

Human Walking ◽

Joint Rotation ◽

Gait Parameters ◽

Zero Moment ◽

Crossing Point

The parameters of walking have been studied from the viewpoints of joint rotation and translation of body. The balance and symmetry of walking are indispensable features to understand for healthy walking, while also being a personal characteristic. However, quantification has not been easy to carry out in the case of the conventional gait parameters COG (center of gravity) and ZMP (zero moment point). In this approach, the CP (crossing point) is proposed to quantify the concept of symmetry and balance by comparing it to the COG and ZMP. The CP is estimated based on the intersection between the hip line and the ankle line. While the hip line is fixed on the upper body where the COG is, the ankle line is altered depending on the each footfall, where the ZMP is. Therefore, the values of COG, ZMP, and CP have similar or different tendencies in terms of whether balanced walking results in symmetry or not. The validity of this is verified by carrying out a simulation with robot walking, and an experiment using human walking. Through additional experiments, it was noticed that the CP was able to improve the role of COG and ZMP in terms of not only stability, but also its relationship with the movement range of the lower limbs.

Download Full-text

Second Spine: Upper Body Assistive Device for Human Load Carriage

Journal of Mechanisms and Robotics ◽

10.1115/1.4029293 ◽

2015 ◽

Vol 7 (1) ◽

Cited By ~ 5

Author(s):

Joon-Hyuk Park ◽

Xin Jin ◽

Sunil K. Agrawal

Keyword(s):

Human Motion ◽

Musculoskeletal Injuries ◽

Load Carriage ◽

Assistive Device ◽

Upper Body ◽

Human Walking ◽

Inertia Force ◽

Concept Design ◽

Test Bed ◽

Heavy Load

This study presents the development of second spine, an upper body assistive device for human load carriage. The motivation comes from reducing musculoskeletal injuries caused by carrying a heavy load on the upper body. Our aim was to design a wearable upper body device that can prevent musculoskeletal injuries during human load carriage by providing a secondary load pathway—second spine—to transfer the loads from shoulders to pelvis while also allowing a good range of torso motion to the wearer. Static analysis of the backpack and the second spine was first performed to investigate the feasibility of our concept design. The development of second spine had two considerations: load distribution between shoulders and pelvis, and preserving the range of torso motion. The design was realized using load bearing columns between the shoulder support and hip belt, comprising multiple segments interconnected by cone-shaped joints. The performance of second spine was evaluated through experimental study, and its biomechanical effects on human loaded walking were also assessed. Based on the findings from second spine evaluation, we proposed the design of a motorized second spine which aims to compensate the inertia force of a backpack induced by human walking through active load modulation. This was achieved by real-time sensing of human motion and actuating the motors in a way that the backpack motion is kept nearly inertially fixed. Simulation study was carried out to determine the proper actuation of motors in response to the human walking kinematics. The performance of motorized second spine was evaluated through an instrumented test-bed using Instron machine. Results showed a good agreement with simulation. It was shown that the backpack motion can be made nearly stationary with respect to the ground which can further enhance the effectiveness of the device in assisting human load carriage.

Download Full-text

Effects of aging and arm swing on the metabolic cost of stability in human walking

Journal of Biomechanics ◽

10.1016/j.jbiomech.2008.06.039 ◽

2008 ◽

Vol 41 (16) ◽

pp. 3303-3308 ◽

Cited By ~ 127

Author(s):

Justus D. Ortega ◽

Leslie A. Fehlman ◽

Claire T. Farley

Keyword(s):

Metabolic Cost ◽

Human Walking ◽

Arm Swing ◽

Effects Of Aging

Download Full-text

Metabolic Cost of Upper Body Torso Stabilization During Cycling

Medicine & Science in Sports & Exercise ◽

10.1249/00005768-200405001-00804 ◽

2004 ◽

Vol 36 (Supplement) ◽

pp. S168

Author(s):

John McDaniel ◽

Andy W. Subudhi ◽

Jim C. Martin

Keyword(s):

Metabolic Cost ◽

Upper Body

Download Full-text

578 THE METABOLIC COST OF LOW CADENCE AND HIGH CADENCE UPPER BODY AEROBIC EXERCISE IN DIFFERENTLY ABLE AND ABLE BODIED SUBJECTS

Medicine & Science in Sports & Exercise ◽

10.1249/00005768-199305001-00580 ◽

1993 ◽

Vol 25 (Supplement) ◽

pp. S104

Author(s):

H. R. Perez ◽

J. Wygand ◽

E. Kowalski ◽

R. M. Otto ◽

A. Babcock ◽

...

Keyword(s):

Aerobic Exercise ◽

Metabolic Cost ◽

Upper Body ◽

High Cadence

Download Full-text

A low-cost method for carrying loads during human walking

Journal of Experimental Biology ◽

10.1242/jeb.216119 ◽

2020 ◽

Vol 223 (23) ◽

pp. jeb216119

Author(s):

Christopher J. Arellano ◽

Obioma B. McReynolds ◽

Shernice A. Thomas

Keyword(s):

Low Cost ◽

Center Of Mass ◽

Metabolic Cost ◽

The Body ◽

Human Walking ◽

Metabolic Power ◽

Arm Swing ◽

Leg Motion ◽

The Cost ◽

Pendulum Dynamics

ABSTRACTHumans often perform tasks that require them to carry loads, but the metabolic cost of carrying loads depends on where the loads are positioned on the body. We reasoned that carrying loads at the arms’ center of mass (COM) during walking might be cheap because arm swing is thought to be dominated by passive pendulum dynamics. In contrast, we expected that carrying loads at the leg COM would be relatively expensive because muscular actuation is necessary to initiate and propagate leg swing. Therefore, we hypothesized that carrying loads at the arm COM while swinging would be cheaper than carrying loads at the leg COM. We further hypothesized that carrying loads at the arm COM while swinging would be more expensive than carrying loads at the waist, where the mass does not swing relative to the body. We measured net metabolic power, arm and leg motion, and the free vertical moment while subjects (n=12) walked on a treadmill (1.25 m s−1) without a load, and with 8 kg added to the arms (swinging versus not swinging), legs or waist. We found that carrying loads on the arms or legs altered arm swinging amplitude; however, the free vertical moment remained similar across conditions. Most notably, the cost of carrying loads on the swinging arms was 9% less than carrying at the leg COM (P<0.001), but similar to that at the waist (P=0.529). Overall, we found that carrying loads at the arm COM is just as cheap as carrying loads at the waist.

Download Full-text

The Effects of Upper-Body Exoskeletons on Human Metabolic Cost and Thermal Response during Work Tasks—A Systematic Review

International Journal of Environmental Research and Public Health ◽

10.3390/ijerph17207374 ◽

2020 ◽

Vol 17 (20) ◽

pp. 7374

Author(s):

Simona Del Ferraro ◽

Tiziana Falcone ◽

Alberto Ranavolo ◽

Vincenzo Molinaro

Keyword(s):

Systematic Review ◽

Thermal Response ◽

Preliminary Finding ◽

Metabolic Cost ◽

Statistical Correlation ◽

Upper Body ◽

Work Activity ◽

Mean Values ◽

Work Related ◽

Work Tasks

Background: New wearable assistive devices (exoskeletons) have been developed for assisting people during work activity or rehabilitation. Although exoskeletons have been introduced into different occupational fields in an attempt to reduce the risk of work-related musculoskeletal disorders, the effectiveness of their use in workplaces still needs to be investigated. This systematic review focused on the effects of upper-body exoskeletons (UBEs) on human metabolic cost and thermophysiological response during upper-body work tasks. Methods: articles published until 22 September 2020 were selected from Scopus, Web of Science, and PubMed for eligibility and the potential risk of bias was assessed. Results: Nine articles resulted in being eligible for the metabolic aspects, and none for the thermal analysis. All the studies were based on comparisons between conditions with and without exoskeletons and considered a total of 94 participants (mainly males) performing tasks involving the trunk or overhead work, 7 back-support exoskeletons, and 1 upper-limb support exoskeleton. Eight studies found a significant reduction in the mean values of the metabolic or cardiorespiratory parameters considered and one found no differences. Conclusions: The reduction found represents a preliminary finding that needs to be confirmed in a wider range of conditions, especially in workplaces, where work tasks show different characteristics and durations compared to those simulated in the laboratory. Future developments should investigate the dependence of metabolic cost on specific UBE design approaches during tasks involving the trunk and the possible statistical correlation between the metabolic cost and the surface ElectroMyoGraphy (sEMG) parameters. Finally, it could be interesting to investigate the effect of exoskeletons on the human thermophysiological response.

Download Full-text

Reduction in the metabolic cost of human walking gaits using quasi-passive upper body exoskeleton