Systematic Review on Wearable Lower-Limb Exoskeletons for Gait Training in Neuromuscular Impairments

Rodríguez-Fernández, Antonio; Lobo-Prat, Joan; Font-Llagunes, Josep M.

doi:10.21203/rs.3.rs-40114/v2

Cited by 11 publications

(23 citation statements)

References 46 publications

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“…A motorized exoskeleton with a user can be modeled as a four-link bipedal walking system in the sagittal plane as follows M (q)q + C(q, q) q + G(q) + P (q, q) + d(t) = τ e (q, q, t), (1) where q : R ≥t0 → R 4 denotes the measurable hip and knee joint angles on both sides, q, q : R ≥t0 → R 4 denote the measurable joint angular velocities and unmeasurable joint angular accelerations, respectively, where t 0 ∈ R >0 is denoted as initial time; M : R 4 → R 4×4 >0 denotes the combined human-exoskeleton inertia; C : R 4 × R 4 → R 4×4 and G : R 4 → R 4 denote centripetal-Coriolis and gravitational effects, respectively; P : R 4 ×R 4 → R 4 denotes the damping and viscoelastic effects; and d : R ≥t0 → R 4 denotes unmodeled terms and disturbances. The torque produced by the electrical motors are expressed as τ e : R 4 ×R 4 ×R ≥t0 → R 4 .…”

Section: Human-exoskeleton Dynamic Modelmentioning

confidence: 99%

“…Powered exoskeletons vary in their design, wearability, sensing, and actuation. Existing powered exoskeletons use electrical motors [1], hydraulic [2] and pneumatic actuators [3], [4]. The actuators used to outfit the exoskeleton influence the magnitude and response of the inputs applied to the body and thus the human-robot interaction.…”

Section: Introductionmentioning

confidence: 99%

“…Cable-driven transmission mechanisms offload actuators away from the human to reduce the weight imposed on the body and thus reduces the burden on the user-side. 1 Department of Mechanical and Aerospace Engineering, Syracuse University, Syracuse NY 13244, USA. Email: {cchang21, jacasasb, vhduenas}@syr.edu Such mechanisms have been widely applied for orthotic devices (e.g., lower-limb [7], [8], upper-limb [9], [10], hand orthoses [11]) to provide torques about the joints to assist or augment human function.…”

Section: Introductionmentioning

confidence: 99%

“…Since cables cannot transmit compression forces, at least l + 1 cables are required to control l DOFs to provide an agonist-antagonist movement [12]. Despite the benefits of cable-driven mechanisms, two critical issues arise: (1) cables experience a slack behavior if the tension is not accurately controlled, thus affecting the response time; (2) undesired agonist-antagonist coordination may produce counteracting torques about a joint. Hence, it is essential to develop effective control strategies to ensure coordinated or synchronized motion in a multi-joint system.…”

Section: Introductionmentioning

confidence: 99%

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Closed-loop Control Design and Motor Allocation for a Lower-limb Cable-driven Exoskeleton: A Switched Systems Approach

Chang,

Casas,

Duenas

2021

Preprint

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Powered lower-limb exoskeletons provide assistive torques to coordinate limb motion during walking in individuals with movement disorders. Advances in sensing and actuation have improved the wearability and portability of state-ofthe-art exoskeletons for walking. Cable-driven exoskeletons offload the actuators away from the user, thus rendering lightweight devices to facilitate locomotion training. However, cabledriven mechanisms experience a slacking behavior if tension is not accurately controlled. Moreover, counteracting forces can arise between the agonist and antagonist motors yielding undesired joint motion. In this paper, the strategy is to develop two control layers to improve the performance of a cabledriven exoskeleton. First, a joint tracking controller is designed using a high-gain robust approach to track desired knee and hip trajectories. Second, a motor synchronization objective is developed to mitigate the effects of cable slacking for a pair of electric motors that actuate each joint. A sliding-mode robust controller is designed for the motor synchronization objective. A Lyapunov-based stability analysis is developed to guarantee a uniformly ultimately bounded result for joint tracking and exponential tracking for the motor synchronization objective. Moreover, an average dwell time analysis provides a bound on the number of motor switches when allocating the control between motors that actuate each joint. An experimental result with an able-bodied individual illustrates the feasibility of the developed control methods.

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Section: Human-exoskeleton Dynamic Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Closed-loop Control Design and Motor Allocation for a Lower-limb Cable-driven Exoskeleton: A Switched Systems Approach

Chang,

Casas,

Duenas

2021

Preprint

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“…High variability was found in the number of partici-702 pants (14.87 ± 13.53), number of sessions (11.77 ± 12.20),703 session frequency (times per week; 3.09 ± 1.68), and 704 session duration (50.57 ± 34.06 min) (see Figure 5.C). 705 Previous reviews that analyzed the protocol of robotic 706 treatment reported similar high variability [40,46]. 707 Some studies did not provide complete information 708 about the experimental protocol, e.g., they did not mention the number (15.09 %), duration (33.33 %), or frequency (31.44 %) of the training sessions.…”

mentioning

confidence: 99%

Control strategies used in lower limb exoskeletons for gait rehabilitation after brain injury: a systematic review and analysis of clinical effectiveness

Miguel-Fernández

Lobo-Prat²,

Prinsen

et al. 2022

Preprint

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BackgroundIn the past decade, there has been substantial progress in the development of robotic controllers that specify how lower-limb exoskeletons should interact with brain-injured patients. However, it is still an open question which exoskeleton control strategies can more effectively stimulate motor function recovery. Within this review, we aim to complement previous literature surveys on the topic of exoskeleton control for gait rehabilitation by: (1) Providing an updated structured framework of current control strategies, (2) Analyzing the methodology of clinical validations used in the robotic interventions, and (3) Reporting the potential relation between the employed control strategies and clinical outcomes. MethodsFour databases were searched using database-specific search terms from 2000 to September 2020. We identified 1648 articles, of which 159 were included and evaluated in full-text. We included studies that clinically evaluated the effectiveness of the exoskeleton on impaired participants, and which clearly explained or referenced the implemented control strategy. Results(1) We found that adaptive assistive control (100 \% of exoskeletons) that followed rule-based algorithms (72 \%) based on ground reaction force thresholds (63 \%) in conjunction with trajectory-tracking control (97 \%) were the most implemented control strategies. (2) Regarding the clinical validations used in the robotic interventions, we found high variability on the experimental protocols and outcome metrics selected. (3) With moderate grade of evidence, associated to the high heterogeneity in the experimental protocol and low number of studies, we found that adaptive control strategies, which followed threshold-based or adaptive oscillator algorithms together with trajectory-tracking control, resulted in the highest improvements on clinical outcomes for people with stroke. ConclusionsDespite the efforts to develop novel more effective controllers for gait neurorehabilitation, the current level of evidence on the effectiveness of the different control strategies on clinical outcomes is still low. There is a clear lack of standardization in the experimental protocols leading to high levels of heterogeneity. Standardized comparisons among control strategies analyzing the relation between control parameters and biomechanical metrics will fill this gap to better guide future technical developments. The most promising controllers seem to be those that adapt to key biomechanical descriptors based on the patients' specific pathology.

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Exoskeletons: A challenge for development

2023

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The development of exoskeletons is currently a lengthy process full of challenges. We are proposing a framework to accelerate the process and make the resulting exoskeletons more user-centered. The needed accomplishments in science are described in an effort to lay the foundation for future research projects. Since the early 2000s, exoskeletons have been discussed as an emerging technology in industrial, medical, or military applications. Those systems are designed to support people during manual tasks. At first, those systems lacked broad acceptance. Many models found their niches in ongoing developments and more diverse systems entering the market. There are still applications that are in dire need of such assistance. Due to the lack of experience with body-worn robotics, the development of such systems has been shaped by trial and error. The lack of legacy products results in longer development times. In this paper, a process to generate a framework is presented to display the required research to enable future exoskeleton designers. Owing to their proximity to the user’s body, exoskeletons are highly complex systems that need sophisticated subsystems, such as kinematic, control, interaction design, or actuators, to be accepted by users. Due to the wide variety of fields and high user demands, a synchronized multidisciplinary effort is necessary. To achieve this, a process to develop a modular framework for exoskeleton design is proposed. It focuses on user- and use-case-centered solutions for matching kinematics, actuation, and control. To ensure the usefulness of the framework, an evaluation of the incorporated solutions is required.

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Systematic Review on Wearable Lower-Limb Exoskeletons for Gait Training in Neuromuscular Impairments

Cited by 11 publications

References 46 publications

Closed-loop Control Design and Motor Allocation for a Lower-limb Cable-driven Exoskeleton: A Switched Systems Approach

Closed-loop Control Design and Motor Allocation for a Lower-limb Cable-driven Exoskeleton: A Switched Systems Approach

Control strategies used in lower limb exoskeletons for gait rehabilitation after brain injury: a systematic review and analysis of clinical effectiveness

Exoskeletons: A challenge for development

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