Standing-up exerciser based on functional electrical stimulation and body weight relief

Ferrarin, Maurizio; Pavan, E.; Spadone, R.; Cardini, Roldano; Frigo, C.

doi:10.1007/bf02344209

Cited by 24 publications

(24 citation statements)

References 26 publications

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“…25 This system was designed and developed for quadriceps muscles' re-strength during movements of standing up ± sitting down, induced by FES and supported by a mechanical device for weight relief. The training of muscle conditioning consisted of 3 to 4 sessions/week of 90 min, and lasted 30 sessions.…”

Section: Training Programmentioning

confidence: 99%

Energy consumption of locomotion with orthosis versus Parastep-assisted gait: a single case study

et al. 2003

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Study design: Single case study. Objectives: To evaluate the energy expenditure during ambulation with the Advanced Reciprocating Gait Orthosis (ARGO), with and without functional electrical stimulation (FES), and with the Parastep system in a single subject, in order to avoid the e ect of intersubject variability. Setting: The Centre of Sport Medicine and Bioengineering Centre`Don C Gnocchi' Foundation ONLUS IRCCS, Milano, Italy. Methods: A single patient (lesion level T 5 ± T 6 ) was trained speci®cally for each walking system and was evaluated after each training period. The e ects of FES on muscle conditioning, spasticity and bone density were also evaluated. The HR/ VO 2 relationship and the energy cost of locomotion were measured during wheelchair (WHCH) use, during locomotion with ARGO (with and without FES) and Parastep system at di erent speeds. Results: The following was observed at the end of the whole training: (a) circumferences of both lower limbs and quadriceps forces were increased, whereas fatigue index was slightly decreased, spasticity and bone density were unchanged; (b) compared to WHCH locomotion, the slope of HR/ VO 2 curves with ARGO was higher (slope di erence=51.1 b 1O 2 71 ), with ARGO+FES was similar (slope di erence=75.3 b 1O 2 71 ) and with Parastep was smaller (slope di erence=755.6 b 1O 2 71 ); (c) HR increased linearly with all locomotion systems, but did not rise above 125 bpm with Parastep; (d) the cost of locomotion was higher with Parastep than with ARGO (with and without FES), tested at each velocity; (e) Parastep appears to be easier to use for the subject. Conclusions: (a) FES can improve ambulation with orthosis, but the cost of locomotion remains very high; (b) the Parastep assisted gait elicits a higher energy expenditure than other orthoses, probably due to the lower speed of locomotion and to the high isometric e ort of the stimulated muscles. Sponsorship: This work has been partially supported by the Italian Minister of Public Health (Ricerca Finalizzata IRCCS no ICS030.7/RF97.25).

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Section: Training Programmentioning

confidence: 99%

Energy consumption of locomotion with orthosis versus Parastep-assisted gait: a single case study

et al. 2003

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“…The pennation angle of human quadriceps muscle changes monotonically during quadriceps contraction and is a continuously differentiable, positive, monotonic, and bounded function with a bounded first time derivative [21]. The relationship between muscle force and applied voltage is denoted by the unknown function as (6) where is the voltage applied to the quadriceps muscle by electrical stimulation. While exact force versus voltage models are debatable and contain parametric uncertainty, the generally accepted empirical relationship between the applied voltage (or similarly, current, frequency [22], [23], or pulse width) is well established.…”

Section: Muscle Activation and Limb Modelmentioning

confidence: 99%

“…Typically, these approaches have only been empirically investigated and no analytical stability analysis has been developed that provides an indication of the performance, robustness, or stability of these control methods. Some recent studies (e.g., see [6]) also point to evidence that suggests that linear control methods do not yield acceptable performance in practice. The development of a stability analysis for previous PID-based NMES controllers has been evasive because of the fact that the governing equations for a muscle contraction/limb motion are nonlinear with unstructured uncertainties.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear Neuromuscular Electrical Stimulation Tracking Control of a Human Limb

Sharma

Stegath

Gregory

et al. 2009

IEEE Trans. Neural Syst. Rehabil. Eng.

131

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Abstract-A high-level objective of neuromuscular electrical stimulation (NMES) is to enable a person to achieve some functional task. Towards this goal, the objective of the current effort is to develop a NMES controller to produce a knee position trajectory that will enable a human shank to track any continuous desired trajectory (or constant setpoint). A nonlinear control method is developed to control the human quadriceps femoris muscle undergoing nonisometric contractions. The developed controller does not require a muscle model and can be proven to yield asymptotic stability for a nonlinear muscle model in the presence of bounded nonlinear disturbances (e.g., spasticity, delays, fatigue). The performance of the controller is demonstrated through a series of closed-loop experiments on human subjects. The experiments illustrate the ability of the controller to enable the leg shank to track single and multiple period trajectories with different periods and ranges of motion, and also track desired step changes with changing loads.

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“…This system has been mathematically represented by means of a simulation model described in Reference [17]. The model refers to the experimental set-up developed at the Fondazione Don Gnocchi [3,13,18], which is aimed to train the paralysed quadriceps muscles of patients with spinal cord lesion, for the increase of muscle strength and endurance, in view of the functional applications of FES such as walking or cycling.…”

Section: Description Of the Systemmentioning

confidence: 99%

“…On the basis of previous experiences (see Reference [3]), which showed that a non-linear controller is strongly advisable, it was decided to perform a series of preliminary simulation studies, without involving patients; this is to rapidly test an advanced control strategy. Hence, in this work, the correct stimulation pattern is decided by a gain scheduling non-linear feedback controller designed to work on a wide range of operating conditions of the system using only knee joint measurements in order to generate the appropriate electrical stimulation.…”

Section: Introductionmentioning

confidence: 99%

Gain scheduling control of functional electrical stimulation for assisted standing up and sitting down in paraplegia: a simulation study

Previdi

Ferrarin

Savaresi

et al. 2004

Adaptive Control & Signal

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This paper reports on a simulation study that concerns the design of a non-linear controller for the standing up and the sitting down of a paraplegic patient by means of functional electrical stimulation. The simulations refer to a specific experimental device developed at the Fondazione Don Gnocchi (Italy). This is a seesaw, with the patient on one side and a weight on the other side. The patient is seated so that its posture can be fully known in real-time by continuously monitoring the knee joint angle. By delivering a suitable electrical stimulation to the quadriceps muscles groups, the patient can be raised and made to sit via smooth movements. Hitherto, the only feedback control law, which has been implemented in this area, is based on a PID controller and usually provides poor tracking performances. Hence, in this work, a nonlinear gain scheduling controller has been designed and tested in a series of simulation experiments. The controller is tuned following a gain scheduling strategy: a set of local linear quadratic controllers is designed using a set of linear tangent models. A global non-linear gain scheduled controller is then obtained via interpolation. The gain-scheduled controller is implemented following an advanced strategy that guarantees that the so-called linearization property holds.

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Standing-up exerciser based on functional electrical stimulation and body weight relief

Cited by 24 publications

References 26 publications

Energy consumption of locomotion with orthosis versus Parastep-assisted gait: a single case study

Energy consumption of locomotion with orthosis versus Parastep-assisted gait: a single case study

Nonlinear Neuromuscular Electrical Stimulation Tracking Control of a Human Limb

Gain scheduling control of functional electrical stimulation for assisted standing up and sitting down in paraplegia: a simulation study

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