Locomotor training through a novel robotic platform for gait rehabilitation in pediatric population: short report

Bayón, Cristina; Lerma, S.; Ramírez, Óscar; Serrano, J. Ignacio; Castillo, M. Dolores del; Raya, Rafael; Belda-Lois, Juan-Manuel; Mastro-Martínez, Ignacio; Rocón, Eduardo

doi:10.1186/s12984-016-0206-x

Cited by 42 publications

(44 citation statements)

References 12 publications

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“…Mobile-platform-mounted exoskeletons are similar to type VI, with the exoskeleton mounted on a mobile wheeled platform that supports the weight of the device [ 54 ]. Exoskeletons that completely support their own weight through their foot segments are also under this type, as they are mobile by walking ability.…”

Section: Balance Assessment Using Robotic Devices Extends Posturograpmentioning

confidence: 99%

Robot-supported assessment of balance in standing and walking

Shirota

Asseldonk

Matjačić

et al. 2017

J NeuroEngineering Rehabil

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Clinically useful and efficient assessment of balance during standing and walking is especially challenging in patients with neurological disorders. However, rehabilitation robots could facilitate assessment procedures and improve their clinical value. We present a short overview of balance assessment in clinical practice and in posturography. Based on this overview, we evaluate the potential use of robotic tools for such assessment. The novelty and assumed main benefits of using robots for assessment are their ability to assess ‘severely affected’ patients by providing assistance-as-needed, as well as to provide consistent perturbations during standing and walking while measuring the patient’s reactions. We provide a classification of robotic devices on three aspects relevant to their potential application for balance assessment: 1) how the device interacts with the body, 2) in what sense the device is mobile, and 3) on what surface the person stands or walks when using the device. As examples, nine types of robotic devices are described, classified and evaluated for their suitability for balance assessment. Two example cases of robotic assessments based on perturbations during walking are presented. We conclude that robotic devices are promising and can become useful and relevant tools for assessment of balance in patients with neurological disorders, both in research and in clinical use. Robotic assessment holds the promise to provide increasingly detailed assessment that allows to individually tailor rehabilitation training, which may eventually improve training effectiveness.

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Section: Balance Assessment Using Robotic Devices Extends Posturograpmentioning

confidence: 99%

Robot-supported assessment of balance in standing and walking

Shirota

Asseldonk

Matjačić

et al. 2017

J NeuroEngineering Rehabil

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“…Currently, a new generation of robotic devices [ 6 – 8 ] provides means for encouraging the patients to an active participation in exercises, which are now more task specific. Both the implemented novel control strategies and the modularity of new exoskeletons and gait trainers offer promising possibilities to enhance the rehabilitation outcomes by adapting the treatment to the patient’s needs [ 9 , 10 ]. Nevertheless, so far there is not enough evidence to ensure that classic robot-based rehabilitation provides better treatment outcomes by itself than conventional physical strategies in childhood [ 11 ].…”

Section: Introductionmentioning

confidence: 99%

A robot-based gait training therapy for pediatric population with cerebral palsy: goal setting, proposal and preliminary clinical implementation

Bayón

Lorenzo

Moral-Saiz

et al. 2018

J NeuroEngineering Rehabil

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BackgroundThe use of robotic trainers has increased with the aim of improving gait function in patients with limitations. Nevertheless, there is an absence of studies that deeply describe detailed guidelines of how to correctly implement robot-based treatments for gait rehabilitation. This contribution proposes an accurate robot-based training program for gait rehabilitation of pediatric population with Cerebral Palsy (CP).MethodsThe program is focused on the achievement of some specifications defined by the International Classification of Functioning, Disability and Health framework, Children and Youth version (ICF-CY). It is framed on 16 non-consecutive sessions where motor control, strength and power exercises of lower limbs are performed in parallel with a postural control strategy. A clinical evaluation with four pediatric patients with CP using the CPWalker robotic platform is presented.ResultsThe preliminary evaluation with patients with CP shows improvements in several aspects as strength (74.03 ± 40.20%), mean velocity (21.46 ± 33.79%), step length (17.95 ± 20.45%) or gait performance (e.g. 66 ± 63.54% in Gross Motor Function Measure-88 items, E and D dimensions).ConclusionsThe improvements achieved in the short term show the importance of working strength and power functions meanwhile over-ground training with postural control. This research could serve as preliminary support for future clinical implementations in any robotic device.Trial registrationThe study was carried out with the number R-0032/12 from Local Ethical Committee of the Hospital Infantil Niño Jesús. Public trial registered on March 23, 2017: ISRCTN18254257.Electronic supplementary materialThe online version of this article (10.1186/s12984-018-0412-9) contains supplementary material, which is available to authorized users.

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“…The possibility of having this information directly from a sensor could dramatically reduce the computational burden of exoskeletons' control strategy because currently it is estimated based on very complex biomechanical models. 9 The dynamic and continuous monitor of gait parameters requires that the sensing mechanisms implemented are mobile, with limited or nonexistent wiring, preferably adaptable to a shoe, low cost, and with low power consumption. 10 Although a considerable number of solutions for plantar pressure have been already reported, they are mainly based on electronic or imaging devices, presenting some drawbacks such as fragility, instability, and inconsistent feedback.…”

Section: Introductionmentioning

confidence: 99%

Insole optical fiber Bragg grating sensors network for dynamic vertical force monitoring

et al. 2017

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In an era of unprecedented progress in technology and increase in population age, continuous and close monitoring of elder citizens and patients is becoming more of a necessity than a luxury. Contributing toward this field and enhancing the life quality of elder citizens and patients with disabilities, this work presents the design and implementation of a noninvasive platform and insole fiber Bragg grating sensors network to monitor the vertical ground reaction forces distribution induced in the foot plantar surface during gait and body center of mass displacements. The acquired measurements are a reliable indication of the accuracy and consistency of the proposed solution in monitoring and mapping the vertical forces active on the foot plantar sole, with a sensitivity up to 11.06 ?? pm / N . The acquired measurements can be used to infer the foot structure and health condition, in addition to anomalies related to spine function and other pathologies (e.g., related to diabetes); also its application in rehabilitation robotics field can dramatically reduce the computational burden of exoskeletons’ control strategy. The proposed technology has the advantages of optical fiber sensing (robustness, noninvasiveness, accuracy, and electromagnetic insensitivity) to surpass all drawbacks verified in traditionally used sensing systems (fragility, instability, and inconsistent feedback).

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Locomotor training through a novel robotic platform for gait rehabilitation in pediatric population: short report

Cited by 42 publications

References 12 publications

Robot-supported assessment of balance in standing and walking

Robot-supported assessment of balance in standing and walking

A robot-based gait training therapy for pediatric population with cerebral palsy: goal setting, proposal and preliminary clinical implementation

Insole optical fiber Bragg grating sensors network for dynamic vertical force monitoring

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