Your search keyword '"Celadon N"' showing total 11 results

1. EMG-based biofeedback system for motor rehabilitation: A pilot study

Author

Di Girolamo, M., primary, Celadon, N., additional, Appendino, S., additional, Turolla, A., additional, and Ariano, P., additional

Published

2017

2. Design and testing of an under-actuated surface EMG-driven hand exoskeleton

Author

Lince, A., primary, Celadon, N., additional, Battezzato, A., additional, Favetto, A., additional, Appendino, S., additional, Ariano, P., additional, and Paleari, M., additional

Published

2017

3. SEMG-biofeedback armband for hand motor rehabilitation in stroke patients: A preliminary pilot longitudinal study

Author

Carmine Berlingieri, Andrea Turolla, Daniyal Ahmed, Nicolo Celadon, Eleonora Mascotto, Silvia Salvalaggio, Mahmoud Alhelou, Daniele Rimini, Giorgia Pregnolato, Paolo Ariano, Rimini D., Salvalaggio S., Pregnolato G., Alhelou M., Berlingieri C., Mascotto E., Turolla A., Ariano P., Celadon N., and Ahmed D.

Subjects

biofeedback, 030506 rehabilitation, medicine.medical_specialty, Longitudinal study, medicine.medical_treatment, Electromyography, Biofeedback, rehabilitation, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, EMG, Quality of life, medicine, Stroke, Rehabilitation, medicine.diagnostic_test, business.industry, medicine.disease, stroke, medicine.anatomical_structure, Upper limb, hand, 0305 other medical science, Motor learning, business, 030217 neurology & neurosurgery

Abstract

Upper limb motor impairment is one of the most debilitating sequelae after stroke, thus the aim of rehabilitation is to promote functional recovery and improve quality of life. Surface Electromyography Biofeedback (sEMG-BFB) is a therapeutic tool based on providing amplified neuromuscular information on motor performance to the patient, for enhancing motor learning and driving to a successful recovery. A preliminary pilot longitudinal study was carried out to preliminarily investigate any clinical and instrumental effect due to an innovative treatment based on sEMG-BFB, in stroke survivors. Fifteen stroke patients with impairment of hand function were enrolled for a 3-weeks- training with REcognition MOvement (REMO®), a sEMG-BFB armband, clinical and instrumental assessments were administered before and after the training. After training, statistically significant differences were observed at the Box and Block Test (BBT) and in the relation between changes at BBT and chMAX-chMIN of wrist extension movement. Our results indicated that improvement in the device control is associated to a better hand function. Further studies need to be conducted to investigate the feasibility of using REMO® to study motor behavior in both healthy and diseased subjects.

Published

2020

4. EMG-based biofeedback system for motor rehabilitation: A pilot study

Author

M. Di Girolamo, Andrea Turolla, Paolo Ariano, Silvia Appendino, Nicolo Celadon, Di Girolamo M., Celadon N., Appendino S., Turolla A., and Ariano P.

Subjects

Protocol (science), 030506 rehabilitation, medicine.medical_specialty, medicine.diagnostic_test, business.industry, medicine.medical_treatment, Healthy subjects, Biological control systems, Medical treatment, Task analysis, Thumb, Protocols, Calibration, Muscles, calibration, electromyography, graphical user interfaces, medical signal processing, muscle, patient rehabilitation, patient treatment, EMG, biofeedback system, motor rehabilitation, compact surface electromyography sensor, sEMG biofeedback protocol, GUI, calibration procedure duration, clinical environment, graphic user interface, Context (language use), Electromyography, Thumb, Biofeedback, Motor rehabilitation, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Physical medicine and rehabilitation, Medicine, Procedure Duration, 0305 other medical science, business, 030217 neurology & neurosurgery

Abstract

The study aim was to test, in a clinical context, a compact surface electromyography (sEMG) sensor and a sEMG biofeedback protocol driven by a specifically designed graphic user interface (GUI). The system was tested on 5 healthy subjects and 3 post-stroke patients. The complete system evaluation was conducted considering the device setup time, the calibration procedure duration and the capability of the patients to understand and complete the proposed exercises. Furthermore, a set of two different therapy outcomes was calculated in order to quantify the capability to modulate the muscle contraction from patients and healthy subjects. The pilot results revealed both the suitability of the system in a clinical environment and the effective extraction of quantitative outcomes during the therapy, showing differences between patients and healthy subjects.

Published

2018

5. Evaluating a vertical greening system mesocosm for kitchen greywater treatment: Comparison among vegetation species in water consumption, biomass growth and pollutants uptake and removal.

Author

Dal Ferro N, Celadon N, and Borin M

Subjects

Biomass, Oenanthe, Wetlands, Primulaceae, Wastewater, Water Pollutants, Chemical analysis, Waste Disposal, Fluid methods

Abstract

The escalating climate imbalance, coupled with rising water demands in rapidly expanding urban areas, is forcing scientists and policymakers to seek alternative strategies for efficient water resource management. Nature Based Solutions (NBS) are gaining prominence due to their ability to provide multiple ecosystem services. However, the quantification of benefits and drawbacks mediated by different vegetation species remains inadequate. In this study, we investigated the performance of a pot-based vertical greening system (VGS) designed to integrate the functions of green facades with those of treatment wetlands. The VGS was vegetated with Mentha aquatica L. (hereafter Mentha), Oenanthe javanica (Blume) DC. (hereafter Oenanthe) and Lysimachia nummularia L. (hereafter Lysimachia), and their respective effects on water balance and mass removal of common greywater pollutants were compared. Results indicated that VGS lines vegetated with Oenanthe and Mentha exhibited comparable pollutant removals. Oenanthe showed a preference for greywater that had already undergone partial treatment, while Mentha was not affected by any pollutant load in water removal -48.1 % of total inflow- and in nutrients uptake in aboveground biomass -14.3 % N and 7 % P- due to sustained and robust growth, outperforming Oenanthe and Lysimachia. This has suggested the potential use of Oenathe in combination with Mentha for enhanced performances, particularly given Oenanthe's rapid growth in the early season and high biomass and nitrogen content following initial greywater treatment., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

6. Clinical Features to Predict the Use of a sEMG Wearable Device (REMO ® ) for Hand Motor Training of Stroke Patients: A Cross-Sectional Cohort Study.

Author

Pregnolato G, Rimini D, Baldan F, Maistrello L, Salvalaggio S, Celadon N, Ariano P, Pirri CF, and Turolla A

Subjects

Humans, Cross-Sectional Studies, Upper Extremity, Muscle Spasticity rehabilitation, Cohort Studies, Treatment Outcome, Motor Disorders, Stroke Rehabilitation methods, Stroke, Wearable Electronic Devices

Abstract

After stroke, upper limb motor impairment is one of the most common consequences that compromises the level of the autonomy of patients. In a neurorehabilitation setting, the implementation of wearable sensors provides new possibilities for enhancing hand motor recovery. In our study, we tested an innovative wearable (REMO ® ) that detected the residual surface-electromyography of forearm muscles to control a rehabilitative PC interface. The aim of this study was to define the clinical features of stroke survivors able to perform ten, five, or no hand movements for rehabilitation training. 117 stroke patients were tested: 65% of patients were able to control ten movements, 19% of patients could control nine to one movement, and 16% could control no movements. Results indicated that mild upper limb motor impairment (Fugl-Meyer Upper Extremity ≥ 18 points) predicted the control of ten movements and no flexor carpi muscle spasticity predicted the control of five movements. Finally, severe impairment of upper limb motor function (Fugl-Meyer Upper Extremity > 10 points) combined with no pain and no restrictions of upper limb joints predicted the control of at least one movement. In conclusion, the residual motor function, pain and joints restriction, and spasticity at the upper limb are the most important clinical features to use for a wearable REMO ® for hand rehabilitation training.

Published

2023

7. Design and testing of an under-actuated surface EMG-driven hand exoskeleton.

Author

Lince A, Celadon N, Battezzato A, Favetto A, Appendino S, Ariano P, and Paleari M

Subjects

Adult, Algorithms, Biomechanical Phenomena, Electromyography methods, Equipment Design, Female, Humans, Male, Rehabilitation instrumentation, Signal Processing, Computer-Assisted, Wearable Electronic Devices, Electromyography instrumentation, Exoskeleton Device, Hand physiology

Abstract

Stroke and other neurological pathologies are an increasing cause of hand impairment, involving expensive rehabilitative therapies. In this scenario, robotics applied to hand rehabilitation and assistance appears particularly promising in order to lower therapy costs and boost its efficacy. This work shows a recently conceived hand exoskeleton, from the design and realization to its preliminary evaluation. A control strategy based on surface electromyography (sEMG) signals is integrated: preliminary tests performed on healthy subjects show the validity of this choice. The testing protocol, applied on healthy subjects, demonstrated the robustness of the whole system, both in terms of mimicking a physiological distribution of finger forces across subjects, and of realizing an effective control strategy based on the user's intention.

Published

2017

8. Proportional estimation of finger movements from high-density surface electromyography.

Author

Celadon N, Došen S, Binder I, Ariano P, and Farina D

Subjects

Adult, Algorithms, Electrodes, Female, Healthy Volunteers, Humans, Isometric Contraction, Machine Learning, Male, Online Systems, Psychomotor Performance, Robotics, Signal Processing, Computer-Assisted, Stroke Rehabilitation instrumentation, Stroke Rehabilitation methods, Electromyography methods, Fingers physiology, Movement physiology

Abstract

Background: The importance to restore the hand function following an injury/disease of the nervous system led to the development of novel rehabilitation interventions. Surface electromyography can be used to create a user-driven control of a rehabilitation robot, in which the subject needs to engage actively, by using spared voluntary activation to trigger the assistance of the robot., Methods: The study investigated methods for the selective estimation of individual finger movements from high-density surface electromyographic signals (HD-sEMG) with minimal interference between movements of other fingers. Regression was evaluated in online and offline control tests with nine healthy subjects (per test) using a linear discriminant analysis classifier (LDA), a common spatial patterns proportional estimator (CSP-PE), and a thresholding (THR) algorithm. In all tests, the subjects performed an isometric force tracking task guided by a moving visual marker indicating the contraction type (flexion/extension), desired activation level and the finger that should be moved. The outcome measures were mean square error (nMSE) between the reference and generated trajectories normalized to the peak-to-peak value of the reference, the classification accuracy (CA), the mean amplitude of the false activations (MAFA) and, in the offline tests only, the Pearson correlation coefficient (PCORR)., Results: The offline tests demonstrated that, for the reduced number of electrodes (≤24), the CSP-PE outperformed the LDA with higher precision of proportional estimation and less crosstalk between the movement classes (e.g., 8 electrodes, median MAFA ~ 0.6 vs. 1.1 %, median nMSE ~ 4.3 vs. 5.5 %). The LDA and the CSP-PE performed similarly in the online tests (median nMSE < 3.6 %, median MAFA < 0.7 %), but the CSP-PE provided a more stable performance across the tested conditions (less improvement between different sessions). Furthermore, THR, exploiting topographical information about the single finger activity from HD-sEMG, provided in many cases a regression accuracy similar to that of the pattern recognition techniques, but the performance was not consistent across subjects and fingers., Conclusions: The CSP-PE is a method of choice for selective individual finger control with the limited number of electrodes (<24), whereas for the higher resolution of the recording, either method (CPS-PA or LDA) can be used with a similar performance. Despite the abundance of detection points, the simple THR showed to be significantly worse compared to both pattern recognition/regression methods. Nevertheless, THR is a simple method to apply (no training), and it could still give satisfactory performance in some subjects and/or simpler scenarios (e.g., control of selected fingers). These conclusions are important for guiding future developments towards the clinical application of the methods for individual finger control in rehabilitation robotics.

Published

2016

9. On optimal electrode configuration to estimate hand movements from forearm surface electromyography.

Author

Paleari M, Di Girolamo M, Celadon N, Favetto A, and Ariano P

Subjects

Adult, Electrodes, Female, Hand physiology, Humans, Male, Electromyography, Forearm physiology, Movement physiology

Abstract

Understanding the movement of the hand from sEMG signals acquired on the forearm is key in the development of future prosthetics of the upper limb. Despite the technical advancement on this technique, state of the art of sEMG still relies strongly on optimal electrode placement which is typically performed by a specialist by mean of a heuristic search. Involving a specialist has few major disadvantages including high costs and relatively long schedules. This work searches an optimal electrode configuration which could reduce or avoid the intervention of a specialist. More than 200 different possible electrode configurations were assessed by means of the average recognition rate over 11 different movements of the hand, wrist, and fingers. It is shown that using two rows of 8 equally spaced electrodes around the circumference of the forearm could be an optimal trade-off solution to accomplish the task of recognizing hand movement (ARR = 92%) without the need for a specialist or very complex hardware.

Published

2015

10. Individual finger classification from surface EMG: Influence of electrode set.

Author

Celadon N, Dosen S, Paleari M, Farina D, and Ariano P

Subjects

Adult, Discriminant Analysis, Electrodes, Forearm physiology, Humans, Isometric Contraction physiology, Muscle, Skeletal physiology, Range of Motion, Articular, Signal Processing, Computer-Assisted, Electromyography standards, Fingers physiology

Abstract

The aim of this work was to minimize the number of channels, determining acceptable electrode locations and optimizing electrode-recording configurations to decode isometric flexion and extension of individual fingers. Nine healthy subjects performed cyclical isometric contractions activating individual fingers. During the experiment they tracked a moving visual marker indicating the contraction type (flexion/extension), desired activation level and the finger that should be employed. Surface electromyography (sEMG) signals were detected from the forearm muscles using a matrix of 192 channels (24 longitudinal columns and 8 transversal rows, 10 mm inter-electrode distance). The classification was evaluated in the context of a linear discriminant analysis (LDA) with different sets of EMG electrodes: A) one linear array of 8 electrodes, B) two arrays of 8 electrodes each, C) a set with one electrode on the barycenter of each sEMG activity area, D) all the recorded channels. The results showed that the classification accuracy depended on the electrode set (F=14.67, p<;0.001). The best reduction approaches were the barycenter calculation and the use of two linear arrays of electrodes, which performed similarly to each other (both > 82% of average success rate). Considering the computation time and electrode positioning, it is concluded that two arrays of 8 electrodes provide an optimal configuration to classify the isometric flexion and extension of individual fingers.

Published

2015

11. Quantifying forearm muscle activity during wrist and finger movements by means of multi-channel electromyography.

Author

Gazzoni M, Celadon N, Mastrapasqua D, Paleari M, Margaria V, and Ariano P

Subjects

Adult, Algorithms, Biomechanical Phenomena, Electrodes, Electromyography instrumentation, Electromyography statistics & numerical data, Factor Analysis, Statistical, Fingers anatomy & histology, Forearm anatomy & histology, Humans, Male, Muscle, Skeletal anatomy & histology, Wrist anatomy & histology, Electromyography methods, Fingers physiology, Forearm physiology, Movement physiology, Muscle, Skeletal physiology, Wrist physiology

Abstract

The study of hand and finger movement is an important topic with applications in prosthetics, rehabilitation, and ergonomics. Surface electromyography (sEMG) is the gold standard for the analysis of muscle activation. Previous studies investigated the optimal electrode number and positioning on the forearm to obtain information representative of muscle activation and robust to movements. However, the sEMG spatial distribution on the forearm during hand and finger movements and its changes due to different hand positions has never been quantified. The aim of this work is to quantify 1) the spatial localization of surface EMG activity of distinct forearm muscles during dynamic free movements of wrist and single fingers and 2) the effect of hand position on sEMG activity distribution. The subjects performed cyclic dynamic tasks involving the wrist and the fingers. The wrist tasks and the hand opening/closing task were performed with the hand in prone and neutral positions. A sensorized glove was used for kinematics recording. sEMG signals were acquired from the forearm muscles using a grid of 112 electrodes integrated into a stretchable textile sleeve. The areas of sEMG activity have been identified by a segmentation technique after a data dimensionality reduction step based on Non Negative Matrix Factorization applied to the EMG envelopes. The results show that 1) it is possible to identify distinct areas of sEMG activity on the forearm for different fingers; 2) hand position influences sEMG activity level and spatial distribution. This work gives new quantitative information about sEMG activity distribution on the forearm in healthy subjects and provides a basis for future works on the identification of optimal electrode configuration for sEMG based control of prostheses, exoskeletons, or orthoses. An example of use of this information for the optimization of the detection system for the estimation of joint kinematics from sEMG is reported.

Published

2014