Your search keyword '"Rocon, Eduardo"' showing total 13 results

1. Novel Methods for Personalized Gait Assistance: Three-Dimensional Trajectory Prediction Based on Regression and LSTM Models.

Author

Romero-Sorozábal, Pablo, Delgado-Oleas, Gabriel, Laudanski, Annemarie F., Gutiérrez, Álvaro, and Rocon, Eduardo

Subjects

ANKLE, GAIT in humans, REGRESSION analysis, HUMAN-robot interaction

Abstract

Enhancing human–robot interaction has been a primary focus in robotic gait assistance, with a thorough understanding of human motion being crucial for personalizing gait assistance. Traditional gait trajectory references from Clinical Gait Analysis (CGA) face limitations due to their inability to account for individual variability. Recent advancements in gait pattern generators, integrating regression models and Artificial Neural Network (ANN) techniques, have aimed at providing more personalized and dynamically adaptable solutions. This article introduces a novel approach that expands regression and ANN applications beyond mere angular estimations to include three-dimensional spatial predictions. Unlike previous methods, our approach provides comprehensive spatial trajectories for hip, knee and ankle tailored to individual kinematics, significantly enhancing end-effector rehabilitation robotic devices. Our models achieve state-of-the-art accuracy: overall RMSE of 13.40 mm and a correlation coefficient of 0.92 for the regression model, and RMSE of 12.57 mm and a correlation of 0.99 for the Long Short-Term Memory (LSTM) model. These advancements underscore the potential of these models to offer more personalized gait trajectory assistance, improving human–robot interactions. [ABSTRACT FROM AUTHOR]

Published

2024

2. On the Effect of Vibrotactile Stimulation in Essential Tremor.

Author

Cabral, Ariana Moura, Lora-Millán, Julio Salvador, Pereira, Adriano Alves, Rocon, Eduardo, and Andrade, Adriano de Oliveira

Subjects

RESEARCH, KRUSKAL-Wallis Test, ONE-way analysis of variance, REGRESSION analysis, SENSORY stimulation, COMPARATIVE studies, ESSENTIAL tremor, SIGNAL processing, ELECTRIC stimulation, RESEARCH funding, STATISTICAL correlation, DATA analysis software

Abstract

(1) Background: Vibrotactile stimulation has been studied for tremor, but there is little evidence for Essential Tremor (ET). (2) Methods: This research employed a dataset from a previous study, with data collected from 18 individuals subjected to four vibratory stimuli. To characterise tremor changes before, during, and after stimuli, time and frequency domain features were estimated from the signals. Correlation and regression analyses verified the relationship between features and clinical tremor scores. (3) Results: Individuals responded differently to vibrotactile stimulation. The 250 Hz stimulus was the only one that reduced tremor amplitude after stimulation. Compared to the baseline, the 250 Hz and random frequency stimulation reduced tremor peak power. The clinical scores and amplitude-based features were highly correlated, yielding accurate regression models (mean squared error of 0.09). (4) Conclusions: The stimulation frequency of 250 Hz has the greatest potential to reduce tremors in ET. The accurate regression model and high correlation between estimated features and clinical scales suggest that prediction models can automatically evaluate and control stimulus-induced tremor. A limitation of this research is the relatively reduced sample size. [ABSTRACT FROM AUTHOR]

Published

2024

3. A Novel Physical Mobility Task to Assess Freezers in Parkinson's Disease.

Author

Nóbrega, Lígia Reis, Rocon, Eduardo, Pereira, Adriano Alves, and Andrade, Adriano de Oliveira

Subjects

DIAGNOSIS of neurological disorders, DRUG therapy for Parkinson's disease, RESEARCH methodology, TIME, AGE distribution, TASK performance, WEARABLE technology, ACCELEROMETERS, SMARTPHONES, GAIT disorders, COMPARATIVE studies, NEUROPSYCHOLOGICAL tests, PHYSICAL mobility, PARKINSON'S disease, RESEARCH funding, QUESTIONNAIRES, DESCRIPTIVE statistics, COGNITIVE testing, VIDEO recording, MOTOR ability, DISEASE complications

Abstract

Freezing of gait (FOG), one of the most disabling features of Parkinson's disease (PD), is a brief episodic absence or marked reduction in stride progression despite the intention to walk. Progressively more people who experience FOG restrict their walking and reduce their level of physical activity. The purpose of this study is to develop and validate a physical mobility task that induces freezing of gait in a controlled environment, employing known triggers of FOG episodes according to the literature. To validate the physical mobility tasks, we recruited 10 volunteers that suffered PD-associated freezing (60.6 ± 7.29 years-old) with new FOG-Q ranging from 12 to 26. The validation of the proposed method was carried out using inertial sensors and video recordings. All subjects were assessed during the OFF and ON medication states. The total number of FOG occurrences during data collection was 144. The proposed tasks were able to trigger 120 FOG episodes, while the TUG test caused 24. The Inertial Measurement Unit (IMU) with accelerometer and gyroscope could not only detect FOG episodes but also allowed us to visualize the three types of FOG: akinesia, festination and trembling in place. [ABSTRACT FROM AUTHOR]

Published

2023

4. Quasi-Passive Resistive Exosuit for Space Activities: Proof of Concept.

Author

Di Natali, Christian, Chini, Giorgia, Totaro, Massimo, Lora-Millán, Julio S., Rocon, Eduardo, Beccai, Lucia, Caldwell, Darwin G., Visentin, Gianfranco, Ortiz, Jesús, Reinoso Garcia, Oscar, and Cocuzza, Silvio

Subjects

MUSCLE fatigue, PROOF of concept, MUSCLE strength, BONE density, SPACE flight, PROPRIOCEPTION

Abstract

The limits of space travel are continuously evolving, and this creates increasingly extreme challenges for the crew's health that must be addressed by the scientific community. Long-term exposure to micro-gravity, during orbital flights, contributes to muscle strength degradation and increases bone density loss. In recent years, several exercise devices have been developed to counteract the negative health effects of zero-gravity on astronauts. However, the relatively large size of these devices, the need for a dedicated space and the exercise time-frame for each astronaut, does not make these devices the best choice for future long range exploration missions. This paper presents a quasi-passive exosuit to provide muscle training using a small, portable, proprioceptive device. The exosuit promotes continuous exercise, by resisting the user's motion, during routine all-day activity. This study assesses the effectiveness of the resistive exosuit by evaluating its effects on muscular endurance during a terrestrial walking task. The experimental assessment on biceps femoris and vastus lateralis, shows a mean increase in muscular activation of about 97.8 % during five repetitions of 3 min walking task at 3 km/h. The power frequency analysis shows an increase in muscular fatigue with a reduction of EMG median frequency of about 15.4 % for the studied muscles. [ABSTRACT FROM AUTHOR]

Published

2021

5. Reorganization of Resting-State EEG Functional Connectivity Patterns in Children with Cerebral Palsy Following a Motor Imagery Virtual-Reality Intervention.

Author

Stefano Filho, Carlos Alberto, Ignacio Serrano, José, Attux, Romis, Castellano, Gabriela, Rocon, Eduardo, del Castillo, Maria Dolores, and La Foresta, Fabio

Subjects

CHILDREN with cerebral palsy, FUNCTIONAL connectivity, BRAIN-computer interfaces, GRAPH theory, PHYSICAL therapy

Abstract

Motor imagery (MI) has been suggested to provide additional benefits when included in traditional approaches of physical therapy for children with cerebral palsy (CP). Regardless, little is understood about the underlying neurological substrates that might justify its supposed benefits. In this work, we studied resting-state (RS) electroencephalography (EEG) recordings of five children with CP that underwent a MI virtual-reality (VR) intervention. Our aim was to explore functional connectivity (FC) patterns alterations following this intervention through the formalism of graph theory, performing both group and subject-specific analyses. We found that FC patterns were more consistent across subjects prior to the MI-VR intervention, shifting along the anterior-posterior axis, post-intervention, for the β and γ bands. Additionally, group FC patterns were not found for the α range. Furthermore, intra-subject analyses reinforced the existence of large inter-subject variability and the need for a careful exploration of individual pattern alterations. Such patterns also hinted at a dependency between short-term functional plasticity mechanisms and the EEG frequency bands. Although our sample size is small, we provide a longitudinal analysis framework that can be replicated in future studies, especially at the group level, and whose foundation can be easily extended to verify the validity of our hypotheses. [ABSTRACT FROM AUTHOR]

Published

2021

6. Adaptive Spatial Filter Based on Similarity Indices to Preserve the Neural Information on EEG Signals during On-Line Processing.

Author

Delisle-Rodriguez, Denis, Villa-Parra, Ana Cecilia, Bastos-Filho, Teodiano, López-Delis, Alberto, Frizera-Neto, Anselmo, Krishnan, Sridhar, and Rocon, Eduardo

Subjects

SPATIAL filters, LIGHT filters, GRADED index fibers, BEAMFORMING, ELECTROENCEPHALOGRAPHY, ELECTRODES

Abstract

This work presents a new on-line adaptive filter, which is based on a similarity analysis between standard electrode locations, in order to reduce artifacts and common interferences throughout electroencephalography (EEG) signals, but preserving the useful information. Standard deviation and Concordance Correlation Coefficient (CCC) between target electrodes and its correspondent neighbor electrodes are analyzed on sliding windows to select those neighbors that are highly correlated. Afterwards, a model based on CCC is applied to provide higher values of weight to those correlated electrodes with lower similarity to the target electrode. The approach was applied to brain computer-interfaces (BCIs) based on Canonical Correlation Analysis (CCA) to recognize 40 targets of steady-state visual evoked potential (SSVEP), providing an accuracy (ACC) of 86.44 ± 2.81%. In addition, also using this approach, features of low frequency were selected in the pre-processing stage of another BCI to recognize gait planning. In this case, the recognition was significantly (p < 0.01) improved for most of the subjects (ACC ≥ 74.79%), when compared with other BCIs based on Common Spatial Pattern, Filter Bank - Common Spatial Pattern, and Riemannian Geometry. [ABSTRACT FROM AUTHOR]

Published

2017

7. An IMU-to-Body Alignment Method Applied to Human Gait Analysis.

Author

Vargas-Valencia, Laura Susana, Elias, Arlindo, Rocon, Eduardo, Bastos-Filho, Teodiano, and Frizera, Anselmo

Subjects

GAIT in humans, COMPUTER simulation, JOINTS (Anatomy), CALIBRATION, KINEMATICS, COMPUTER network resources

Abstract

This paper presents a novel calibration procedure as a simple, yet powerful, method to place and align inertial sensors with body segments. The calibration can be easily replicated without the need of any additional tools. The proposed method is validated in three different applications: a computer mathematical simulation; a simplified joint composed of two semi-spheres interconnected by a universal goniometer; and a real gait test with five able-bodied subjects. Simulation results demonstrate that, after the calibration method is applied, the joint angles are correctly measured independently of previous sensor placement on the joint, thus validating the proposed procedure. In the cases of a simplified joint and a real gait test with human volunteers, the method also performs correctly, although secondary plane errors appear when compared with the simulation results. We believe that such errors are caused by limitations of the current inertial measurement unit (IMU) technology and fusion algorithms. In conclusion, the presented calibration procedure is an interesting option to solve the alignment problem when using IMUs for gait analysis. [ABSTRACT FROM AUTHOR]

Published

2016

8. Inertial Sensor Error Reduction through Calibration and Sensor Fusion.

Author

Lambrecht, Stefan, Nogueira, Samuel L., Bortole, Magdo, Siqueira, Adriano A. G., Terra, Marco H., Rocon, Eduardo, and Pons, José L.

Subjects

KALMAN filtering, DETECTORS, ESTIMATION theory, PREDICTION theory, POTENTIOMETERS

Abstract

This paper presents the comparison between cooperative and local Kalman Filters (KF) for estimating the absolute segment angle, under two calibration conditions. A simplified calibration, that can be replicated in most laboratories; and a complex calibration, similar to that applied by commercial vendors. The cooperative filters use information from either all inertial sensors attached to the body, Matricial KF; or use information from the inertial sensors and the potentiometers of an exoskeleton, Markovian KF. A one minute walking trial of a subject walking with a 6-DoF exoskeleton was used to assess the absolute segment angle of the trunk, thigh, shank, and foot. The results indicate that regardless of the segment and filter applied, the more complex calibration always results in a significantly better performance compared to the simplified calibration. The interaction between filter and calibration suggests that when the quality of the calibration is unknown the Markovian KF is recommended. Applying the complex calibration, the Matricial and Markovian KF perform similarly, with average RMSE below 1.22 degrees. Cooperative KFs perform better or at least equally good as Local KF, we therefore recommend to use cooperative KFs instead of local KFs for control or analysis of walking. [ABSTRACT FROM AUTHOR]

Published

2016

9. A Robust Kalman Algorithm to Facilitate Human-Computer Interaction for People with Cerebral Palsy, Using a New Interface Based on Inertial Sensors.

Author

Raya, Rafael, Rocon, Eduardo, Gallego, Juan A., Ceres, Ram¢n, and Pons, Jose L.

Subjects

*HUMAN-computer interaction, *PEOPLE with cerebral palsy, *DETECTORS, *KALMAN filtering, *JUVENILE diseases, *BRAIN injuries

Abstract

This work aims to create an advanced human-computer interface called ENLAZA for people with cerebral palsy (CP). Although there are computer-access solutions for disabled people in general, there are few evidences from motor disabled community (e.g., CP) using these alternative interfaces. The proposed interface is based on inertial sensors in order to characterize involuntary motion in terms of time, frequency and range of motion. This characterization is used to design a filtering technique that reduces the effect of involuntary motion on person-computer interaction. This paper presents a robust Kalman filter (RKF) design to facilitate fine motor control based on the previous characterization. The filter increases mouse pointer directivity and the target acquisition time is reduced by a factor of ten. The interface is validated with CP users who were unable to control the computer using other interfaces. The interface ENLAZA and the RKF enabled them to use the computer. [ABSTRACT FROM AUTHOR]

Published

2012

10. Real-Time Estimation of Pathological Tremor Parameters from Gyroscope Data.

Author

Gallego, Juan A., Rocon, Eduardo, Roa, Javier O., Moreno, Juan C., and Pons, José L.

Subjects

*ALGORITHMS, *ACCELEROMETERS, *SPEED-indicators, *STOCHASTIC processes, *KALMAN filtering, *CONTROL theory (Engineering), *GYROSCOPES, *TIME perception

Abstract

This paper presents a two stage algorithm for real-time estimation of instantaneous tremor parameters from gyroscope recordings. Gyroscopes possess the advantage of providing directly joint rotational speed, overcoming the limitations of traditional tremor recording based on accelerometers. The proposed algorithm first extracts tremor patterns from raw angular data, and afterwards estimates its instantaneous amplitude and frequency. Real-time separation of voluntary and tremorous motion relies on their different frequency contents, whereas tremor modelling is based on an adaptive LMS algorithm and a Kalman filter. Tremor parameters will be employed to drive a neuroprosthesis for tremor suppression based on biomechanical loading. [ABSTRACT FROM AUTHOR]

Published

2010

11. Development and Evaluation of BenchBalance: A System for Benchmarking Balance Capabilities of Wearable Robots and Their Users.

Author

Bayón, Cristina, Delgado-Oleas, Gabriel, Avellar, Leticia, Bentivoglio, Francesca, Di Tommaso, Francesco, Tagliamonte, Nevio L., Rocon, Eduardo, and van Asseldonk, Edwin H. F.

Subjects

ROBOTIC exoskeletons, EQUILIBRIUM testing, PROOF of concept, SOCIAL interaction

Abstract

Recent advances in the control of overground exoskeletons are being centered on improving balance support and decreasing the reliance on crutches. However, appropriate methods to quantify the stability of these exoskeletons (and their users) are still under development. A reliable and reproducible balance assessment is critical to enrich exoskeletons' performance and their interaction with humans. In this work, we present the BenchBalance system, which is a benchmarking solution to conduct reproducible balance assessments of exoskeletons and their users. Integrating two key elements, i.e., a hand-held perturbator and a smart garment, BenchBalance is a portable and low-cost system that provides a quantitative assessment related to the reaction and capacity of wearable exoskeletons and their users to respond to controlled external perturbations. A software interface is used to guide the experimenter throughout a predefined protocol of measurable perturbations, taking into account antero-posterior and mediolateral responses. In total, the protocol is composed of sixteen perturbation conditions, which vary in magnitude and location while still controlling their orientation. The data acquired by the interface are classified and saved for a subsequent analysis based on synthetic metrics. In this paper, we present a proof of principle of the BenchBalance system with a healthy user in two scenarios: subject not wearing and subject wearing the H2 lower-limb exoskeleton. After a brief training period, the experimenter was able to provide the manual perturbations of the protocol in a consistent and reproducible way. The balance metrics defined within the BenchBalance framework were able to detect differences in performance depending on the perturbation magnitude, location, and the presence or not of the exoskeleton. The BenchBalance system will be integrated at EUROBENCH facilities to benchmark the balance capabilities of wearable exoskeletons and their users. [ABSTRACT FROM AUTHOR]

Published

2022

12. Gait Shear and Plantar Pressure Monitoring: A Non-Invasive OFS Based Solution for e-Health Architectures.

Author

Tavares, Cátia, Domingues, M. Fátima, Frizera-Neto, Anselmo, Leite, Tiago, Leitão, Cátia, Alberto, Nélia, Marques, Carlos, Radwan, Ayman, Rocon, Eduardo, André, Paulo, and Antunes, Paulo

Subjects

SHEAR (Mechanics), INFORMATION & communication technologies, OPTICAL fiber detectors, DIABETIC foot, FIBER Bragg gratings

Abstract

In an era of unprecedented progress in sensing technology and communication, health services are now able to closely monitor patients and elderly citizens without jeopardizing their daily routines through health applications on their mobile devices in what is known as e-Health. Within this field, we propose an optical fiber sensor (OFS) based system for the simultaneous monitoring of shear and plantar pressure during gait movement. These parameters are considered to be two key factors in gait analysis that can help in the early diagnosis of multiple anomalies, such as diabetic foot ulcerations or in physical rehabilitation scenarios. The proposed solution is a biaxial OFS based on two in-line fiber Bragg gratings (FBGs), which were inscribed in the same optical fiber and placed individually in two adjacent cavities, forming a small sensing cell. Such design presents a more compact and resilient solution with higher accuracy when compared to the existing electronic systems. The implementation of the proposed elements into an insole is also described, showcasing the compactness of the sensing cells, which can easily be integrated into a non-invasive mobile e-Health solution for continuous remote gait monitoring of patients and elder citizens. The reported results show that the proposed system outperforms existing solutions, in the sense that it is able to dynamically discriminate shear and plantar pressure during gait. [ABSTRACT FROM AUTHOR]

Published

2018

13. Development and Evaluation of BenchBalance: A System for Benchmarking Balance Capabilities of Wearable Robots and Their Users.

Author

Bayón C, Delgado-Oleas G, Avellar L, Bentivoglio F, Di Tommaso F, Tagliamonte NL, Rocon E, and van Asseldonk EHF

Subjects

Benchmarking, Crutches, Humans, Lower Extremity, Exoskeleton Device, Wearable Electronic Devices

Abstract

Recent advances in the control of overground exoskeletons are being centered on improving balance support and decreasing the reliance on crutches. However, appropriate methods to quantify the stability of these exoskeletons (and their users) are still under development. A reliable and reproducible balance assessment is critical to enrich exoskeletons' performance and their interaction with humans. In this work, we present the BenchBalance system, which is a benchmarking solution to conduct reproducible balance assessments of exoskeletons and their users. Integrating two key elements, i.e., a hand-held perturbator and a smart garment, BenchBalance is a portable and low-cost system that provides a quantitative assessment related to the reaction and capacity of wearable exoskeletons and their users to respond to controlled external perturbations. A software interface is used to guide the experimenter throughout a predefined protocol of measurable perturbations, taking into account antero-posterior and mediolateral responses. In total, the protocol is composed of sixteen perturbation conditions, which vary in magnitude and location while still controlling their orientation. The data acquired by the interface are classified and saved for a subsequent analysis based on synthetic metrics. In this paper, we present a proof of principle of the BenchBalance system with a healthy user in two scenarios: subject not wearing and subject wearing the H2 lower-limb exoskeleton. After a brief training period, the experimenter was able to provide the manual perturbations of the protocol in a consistent and reproducible way. The balance metrics defined within the BenchBalance framework were able to detect differences in performance depending on the perturbation magnitude, location, and the presence or not of the exoskeleton. The BenchBalance system will be integrated at EUROBENCH facilities to benchmark the balance capabilities of wearable exoskeletons and their users.

Published

2021