Your search keyword '"Ronald Triolo"' showing total 17 results

1. Motorless cadence control of standard and low duty cycle-patterned neural stimulation intensity extends muscle-driven cycling output after paralysis

Author

Kristen Gelenitis, Kevin Foglyano, Lisa Lombardo, John McDaniel, and Ronald Triolo

Subjects

Paralysis, Spinal cord injury, Exercise, Neural stimulation, Cycling, Feedback control, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Background Stimulation-driven exercise is often limited by rapid fatigue of the activated muscles. Selective neural stimulation patterns that decrease activated fiber overlap and/or duty cycle improve cycling exercise duration and intensity. However, unequal outputs from independently activated fiber populations may cause large discrepancies in power production and crank angle velocity among pedal revolutions. Enforcing a constant cadence through feedback control of stimulus levels may address this issue and further improve endurance by targeting a submaximal but higher than steady-state exercise intensity. Methods Seven participants with paralysis cycled using standard cadence-controlled stimulation (S-Cont). Four of those participants also cycled with a low duty cycle (carousel) cadence-controlled stimulation scheme (C-Cont). S-Cont and C-Cont patterns were compared with conventional maximal stimulation (S-Max). Outcome measures include total work (W), end power (Pend), power fluctuation (PFI), charge accumulation (Q) and efficiency (η). Physiological measurements of muscle oxygenation (SmO2) and heart rate were also collected with select participants. Results At least one cadence-controlled stimulation pattern (S-Cont or C-Cont) improved Pend over S-Max in all participants and increased W in three participants. Both controlled patterns increased Q and η and reduced PFI compared with S-Max and prior open-loop studies. S-Cont stimulation also delayed declines in SmO2 and increased heart rate in one participant compared with S-Max. Conclusions Cadence-controlled selective stimulation improves cycling endurance and increases efficiency over conventional stimulation by incorporating fiber groups only as needed to maintain a desired exercise intensity. Closed-loop carousel stimulation also successfully reduces power fluctuations relative to previous open-loop efforts, which will enable neuroprosthesis recipients to better take advantage of duty cycle reducing patterns.

Published

2022

2. Selective neural stimulation methods improve cycling exercise performance after spinal cord injury: a case series

Author

Kristen Gelenitis, Kevin Foglyano, Lisa Lombardo, and Ronald Triolo

Subjects

Paralysis, Spinal cord Injury, Exercise, Neural stimulation, Musculoskeletal, Cycling, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Background Exercise after paralysis can help prevent secondary health complications, but achieving adequate exercise volumes and intensities is difficult with loss of motor control. Existing electrical stimulation-driven cycling systems involve the paralyzed musculature but result in rapid force decline and muscle fatigue, limiting their effectiveness. This study explores the effects of selective stimulation patterns delivered through multi-contact nerve cuff electrodes on functional exercise output, with the goal of increasing work performed and power maintained within each bout of exercise. Methods Three people with spinal cord injury and implanted stimulation systems performed cycling trials using conventional (S-Max), low overlap (S-Low), low duty cycle (C-Max), and/or combined low overlap and low duty cycle (C-Low) stimulation patterns. Outcome measures include total work (W), end power (Pend), power fluctuation indices (PFI), charge accumulation (Q), and efficiency (η). Mann–Whitney tests were used for statistical comparisons of W and Pend between a selective pattern and S-Max. Welch’s ANOVAs were used to evaluate differences in PFIs among all patterns tested within a participant (n ≥ 90 per stimulation condition). Results At least one selective pattern significantly (p

Published

2021

3. Sum of phase-shifted sinusoids stimulation prolongs paralyzed muscle output

Author

Kristen Gelenitis, Max Freeberg, and Ronald Triolo

Subjects

Neuroprostheses, Paralysis, Stimulation, Fatigue, Duty cycle, Feedback control, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Neuroprostheses that activate musculature of the lower extremities can enable standing and movement after paralysis. Current systems are functionally limited by rapid muscle fatigue induced by conventional, non-varying stimulus waveforms. Previous work has shown that sum of phase-shifted sinusoids (SOPS) stimulation, which selectively modulates activation of individual motor unit pools (MUPs) to lower the duty cycle of each while maintaining a high net muscle output, improves joint moment maintenance but introduces greater instability over conventional stimulation. In this case study, implementation of SOPS stimulation with a real-time feedback controller successfully decreased joint moment instability and further prolonged joint moment output with increased stimulation efficiency over open-loop approaches in one participant with spinal cord injury. These findings demonstrate the potential for closed-loop SOPS to improve functionality of neuroprosthetic systems.

Published

2020

4. Effect of Joint Friction Compensation on a 'Muscle-First' Motor-Assisted Hybrid Neuroprosthesis

Author

Ryan-David Reyes, Rudolf Kobetic, Mark Nandor, Nathaniel Makowski, Musa Audu, Roger Quinn, and Ronald Triolo

Subjects

motorized, exoskeleton, metabolic, consumption, METs, friction, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

This study assessed the metabolic energy consumption of walking with the external components of a “Muscle-First” Motor Assisted Hybrid Neuroprosthesis (MAHNP), which combines implanted neuromuscular stimulation with a motorized exoskeleton. The “Muscle-First” approach prioritizes generating motion with the wearer's own muscles via electrical stimulation with the actuators assisting on an as-needed basis. The motorized exoskeleton contributes passive resistance torques at both the hip and knee joints of 6Nm and constrains motions to the sagittal plane. For the muscle contractions elicited by neural stimulation to be most effective, the motorized joints need to move freely when not actively assisting the desired motion. This study isolated the effect of the passive resistance or “friction” added at the joints by the assistive motors and transmissions on the metabolic energy consumption of walking in the device. Oxygen consumption was measured on six able-bodied subjects performing 6 min walk tests at three different speeds (0.4, 0.8, and 1.2 m/s) under two different conditions: one with the motors producing no torque to compensate for friction, and the other having the motors injecting power to overcome passive friction based on a feedforward friction model. Average oxygen consumption in the uncompensated condition across all speeds, measured in Metabolic Equivalent of Task (METs), was statistically different than the friction compensated condition. There was an average decrease of 8.8% for METs and 1.9% for heart rate across all speeds. While oxygen consumption was reduced when the brace performed friction compensation, other factors may have a greater contribution to the metabolic energy consumption when using the device. Future studies will assess the effects of gravity compensation on the muscular effort required to lift the weight of the distal segments of the exoskeleton as well as the sagittal plane constraint on walking motions in individuals with spinal cord injuries (SCI).

Published

2020

5. Comparison of strategies and performance of functional electrical stimulation cycling in spinal cord injury pilots for competition in the first ever CYBATHLON

Author

Christine Azevedo Coste, Vance Bergeron, Rik Berkelmans, Emerson Fachin Martins, Ché Fornusek, Arnin Jetsada, Kenneth J. Hunt, Raymond Tong, Ronald Triolo, and Peter Wolf

Subjects

spinal cord injury, FES cycling, FES for denervated muscles, competition context, CYBATHLON, Medicine, Human anatomy, QM1-695

Abstract

Functional Electrical Stimulation (FES) can elicit muscular contraction and restore motor function in paralyzed limbs. FES is a rehabilitation technique applied to various sensorimotor deficiencies and in different functional situations, e.g. grasping, walking, standing, transfer, cycling and rowing. FES can be combined with mechanical devices. FES-assisted cycling is mainly used in clinical environments for training sessions on cycle ergometers, but it has also been adapted for mobile devices, usually tricycles. In October 2016, twelve teams participated in the CYBATHLON competition in the FES-cycling discipline for persons with motor-complete spinal cord injury. It was the first event of this kind and a wide variety of strategies, techniques and designs were employed by the different teams in the competition. The approaches of the teams are detailed in this special issue. We hope that the knowledge contained herein, together with recent positive results of FES for denervated degenerating muscles, will provide a solid basis to encourage improvements in FES equipment and open new opportunities for many patients in need of safe and effective FES management. We hope to see further developments and/or the benefit of new training strategies at future FES competitions, e.g. at the Cybathlon 2020 (www.cybathlon.ethz.ch).

Published

2017

6. 2188

Author

Nathaniel Makowski, Rudi Kobetic, Lisa Lombardo, Kevin Foglyano, Gilles Pinault, Stephen Selkirk, and Ronald Triolo

Subjects

Medicine

Abstract

OBJECTIVES/SPECIFIC AIMS: Evaluate the effect of multijoint functional electrical stimulation (FES) on energy consumption during post-stroke walking. METHODS/STUDY POPULATION: A 67-year-old male with chronic stroke was implanted with an 8-channel implanted pulse generator to stimulate flexor and extensor muscles of the hip, knee, and ankle. Oxygen consumption was measured with a k2b4 portable pulmonary gas analyzer during walking with and without FES assistance. Data were analyzed during steady state oxygen consumption within the last 2 minutes of a 5 minute walk. Distance and walking speed were also measured. RESULTS/ANTICIPATED RESULTS: Electrical stimulation increased walking speed from 0.29 to 0.64 minute/second. Faster walking corresponded with increased oxygen consumption from 10.1 to 14.4 mL O2/kg per minute. Energy cost, consumption as a function of distance, decreased from 3.7 to 2.9 mL O2/kg per minute walking with stimulation compared with without. DISCUSSION/SIGNIFICANCE OF IMPACT: These preliminary data suggest improvements in walking speed with FES are accompanied by increased energy consumption and decreased energy cost. Oxygen consumption during FES assisted walking was

Published

2017

7. Restored somatosensation in individuals with lower limb loss improves gait, speed perception, and motor adaptation

Author

Daekyoo Kim, Ronald Triolo, and Hamid Charkhkar

Abstract

Lower limb loss is a significant insult to the body's nervous and musculoskeletal systems. Despite technological advances in prosthesis design, artificial limbs are not yet integrated into the body's physiological systems. Therefore, lower limb amputees (LLAs) experience lower balance confidence, higher fear of falls, and impaired gait mechanics compared to their able-bodied peers (ABs). Restoring sensations perceived as originating directly from the missing limb via implanted neural interfaces were shown to improve balance and performance in certain ambulatory tasks; however, the effects of such evoked sensations on neural circuitries involved in the locomotor activity are not well understood. In this work, we investigated the effects of plantar sensation elicited by peripheral nerve stimulation delivered by multi-contact nerve cuff electrodes on gait symmetry and stability, speed perception, and motor adaptation during walking. We found that restored plantar sensation increased stance time and propulsive force on the prosthetic side, improved gait symmetry, and yielded an enhanced perception of prosthetic limb movement. Most importantly, our results show the locomotor adaptation among LLAs with plantar sensation became similar to ABs. These findings suggest that our peripheral nerve-based approach to elicit plantar sensation directly affects central nervous pathways involved in locomotion and motor adaptation during walking. Our neuroprosthesis provided a unique model to investigate the role of somatosensation in the lower limb during walking and its effects on perceptual recalibration following a locomotor adaptation task. Furthermore, we demonstrated how plantar sensation in LLAs could effectively increase mobility, improve walking dynamics, and possibly reduce fall risks.

Published

2023

8. Trunk Posture from Randomly Oriented Accelerometers

Author

Aidan Friederich, Musa Audu, and Ronald Triolo

Subjects

Motion, Accelerometry, Posture, Humans, sensor fusion, spinal cord injury, accelerometer, neuroprosthesis, Electrical and Electronic Engineering, Muscle, Skeletal, Biochemistry, Instrumentation, Atomic and Molecular Physics, and Optics, Spinal Cord Injuries, Analytical Chemistry

Abstract

Feedback control of functional neuromuscular stimulation has the potential to improve daily function for individuals with spinal cord injuries (SCIs) by enhancing seated stability. Our fully implanted networked neuroprosthesis (NNP) can provide real-time feedback signals for controlling the trunk through accelerometers embedded in modules distributed throughout the trunk. Typically, inertial sensors are aligned with the relevant body segment. However, NNP implanted modules are placed according to surgical constraints and their precise locations and orientations are generally unknown. We have developed a method for calibrating multiple randomly oriented accelerometers and fusing their signals into a measure of trunk orientation. Six accelerometers were externally attached in random orientations to the trunks of six individuals with SCI. Calibration with an optical motion capture system resulted in RMSE below 5° and correlation coefficients above 0.97. Calibration with a handheld goniometer resulted in RMSE of 7° and correlation coefficients above 0.93. Our method can obtain trunk orientation from a network of sensors without a priori knowledge of their relationships to the body anatomical axes. The results of this study will be invaluable in the design of feedback control systems for stabilizing the trunk of individuals with SCI in combination with the NNP implanted technology.

Published

2022

9. Introduction

Author

Ronald Triolo

Subjects

Rehabilitation, Physical Therapy, Sports Therapy and Rehabilitation

Published

2000

10. Preface

Author

Colin Dourish, Robert Kirsch, Sabine Timpf, Ronald Triolo, and Jawad Ali

Subjects

Anesthesiology and Pain Medicine, Neurology, Neurology (clinical), General Medicine

Published

2011

11. Use of the Case Western Reserve/Veterans Administration neuroprosthesis for exercise, standing and transfers by a paraplegic subject

Author

Lori Rhodi, Thomas C. Smith, Michael Miller, Darryl J. DiRisio, Ronald Triolo, Jason P. Gagnon, and George Forrest

Subjects

Male, medicine.medical_specialty, Engineering, Neuroprosthetics, Posture, Biomedical Engineering, Physical Therapy, Sports Therapy and Rehabilitation, Electric Stimulation Therapy, Walking, Metabolic equivalent, Speech and Hearing, Physical medicine and rehabilitation, Activities of Daily Living, medicine, Humans, Orthopedics and Sports Medicine, Spinal cord injury, Exercise, Electric stimulation, Spinal Cord Injuries, Paraplegia, business.industry, Rehabilitation, Prostheses and Implants, Middle Aged, medicine.disease, Gait, United States, Electrodes, Implanted, United States Department of Veterans Affairs, Therapy, Computer-Assisted, Physical therapy, Current technology, business, Metabolic demand, Follow-Up Studies

Abstract

Functional electric stimulation (FES) is a technology that may allow patients with spinal cord injury (SCI) to transfer stand and walk. This paper reports upon the use of the Case Western Reserve Neuroprosthesis by a T6 ASIA B paraplegic subject. The subject was able to stand for two minutes and 50 seconds. He could walk 35 feet with a swing to gait. Measurement of energy consumption showed that metabolic demand was only 2.1 metabolic equivalent units. The factors that limited the use of the device that need to be improved to make the technology practical for household or community ambulation are speed (5.8 m/min) of ambulation and fatigue of the stimulated muscles.Implications for RehabilitationI think that the article is worth publishing for at least three reasons.It demonstrates the use and limitations of use of functional electric stimulation (FES) for standing and transfers by a paraplegic patient.It implies that main limiting factor to current technology is not the stress on the cardiovascular and p...

Published

2011

12. Surgical Simulation of Tendon Transfers to Augment Lower Extremity Function With Functional Neuromuscular Stimulation

Author

Zhao, W., Ronald Triolo, Wibowo, M., and Bhadra, N.

Subjects

musculoskeletal diseases, musculoskeletal system

Abstract

A musculoskeletal model was used to study tendon transfer surgery in order to decouple hip extension and knee flexion in lower extremity FNS applications. Effects of tendon transfer location and shortening length were quantitatively examined based on the resulting moment-generating capacity. Simulation results have shown that moment arm is not sensitive to the transfer locations. Appropriate shortening is the key to counteract the tendon slack caused by the transplantation and to achieve maximal hip extension strength.

Published

1998

13. Implications of hip subluxation for FES-assisted mobility in patients with spinal cord injury

Author

Betz, R. R., Mulcahey, M. J., Smith, B. T., Ronald Triolo, and Mccarthy, J. J.

14. Preliminary performance of a surgically implanted neuroprosthesis for standing and transfers - Where do we stand?

Author

Davis Jr, J. A., Ronald Triolo, Uhlir, J., Bieri, C., Rohde, L., Lissy, D., and Kukke, S.

15. Standing with Functional Neuromuscular Stimulation: Effect of Foot Placement and Feedback Variables

Author

Abbas, J. J., Finley, J. L., Gillette, J. C., Ronald Triolo, and Resig, J. A.

16. Feasibility of Sensory Feedback for Lower Limb Amputees

Author

Case Western Reserve University, United States Department of Defense, and Ronald Triolo, Senior Research Career Scientist, US Department of Veterans Affairs

Published

2023

17. The need for understanding and engaging the patient as consumer of products developed by neural engineering.

Author

Editors, Guest, Jennifer French, Dawn Bardot, Emily Graczyk, Allison Hess-Dunning, J Luis Lujan, Megan Moynahan, Winny Tan, Ronald Triolo, and Adeline Zbrzeski

Published

2018