Search

Your search keyword '"Lokesh, Rakshith"' showing total 20 results
Start Over Author "Lokesh, Rakshith"
20 results on '"Lokesh, Rakshith"'

1. Immersive Virtual Reality and Robotics for Upper Extremity Rehabilitation

Author

Chheang, Vuthea, Lokesh, Rakshith, Chaudhari, Amit, Wang, Qile, Baron, Lauren, Kiafar, Behdokht, Doshi, Sagar, Thostenson, Erik, Cashaback, Joshua, and Barmaki, Roghayeh Leila

Subjects
Computer Science - Human-Computer Interaction, Computer Science - Robotics
Abstract

Stroke patients often experience upper limb impairments that restrict their mobility and daily activities. Physical therapy (PT) is the most effective method to improve impairments, but low patient adherence and participation in PT exercises pose significant challenges. To overcome these barriers, a combination of virtual reality (VR) and robotics in PT is promising. However, few systems effectively integrate VR with robotics, especially for upper limb rehabilitation. This work introduces a new virtual rehabilitation solution that combines VR with robotics and a wearable sensor to analyze elbow joint movements. The framework also enhances the capabilities of a traditional robotic device (KinArm) used for motor dysfunction assessment and rehabilitation. A pilot user study (n = 16) was conducted to evaluate the effectiveness and usability of the proposed VR framework. We used a two-way repeated measures experimental design where participants performed two tasks (Circle and Diamond) with two conditions (VR and VR KinArm). We observed no significant differences in the main effect of conditions for task completion time. However, there were significant differences in both the normalized number of mistakes and recorded elbow joint angles (captured as resistance change values from the wearable sleeve sensor) between the Circle and Diamond tasks. Additionally, we report the system usability, task load, and presence in the proposed VR framework. This system demonstrates the potential advantages of an immersive, multi-sensory approach and provides future avenues for research in developing more cost-effective, tailored, and personalized upper limb solutions for home therapy applications., Comment: 9 pages, 6 figures

Published
2023

4. Roles and interplay of reinforcement-based and error-based processes during reaching and gait in neurotypical adults and individuals with Parkinson's disease.

Author

Roth, Adam M., Buggeln, John H., Hoh, Joanna E., Wood, Jonathan M., Sullivan, Seth R., Ngo, Truc T., Calalo, Jan A., Lokesh, Rakshith, Morton, Susanne M., Grill, Stephen, Jeka, John J., Carter, Michael J., and Cashaback, Joshua G. A.

Subjects
NEURAL circuitry, PARKINSON'S disease, BASAL ganglia, NEUROREHABILITATION, NEURODIVERSITY, GAIT in humans, REINFORCEMENT (Psychology)
Abstract

From a game of darts to neurorehabilitation, the ability to explore and fine tune our movements is critical for success. Past work has shown that exploratory motor behaviour in response to reinforcement (reward) feedback is closely linked with the basal ganglia, while movement corrections in response to error feedback is commonly attributed to the cerebellum. While our past work has shown these processes are dissociable during adaptation, it is unknown how they uniquely impact exploratory behaviour. Moreover, converging neuroanatomical evidence shows direct and indirect connections between the basal ganglia and cerebellum, suggesting that there is an interaction between reinforcement-based and error-based neural processes. Here we examine the unique roles and interaction between reinforcement-based and error-based processes on sensorimotor exploration in a neurotypical population. We also recruited individuals with Parkinson's disease to gain mechanistic insight into the role of the basal ganglia and associated reinforcement pathways in sensorimotor exploration. Across three reaching experiments, participants were given either reinforcement feedback, error feedback, or simultaneously both reinforcement & error feedback during a sensorimotor task that encouraged exploration. Our reaching results, a re-analysis of a previous gait experiment, and our model suggests that in isolation, reinforcement-based and error-based processes respectively boost and suppress exploration. When acting in concert, we found that reinforcement-based and error-based processes interact by mutually opposing one another. Finally, we found that those with Parkinson's disease had decreased exploration when receiving reinforcement feedback, supporting the notion that compromised reinforcement-based processes reduces the ability to explore new motor actions. Understanding the unique and interacting roles of reinforcement-based and error-based processes may help to inform neurorehabilitation paradigms where it is important to discover new and successful motor actions. Author summary: Reinforcement-based and error-based processes play a pivotal role in regulating our movements. Converging neuroanatomical evidence show interconnected reinforcement-based and error-based neural circuits. Yet is unclear how reinforcement-based and error-based processes interact to influence sensorimotor behavior. In our past work we showed that reinforcement-based and error-based processes are dissociable. Building on this work, here we show that these process can also interact to influence trial-by-trial sensorimotor behaviour. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

5. Characterizing the Sensing Response of Carbon Nanocomposite-Based Wearable Sensors on Elbow Joint Using an End Point Robot and Virtual Reality.

Author

Chaudhari, Amit, Lokesh, Rakshith, Chheang, Vuthea, Doshi, Sagar M., Barmaki, Roghayeh Leila, Cashaback, Joshua G. A., and Thostenson, Erik T.

Subjects
*ELBOW joint, *WEFT knit textiles, *TELEREHABILITATION, *EXERCISE therapy, *WEARABLE technology, *ROBOTIC exoskeletons
Abstract

Physical therapy is often essential for complete recovery after injury. However, a significant population of patients fail to adhere to prescribed exercise regimens. Lack of motivation and inconsistent in-person visits to physical therapy are major contributing factors to suboptimal exercise adherence, slowing the recovery process. With the advancement of virtual reality (VR), researchers have developed remote virtual rehabilitation systems with sensors such as inertial measurement units. A functional garment with an integrated wearable sensor can also be used for real-time sensory feedback in VR-based therapeutic exercise and offers affordable remote rehabilitation to patients. Sensors integrated into wearable garments offer the potential for a quantitative range of motion measurements during VR rehabilitation. In this research, we developed and validated a carbon nanocomposite-coated knit fabric-based sensor worn on a compression sleeve that can be integrated with upper-extremity virtual rehabilitation systems. The sensor was created by coating a commercially available weft knitted fabric consisting of polyester, nylon, and elastane fibers. A thin carbon nanotube composite coating applied to the fibers makes the fabric electrically conductive and functions as a piezoresistive sensor. The nanocomposite sensor, which is soft to the touch and breathable, demonstrated high sensitivity to stretching deformations, with an average gauge factor of ~35 in the warp direction of the fabric sensor. Multiple tests are performed with a Kinarm end point robot to validate the sensor for repeatable response with a change in elbow joint angle. A task was also created in a VR environment and replicated by the Kinarm. The wearable sensor can measure the change in elbow angle with more than 90% accuracy while performing these tasks, and the sensor shows a proportional resistance change with varying joint angles while performing different exercises. The potential use of wearable sensors in at-home virtual therapy/exercise was demonstrated using a Meta Quest 2 VR system with a virtual exercise program to show the potential for at-home measurements. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

11. Reinforcement-based processes actively regulate motor exploration along redundant solution manifolds

Author

Roth, Adam M., Calalo, Jan A., Lokesh, Rakshith, Sullivan, Seth R., Grill, Stephen, Jeka, John J., van der Kooij, Katinka, Carter, Michael J., Cashaback, Joshua G.A., Roth, Adam M., Calalo, Jan A., Lokesh, Rakshith, Sullivan, Seth R., Grill, Stephen, Jeka, John J., van der Kooij, Katinka, Carter, Michael J., and Cashaback, Joshua G.A.

Abstract

From a baby's babbling to a songbird practising a new tune, exploration is critical to motor learning. A hallmark of exploration is the emergence of random walk behaviour along solution manifolds, where successive motor actions are not independent but rather become serially dependent. Such exploratory random walk behaviour is ubiquitous across species' neural firing, gait patterns and reaching behaviour. The past work has suggested that exploratory random walk behaviour arises from an accumulation of movement variability and a lack of error-based corrections. Here, we test a fundamentally different idea-that reinforcement-based processes regulate random walk behaviour to promote continual motor exploration to maximize success. Across three human reaching experiments, we manipulated the size of both the visually displayed target and an unseen reward zone, as well as the probability of reinforcement feedback. Our empirical and modelling results parsimoniously support the notion that exploratory random walk behaviour emerges by utilizing knowledge of movement variability to update intended reach aim towards recently reinforced motor actions. This mechanism leads to active and continuous exploration of the solution manifold, currently thought by prominent theories to arise passively. The ability to continually explore muscle, joint and task redundant solution manifolds is beneficial while acting in uncertain environments, during motor development or when recovering from a neurological disorder to discover and learn new motor actions.

Published
2023
Full Text
View/download PDF

12. Supplementary_V1.pdf

Author

Lokesh, Rakshith

Abstract

Supplementary data for the publication. 'Visual Accuracy Dominates Over Haptic Speed for State Estimation of a Partner During Collaborative Sensorimotor Interactions'

Published
2023
Full Text
View/download PDF

20. Reinforcement-based processes actively regulate motor exploration along redundant solution manifolds.

Author

Roth AM, Calalo JA, Lokesh R, Sullivan SR, Grill S, Jeka JJ, van der Kooij K, Carter MJ, and Cashaback JGA

Subjects
Humans, Reward, Movement physiology, Feedback, Psychomotor Performance physiology, Reinforcement, Psychology, Learning physiology
Abstract

From a baby's babbling to a songbird practising a new tune, exploration is critical to motor learning. A hallmark of exploration is the emergence of random walk behaviour along solution manifolds, where successive motor actions are not independent but rather become serially dependent. Such exploratory random walk behaviour is ubiquitous across species' neural firing, gait patterns and reaching behaviour. The past work has suggested that exploratory random walk behaviour arises from an accumulation of movement variability and a lack of error-based corrections. Here, we test a fundamentally different idea-that reinforcement-based processes regulate random walk behaviour to promote continual motor exploration to maximize success. Across three human reaching experiments, we manipulated the size of both the visually displayed target and an unseen reward zone, as well as the probability of reinforcement feedback. Our empirical and modelling results parsimoniously support the notion that exploratory random walk behaviour emerges by utilizing knowledge of movement variability to update intended reach aim towards recently reinforced motor actions. This mechanism leads to active and continuous exploration of the solution manifold, currently thought by prominent theories to arise passively. The ability to continually explore muscle, joint and task redundant solution manifolds is beneficial while acting in uncertain environments, during motor development or when recovering from a neurological disorder to discover and learn new motor actions.

Published
2023
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results