A Case Study of Upper Limb Robotic-Assisted Therapy Using the Track-Hold Device

Righi, Marco; Magrini, Massimo; Dolciotti, Cristina; Moroni, Davide

doi:10.3390/s22031009

Cited by 6 publications

(4 citation statements)

References 35 publications

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“…The robot mechanism is propelled by gravitational and inertial forces. It is equipped with wearable sensors and free‐contact devices for gesture tracking on the wrist, elbow, and shoulder 16,17 …”

Section: Introductionmentioning

confidence: 99%

Robotic arm use for upper limb rehabilitation after stroke: A systematic review and meta‐analysis

Lee

Saragih

Batubara

2023

The Kaohsiung J of Med Scie

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Several studies have reported the effects of robotic arms on improving upper limb function in patients with stroke. However, previous studies have reported inconsistent findings that may lead to incorrect applications of robotic arm use. Six databases were searched for relevant randomized controlled trials. Meta-analyses were performed for upper limb performance measures, including subgroup analysis of pooled upper limb rehabilitation data such as stroke stage and intervention delivery dose.Furthermore, the Cochrane risk-of-bias tool for randomized trials version 2 (RoB 2) and sensitivity analysis were used to assess methodology and determine publication bias. The final analysis included 18 studies. Robotic arms improved upper limb and hand function in patients with stroke. Subgroup analysis revealed that robotic arm interventions lasting 30-60 min per session significantly improved upper limb function. However, no significant improvement was observed in shoulder and elbow or wrist and hand movements. This review may help develop applicable rehabilitation robots and collaboration between clinicians.

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Section: Introductionmentioning

confidence: 99%

Robotic arm use for upper limb rehabilitation after stroke: A systematic review and meta‐analysis

Lee

Saragih

Batubara

2023

The Kaohsiung J of Med Scie

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“…Nowadays, robot arms for pick-and-place and assembly tasks have matured [ 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 ], and many factory robot arms now use two- or three-finger grippers for tasks, and many research papers have been conducted in this direction or for experiments [ 9 , 10 , 11 , 12 ]. Some use algorithms for control [ 13 ] and others use visual images and machine learning to allow robotic arms to perform tasks [ 14 , 15 ].…”

Section: Introductionmentioning

confidence: 99%

Eye-in-Hand Robotic Arm Gripping System Based on Machine Learning and State Delay Optimization

Chen

2023

Sensors

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This research focused on using RGB-D images and modifying an existing machine learning network architecture to generate predictions of the location of successfully grasped objects and to optimize the control system for state delays. A five-finger gripper designed to mimic the human palm was tested to demonstrate that it can perform more delicate missions than many two- or three-finger grippers. Experiments were conducted using the 6-DOF robot arm with the five-finger and two-finger grippers to perform at least 100 actual machine grasps, and compared to the results of other studies. Additionally, we investigated state time delays and proposed a control method for a robot manipulator. Many studies on time-delay systems have been conducted, but most focus on input and output delays. One reason for this emphasis is that input and output delays are the most commonly occurring delays in physical or electronic systems. An additional reason is that state delays increase the complexity of the overall control system. Finally, it was demonstrated that our network can perform as well as a deep network architecture with little training data and omitting steps, such as posture evaluation, and when combined with the hardware advantages of the five-finger gripper, it can produce an automated system with a gripping success rate of over 90%. This paper is an extended study of the conference paper.

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“…Ritchie et al [ 8 , 9 ] developed a passive robotic arm capable of recording and facilitating the movement of the upper extremity to aid in the rehabilitation of the upper extremity after stroke. Another line of scholars [ 10 , 11 ] have suggested that robotic-assisted therapy may help improve arm and function in patients with cervical spinal cord injury.…”

Section: Introductionmentioning

confidence: 99%

Using Artificial Neuro-Molecular System in Robotic Arm Motion Control—Taking Simulation of Rehabilitation as an Example

Chen¹

2022

Sensors

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Under the delicate control of the brain, people can perform graceful movements through the coordination of muscles, bones, ligaments, and joints. If artificial intelligence can be used to establish a control system that simulates the movements of human arms, it is believed that the application scope of robotic arms in assisting people’s daily life can be greatly increased. The purpose of this study is to build a general system that can use intelligent techniques to assist in the construction of a personalized rehabilitation system. More importantly, this research hopes to establish an intelligent system that can be adjusted according to the needs of the problem domain, that is, the system can move toward the direction of problem-solving through autonomous learning. The artificial neural molecular system (ANM system), developed early in our laboratory, which captured the close structure/function relationship of biological systems, was used. The system was operated on the V-REP (Virtual Robot Experimentation Platform). The results show that the ANM system can use self-learning methods to adjust the start-up time, rotation angle, and the sequence of the motor operation of different motors in order to complete the designated task assignment.

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A Case Study of Upper Limb Robotic-Assisted Therapy Using the Track-Hold Device

Cited by 6 publications

References 35 publications

Robotic arm use for upper limb rehabilitation after stroke: A systematic review and meta‐analysis

Robotic arm use for upper limb rehabilitation after stroke: A systematic review and meta‐analysis

Eye-in-Hand Robotic Arm Gripping System Based on Machine Learning and State Delay Optimization

Using Artificial Neuro-Molecular System in Robotic Arm Motion Control—Taking Simulation of Rehabilitation as an Example

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