A bidirectional fabric-based soft robotic glove for hand function assistance in patients with chronic stroke

Lim, Daniel Yuan-Lee; Lai, Hwa-Sen; Yeow, Raye Chen-Hua

doi:10.1186/s12984-023-01250-4

Cited by 5 publications

(3 citation statements)

References 39 publications

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“…Lastly, p1 and p2 correspond to the centers of mass for the thigh and calf, and l1 and l2 represent the lengths of the thigh and calf, respectively. (3) Kinematic analysis The kinematic analysis of the lower limb robot is mainly based on the parameters such as rod length to establish the mathematical relationship between the joint angle and the end, which is divided into two analysis methods: positive kinematics and inverse kinematics [20][21][22][23][24]. In this paper, the inverse kinematics analysis method is mainly used, according to the position data of the end of the human lower limb hip a(…”

Section: Structural Design Of a Wearable Exoskeleton Robot For Lower ...mentioning

confidence: 99%

Design and Motion Characterisation of a Wearable Lower Limb Rehabilitation Exoskeleton Robot

2024

IJOMAM

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Section: Structural Design Of a Wearable Exoskeleton Robot For Lower ...mentioning

confidence: 99%

Design and Motion Characterisation of a Wearable Lower Limb Rehabilitation Exoskeleton Robot

2024

IJOMAM

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“…However, traditional robots can be challenging to align with the ultra-compact multi-degree of freedom (DOF) human hand, are complex to use, and are generally expensive, thus limiting the adoption out of high-tech clinics and the usage at-home unsupervised (Langan et al, 2018 ). Soft robotic gloves, made of textiles and using cables (e.g., Xiloyannis et al, 2016 ; Ghassemi et al, 2018 ; Kang et al, 2019 ; Yurkewich et al, 2020 ), pneumatics (e.g., Coffey et al, 2014 ; Polygerinos et al, 2015 ; Zhou et al, 2019 ; Correia et al, 2020 ; Lai et al, 2023a , 2023b ; Lim et al, 2023 ), or serial elastic actuators (e.g., Xu et al, 2023 ) as the actuation mechanism, have been presented more recently as an alternative to traditional exoskeletons (Chu and Patterson, 2018 ; Proulx et al, 2020 ; Akbari et al, 2021 ). They potentially allow reduced weight, lower form factor, and increased portability, improved capability to interact with real-life items during ADLs, suitability for safe and independent use at home, and generally lower costs than exoskeletons.…”

Section: Introductionmentioning

confidence: 99%

Combining soft robotics and telerehabilitation for improving motor function after stroke

Proietti,

Nuckols,

Grupper

et al. 2024

Wearable Technol.

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Telerehabilitation and robotics, either traditional rigid or soft, have been extensively studied and used to improve hand functionality after a stroke. However, a limited number of devices combined these two technologies to such a level of maturity that was possible to use them at the patients’ home, unsupervised. Here we present a novel investigation that demonstrates the feasibility of a system that integrates a soft inflatable robotic glove, a cloud-connected software interface, and a telerehabilitation therapy. Ten chronic moderate-to-severe stroke survivors independently used the system at their home for 4 weeks, following a software-led therapy and being in touch with occupational therapists. Data from the therapy, including automatic assessments by the robot, were available to the occupational therapists in real-time, thanks to the cloud-connected capability of the system. The participants used the system intensively (about five times more movements per session than the standard care) for a total of more than 8 hr of therapy on average. We were able to observe improvements in standard clinical metrics (FMA +3.9 ± 4.0, p < .05, COPM-P + 2.5 ± 1.3, p < .05, COPM-S + 2.6 ± 1.9, p < .05, MAL-AOU +6.6 ± 6.5, p < .05) and range of motion (+88%) at the end of the intervention. Despite being small, these improvements sustained at follow-up, 2 weeks after the end of the therapy. These promising results pave the way toward further investigation for the deployment of combined soft robotic/telerehabilitive systems at-home for autonomous usage for stroke rehabilitation.

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“…However, the soft extending actuator may buckle, influencing the bending effects of the finger. For the soft bending actuator, finger flex is similar to the soft extending actuators, like the fiber-reinforced bending actuator and fabric-based pneumatic actuator [25][26][27]. Although there is no buckling for the soft bending actuator and they can bear a high-pressure input, users may feel uncomfortable if the bending trajectory of the soft actuator is inconsistent with the finger flexion.…”

Section: Introductionmentioning

confidence: 99%

Finger joint aligned flat tube folding structure for robotic glove design

Liu,

Wu,

Lin

et al. 2023

Smart Mater. Struct.

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Pneumatic soft actuators have been widely considered the safest actuation technology for use in wearable rehabilitation robots. For soft robotic gloves, researchers commonly put soft extending or bending actuators on dorsal fingers to assist hand flexion. In this research, we propose a novel pre-folded flat tube actuator (PFTA) to assist finger flex into a pre-set bending angle or contact force. The PFTA has three folds, aligned with each of the finger joint. Different from other soft actuators, the PFTA exerts bending torque directly on each finger joint without large actuator deformation. The PFTA made of heat shrink flat tube has a small profile, with low cost, easy fabrication, and high safety. When actuated, the PFTA has the tendency to unfold as well, we call this effect as unfolding flat tube actuation. This effect is characterized by a range of bending angles and input air pressures in which four distinct response regimes were observed. They are defined as shearing, collapsing, creasing, and flattening regimes. Similarly, experimental characterization of PFTAs is also conducted to evaluate the level of joint flexion assistance based on which design guidelines for robotic gloves are recommended. Finally, we build PFTAs on a soft wearable glove and demonstrate their capability in assisting the grasping operations of various object shapes.

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A bidirectional fabric-based soft robotic glove for hand function assistance in patients with chronic stroke

Cited by 5 publications

References 39 publications

Design and Motion Characterisation of a Wearable Lower Limb Rehabilitation Exoskeleton Robot

Design and Motion Characterisation of a Wearable Lower Limb Rehabilitation Exoskeleton Robot

Combining soft robotics and telerehabilitation for improving motor function after stroke

Finger joint aligned flat tube folding structure for robotic glove design

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