IEEE Access (Jan 2023)

Development of a Robot-Assisted Telerehabilitation System With Integrated IIoT and Digital Twin

  • Md. Mahafuzur Rahaman Khan,
  • Md. Samiul Haque Sunny,
  • Tanvir Ahmed,
  • Md. Tanzil Shahria,
  • Preet Parag Modi,
  • Md. Ishrak Islam Zarif,
  • Javier Dario Sanjuan De Caro,
  • Sheikh Iqbal Ahamed,
  • Helal Uddin Ahmed,
  • Erin M. Mcgonigle Ketchum,
  • Mohammad H. Rahman

DOI
https://doi.org/10.1109/ACCESS.2023.3291803
Journal volume & issue
Vol. 11
pp. 70174 – 70189

Abstract

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Upper limb dysfunction (ULD) is common following a stroke, spinal cord injury, trauma, and occupational accidents. Post-stroke patients with ULD need long-term assistance from therapists for their rehabilitation, which generally occurs at the hospital or outpatient clinic. Physical therapists are unavailable because of geographical, financial, and scheduling concerns, and continuity of care needs to be improved due to the need to travel to multiple locations for therapy. As a result, providing specific, tailored therapy programs is challenging due to the absence of feedback and real-time monitoring. An effective telerehabilitation system can address this issue and is more cost-effective for healthcare providers and patients than traditional inpatient or person-to-person rehabilitation. Remotely operating robotic devices and using advanced technology improves patient and healthcare provider safety and reduces injuries. In this study, we developed a novel telerehabilitation framework for rehabilitation robots utilizing PTC’s Industrial Internet of Things (IIoT) platform to remotely provide robot-aided therapies for individuals with ULD. With the developed telerehabilitation framework, an operator can teleoperate the rehab robots to deliver Upper-limb (UL) exercises via an Augmented Reality (AR) based graphical user interface (GUI). This AR platform communicates bidirectionally using ThingWorx IIOT. It leverages the digital twin (DT) structure facilitated by Vuforia studio to visualize the physical robot motions happening in remote places. The telerehabilitation framework was validated through a commercially available robot (xArm 5), an exoskeleton (SREx), and an end-effector type rehabilitation robot (DMRbot) developed at Biorobotics Lab, UWM. The experiment results show that the telerehabilitation system can successfully provide UL rehab exercises in 2D and 3D planes via AR. The proposed framework is developed to facilitate robust and more promising robot-aided rehabilitation sessions remotely, and it can also be applied in other medical applications.

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