The Future of Physical Therapy: Integrating Robotics and Exoskeletons in Rehabilitation Protocols
DOI:
https://doi.org/10.63282/3050-9262.IJAIDSML-V5I3P102Keywords:
Robotics, Exoskeletons, Rehabilitation, Physical Therapy, Telerehabilitation, Patient OutcomesAbstract
The integration of robotics and exoskeletons in physical therapy is poised to revolutionize rehabilitation protocols, enhancing both patient outcomes and the efficiency of therapeutic practices. Recent advancements in robotic technology have led to the development of devices that assist in the rehabilitation of patients with various physical impairments, including those recovering from strokes or spinal cord injuries. These devices can perform repetitive movements, allowing for consistent training and increased therapy duration without overburdening therapists. Robotic systems, particularly exoskeletons, provide tailored support for upper and lower limb rehabilitation, improving range of motion and facilitating gait training. They enable therapists to supervise multiple patients simultaneously, thereby addressing the growing demand for rehabilitation services. Furthermore, the automation of therapy sessions through telerehabilitation platforms allows for remote monitoring and assessment, making rehabilitation more accessible. Despite challenges such as cost and technology integration, the benefits of robotic-assisted therapy including improved patient motivation and adherence are significant. As research continues to evolve, the future of physical therapy will likely see a greater emphasis on these technologies, fundamentally transforming rehabilitation practices and enhancing patient recovery trajectories
References
[1] Apokos Rehabilitation. (n.d.). Robotics: The future of rehabilitation. Retrieved from https://apokosrehab.com/blog/robotics-the-future-of-rehabilitation/
[2] Physio-Pedia. (n.d.). Upper extremity rehabilitation using robotics. Retrieved from https://www.physio-pedia.com/Upper_Extremity_Rehabilitation_using_Robotics
[3] Physio-Pedia. (n.d.). Robotic rehabilitation for the lower extremity. Retrieved from https://www.physio-pedia.com/Robotic_Rehabilitation_for_the_Lower_Extremity
[4] ResearchGate. (2024). Integrating physical and cognitive interaction capabilities in a robot-aided rehabilitation platform. Retrieved from https://www.researchgate.net/publication/374411824_Integrating_Physical_and_Cognitive_Interaction_Capabilities_in_a_Robot-Aided_Rehabilitation_Platform
[5] Empower EMR. (n.d.). Robotic physical therapy. Retrieved from https://www.empoweremr.com/blog/robotic-physical-therapy
[6] ResearchGate. (2023). A review study for robotic exoskeletons rehabilitation devices. Retrieved from https://www.researchgate.net/publication/372717346_A_Review_Study_for_Robotic_Exoskeletons_Rehabilitation_Devices
[7] PubMed Central. (n.d.). The development and evaluation of robotic rehabilitation devices. Retrieved from https://pmc.ncbi.nlm.nih.gov/articles/PMC5461931/
[8] Physio-Pedia. (n.d.). Robotic devices used in rehabilitation. Retrieved from https://www.physio-pedia.com/Robotic_Devices_used_in_Rehabilitation
[9] PubMed Central. (2024). Advanced robotic rehabilitation for post-stroke recovery. Retrieved from https://pmc.ncbi.nlm.nih.gov/articles/PMC8543702/
[10] PubMed Central. (2018). Robotic therapy for upper and lower extremities: A systematic review. Retrieved from https://pmc.ncbi.nlm.nih.gov/articles/PMC6153133/
[11] MDPI. (2024). Medical exoskeletons: Impact on rehabilitation and physical therapy. Healthcare, 12(17), 1720. https://www.mdpi.com/2227-9032/12/17/1720
[12] Ekso Bionics. (n.d.). The impact of medical exoskeletons on patients and physical therapists. Retrieved from https://eksobionics.com/the-impact-of-medical-exoskeletons-on-patients-and-physical-therapists/
[13] Made for Movement. (n.d.). Robotic rehabilitation therapy. Retrieved from https://www.madeformovement.com/robotic-rehabilitation-therapy
[14] Frontiers in Robotics and AI. (2024). Integrating robotics in physiotherapy: Emerging trends. Retrieved from https://www.frontiersin.org/journals/robotics-and-ai/articles/10.3389/frobt.2024.1341580/full
[15] Built In. (n.d.). Exoskeleton suit: Revolutionizing rehabilitation. Retrieved from https://builtin.com/robotics/exoskeleton-suit
[16] MDPI. (2024). Rehabilitation devices for robotic therapy. Healthcare, 12(17), 1720. https://www.mdpi.com/2227-9032/12/17/1720
[17] GoLife Ward. (n.d.). Case studies of exo-suits and exoskeletons in clinical practice. Retrieved from https://golifeward.com/blog/ep-04-case-studies-of-exo-suits-and-exoskeletons-in-clinical-practice/
[18] Rehab India. (n.d.). Emerging trends in physiotherapy: Innovations shaping the future. Retrieved from https://rehabindia.org/blog/emerging-trends-in-physiotherapy-innovations-shaping-the-future/
[19] Teerthanker Mahaveer University. (n.d.). The future of physiotherapy: Emerging trends and innovations. Retrieved from https://www.tmu.ac.in/blog/the-future-of-physiotherapy-emerging-trends-and-innovations
[20] Gymna. (n.d.). 5 physiotherapy trends for 2024. Retrieved from https://gymna.com/en/stories/5-physiotherapy-trends-2024
[21] Physiotattva. (n.d.). Emerging physical therapy trends. Retrieved from https://www.physiotattva.com/blog/emerging-physical-therapy-trends
[22] University of the Cumberlands. (n.d.). Technology is changing physical therapy. Retrieved from https://www.ucumberlands.edu/blog/technology-is-changing-physical-therapy
[23] PT Everywhere. (n.d.). The future of physical therapy. Retrieved from https://www.pteverywhere.com/media/the-future-of-physical-therapy
