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Virtual reality in telerehabilitation

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Virtual reality in telerehabilitation is a method used first in the training of musculoskeletal patients using asynchronous patient data uploading, and an internet video link. Subsequently, therapists using virtual reality-based telerehabilitation prescribe exercise routines via the web which are then accessed and executed by patients through a web browser. Therapists then monitor the patient's progress via the web and modify the therapy asynchronously without real-time interaction or training.[1]

Background

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The computer technology that allows development three-dimensional virtual environments consists of both hardware and software. The current popular, technical, and scientific interest in virtual environments is inspired, in large part, by the advent and availability of increasingly powerful and affordable visually oriented, interactive, graphical display systems and techniques lacking only sense and sensibility.

The term "virtualized reality" (VR) was coined and introduced in a paper by Kanade. The traditional virtual reality world is typically constructed using simplistic, artificially created computer-aided design (CAD) models. VR starts with the real-world scene and virtualizes it.[2] Virtual reality is a practical, affordable technology for the practice of clinical medicine, and modern, high-fidelity virtual reality systems have practical applications in areas ranging from psychiatry to surgical planning and telemedicine.[3] Through VR's capacity to allow the creation and control of dynamic 3-dimensional, ecologically valid stimulus environments within which behavioral response can be recorded and measured, it offers clinical assessment and rehabilitation options not available with traditional methods.[4]

Application

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The value of VR systems for the investigation and rehabilitation of cognitive and perceptual impairments and current and potential applications of VR technology address six neurorehabilitation issues.[5] Korean researchers developed and assessed the value of a new rehabilitation training system to improve postural balance control by combining virtual reality technology with an unfixed bicycle. The system was effective as a training device; in addition, the technology might have a wider applicability to the rehabilitation field.[6]

Tracy and Lathan investigated the relationship between motor tasks and participants' spatial abilities by training participants within a VR based simulator and then observing their ability to transfer training from the simulator to the real world. The study demonstrated that subjects with lower spatial abilities achieved significant positive transfer from a simulator based training task to a similar real world robotic operation task.[7]

Virtual environments were applied to assess the training of inexperienced powered wheelchair users and demonstrated that the two virtual environments represent a potentially useful means of assessing and training novice powered wheelchair users.[8] A recently completed project at the University of Strathclyde has resulted in the development of a wheelchair motion platform which, in conjunction with a virtual reality facility, can be used to address issues of accessibility in the built environment.[9]

Many cases have applied virtual reality technology to telemedicine and telerehabilitation service development. Because telemedicine focuses principally on transmitting medical information, VR has potential to enhance the practice. One significant advancement[10] is the use of VR in telerehabilitation to help patients overcome geographic and mobility barriers by enabling them to engage in therapy remotely. This is particularly important in regions with limited access to healthcare services, where VR-based telerehabilitation can significantly improve patient outcomes without requiring physical attendance at medical facilities. State of the art of VR-based telemedicine applications is used in remote or augmented surgery as well as in surgical training, both of which are critically dependent on eye–hand coordination. Recently, however, different researchers have tried to use virtual environments in medical visualization and for assessment and rehabilitation in neuropsychology.[11]

Case studies for VR applications were conducted that were internet deliverable and they identified technical, practical, and user challenges of remote VR treatment programs.[12] To improve understanding of deficits in autism and in left visual-spatial neglect, Trepagnier et al. investigated face gaze behavior in autism and right hemisphere stroke, using virtual reality and gaze sensing technology.[13]

An at-home stroke telerehabilitation service was developed using virtual reality haptics.[14] Researchers from Rutgers University and Stanford University developed a virtual reality-based orthopedic telerehabilitation system.[15][16][17]

The use of virtual reality technologies in the rehabilitation of patients with vestibular system disorders and in the provision of remote medical consultation for those patients. He stated that an appropriately designed VR experience could greatly increase the rate of adaptation in these patients.[18]

Accessibility

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While VR enables greater accessibility for some, it also carries the risk of exclusion for others, particularly those without adequate resources to access VR technology and those with disabilities that restrict them from the use of virtual reality in telerehabilitation.

Remote VR treatment programs require both a stable access to the internet and varying VR equipment. With one third of the world population not having any access to the internet(UN SOURCE), the access to remote VR treatment programs might be limited. At the same time, the price of the VR headset combined with the specialized accessories for the remote VR treatment programs may exacerbate existing economic disparities in healthcare.

Epilepsy is a chronic neurological disorder that is typically the case of recurrent seizures. These seizures are sudden, temporary alterations of brain function that cause involuntary movements, sensations, or changes in consciousness. These epileptic episodes can be triggered by various light patterns. With VR being a bright screen so close to the eyes, epilepsy patients are generally excluded from VR telerehabilitation due to the concern that using it may trigger seizures. [19]

People’s social identities, such as class and disorders as mentioned above, unfortunately play a role in patients' accessibility to the use of VR telerehabilitation. Because this technology is so new, medical engineers have not had the time nor resources to make the proper advancements to this technology to make it more accessible.

Statistics

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Telerehabilitation has made a huge improvement in rehab accessibility and efficiency. For instance in fields such as Musculoskeletal Rehabilitation, Stroke Recovery, Parkinson’s Disease, and Chronic Pain Management in Cancer Patients, improvements have been quite apparent.

In Musculoskeletal Rehabilitation, 80% of patients using VR for musculoskeletal issues reported improvements in mobility and pain management. [5]This figure highlights how VR can effectively enhance physical therapy outcomes, allowing patients to engage in tailored exercises from home. By utilizing VR's immersive capabilities, patients can perform exercises that feel more engaging, thus increasing adherence to their rehabilitation routines.

See also

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References

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  1. ^ Westwood, James D.; Helene M. Hoffman, Randy S. Haluck, Greg T. Mogel, R. Phillips, Richard A. Robb, K.G. Vosburgh (2005). Medicine Meets Virtual Reality 13: The Magical Next Becomes The Medical Now. IOS Press. p. 294. ISBN 978-1-58603-498-6.{{cite book}}: CS1 maint: multiple names: authors list (link)
  2. ^ Kanade, T.; P.J. Narayanan and P.W. Rander (1995). "Virtualized Reality: Concepts and Early Results". IEEE Workshop on Representation of Visual Scenes, 1995, Proceedings. Los Alamitos, Calif. : IEEE Computer Society Press, c1995. pp. 69–76. CiteSeerX 10.1.1.187.7689. doi:10.1109/WVRS.1995.476854. ISBN 978-0-8186-7122-7. S2CID 56633722.
  3. ^ Bergeron, B. (2003). "Virtual reality applications in clinical medicine". Journal of Medical Practice Management. 18 (4): 211–5. PMID 12661483.
  4. ^ Schultheis, Maria T.; Albert A. Rizzo (August 2001). "The application of virtual reality technology in rehabilitation". Rehabilitation Psychology. 46 (3): 296–311. doi:10.1037/0090-5550.46.3.296.
  5. ^ a b Trepagnier, Cheryl C. (January 1999). "Virtual environments for the investigation and rehabilitation of cognitive and perceptual impairments". NeuroRehabilitation. 12 (1): 63–72. doi:10.3233/NRE-1999-12107. Retrieved 2007-07-26.
  6. ^ Song, Chul Gyu; Jong Yun Kim and Nam Gyun Kim (June 2004). "A new postural balance control system for rehabilitation training based on virtual cycling". IEEE Transactions on Information Technology in Biomedicine. 8 (2): 200–207. doi:10.1109/TITB.2004.828887. PMID 15217265.
  7. ^ Tracey, M. R.; C. E. Lathan (2001). The interaction of spatial ability and motor learning in the transfer of training from a simulator to a real task. Vol. 81. pp. 521–7. ISBN 978-1-58603-143-5. PMID 11317801. {{cite book}}: |journal= ignored (help)
  8. ^ Harrison, A.; G. Derwent; A. Enticknap; F. D. Rose; E. A. Attree (2002). "The role of virtual reality technology in the assessment and training of inexperienced powered wheelchair users". Disability & Rehabilitation. 24 (11–12): 599–606. doi:10.1080/09638280110111360. PMID 12182799. S2CID 24219364.
  9. ^ Grant, M. "Wheelchair Simulation in Virtual Reality". Space Requirements for Wheeled Mobility: An International Workshop, Amherst, 2003. Retrieved 2006-07-26.
  10. ^ Park, Catherine (May 6, 2024). "A systematic review of the effects of interactive telerehabilitation with remote monitoring and guidance on balance and gait performance in older adults and individuals with neurological conditions". Bioengineering. 11 (5): 460. doi:10.3390/bioengineering11050460. PMC 11117498. PMID 38790328.
  11. ^ Riva, Giuseppe; Luciano Gamberini (2000). "Virtual reality in telemedicine". Telemedicine Journal and e-Health. 6 (3): 327–40. CiteSeerX 10.1.1.3.8473. doi:10.1089/153056200750040183. PMID 11110636.
  12. ^ Rizzo, Albert A.; Dorothy Strickland and Stéphane Bouchard (2004). "The challenge of using virtual reality in telerehabilitation". Telemedicine Journal and e-Health. 10 (2): 184–95. doi:10.1089/tmj.2004.10.184. PMID 15319048.
  13. ^ Trepagnier, Cheryl; Michael J. Rosen; Corinna Lathan. "Telerehabilitation and virtual reality technology for rehabilitation: preliminary results". Conference on Technology and Persons with Disabilities, California State University at Northridge, 1999.
  14. ^ Rydmark, M.; J. Boeren and R. Pasher; Pascher, R (2002). Stroke rehabilitation at home using virtual reality, haptics and telemedicine. Vol. 85. pp. 434–7. ISBN 978-1-58603-203-6. PMID 15458128. {{cite book}}: |journal= ignored (help)
  15. ^ Burdea, G. C.; V. G. Popescu, V. R. Hentz and K. Colbert (September 2000). "Virtual reality-based orthopedic telerehabilitation". IEEE Transactions on Rehabilitation Engineering. 8 (3): 430–2. CiteSeerX 10.1.1.456.2349. doi:10.1109/86.867886. PMID 11001524.
  16. ^ Popescu, V. G.; G. C. Burdea, M. Bouzit and V. R. Hentz (March 2000). "A virtual-reality-based telerehabilitation system with force feedback". IEEE Transactions on Information Technology in Biomedicine. 4 (1): 45–51. CiteSeerX 10.1.1.131.7620. doi:10.1109/4233.826858. PMID 10761773. S2CID 15159473.
  17. ^ Burdea, G. C. (2003). "Virtual rehabilitation—benefits and challenges". Methods of Information in Medicine. 42 (5): 519–23. doi:10.1055/s-0038-1634378. PMID 14654886. S2CID 4772209.
  18. ^ Viirre, E. (1996). Vestibular telemedicine and rehabilitation. Vol. 29. pp. 299–305. ISBN 978-90-5199-250-2. PMID 10163763. {{cite book}}: |journal= ignored (help)
  19. ^ "What is Epilepsy?".
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