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Real-Time Balance Feedback Mechanism For Orthopedic and Neuromuscular Diseases Rehabilitation Practices

Year 2020, Issue: 3, 412 - 417, 01.09.2020

Abstract

Biological feedback, which favors motor control in static and dynamic tasks via augmenting motor information for improving balance and performance, is used to assist patients and clinicians during rehabilitation. Lack of balance and postural control has the greatest impact on patients’ mobilization and independent performance during the activities of daily living. Although an individual’s “static” balance is acceptable while standing still or performing a single task at a time; “dynamic” balance problems may become apparent during mobilization or while doing multiple tasks at a time. Therefore, being aware of the real-time dynamic balance of the patient is critical for both the patient and the physical therapist. This investigation developed a tactile and visual biological feedback mechanism intended to be used during the orthopedic and neuromuscular disease rehabilitation

References

  • Alexander RM. Bipedal animals and their differences from humans. J Anat 2004;204:321–30. https://www.ncbi.nlm.nih.gov/pmc/articles/ PMC1571302/
  • Pau M, Ibba PM, Attene G. Fatigue-induced balance impairment in young soccer players. J Athl Train 2014;49:454–61. [CrossRef]
  • Friedrich EVC, Mc Farland DJ, Neuper C, Vaughan TM, Brunner P, Wolpaw JR. A scanning protocol for a sensorimotor rhythm- based brain-computer interface. Biol Psychol 2009;80:169–75. [CrossRef ]
  • Bohnsack Mc Lagan NK, Cusumano JP, Dingwell JB. Adaptability of stride-to-stride control of stepping movements in human walking. J Biomech 2016;49:229–37. [CrossRef]
  • Bourne RB, Chesworth BM, Davis AM, Mahomed NN, Charron KDJ. Patient satisfaction after total knee arthroplasty: who is satisfied and who is not?. Clin Orthop Relat Res 2010;468:57–63. [CrossRef]
  • Christensen JC, La Stayo PC, Marcus RL, Stoddard GJ, Bo Foreman K, Mizner RL, et al. Visual knee-kinetic biofeedback technique normalizes gait abnormalities during high-demand mobility after total knee arthroplasty. Knee 2018;25:73–82. [CrossRef]
  • Kondilopoulos N, Rousanoglou EN, Boudolos KD. Inertial sensing of the motion speed effect on the sit-to-walk activity. Gait Posture 2018;61:111–6. [CrossRef]
  • Jiang GP, Jiao XB, Wu SK, Ji ZQ, Liu WT, Chen X, Wang HH. Balance, Proprioception, and Gross Motor Development of Chinese Children Aged 3 to 6 Years. J Mot Behav 2018;50:343–52. [CrossRef]
  • Collins DF, Refshauge KM, Todd G, Gandevia SC. Cutaneous receptors contribute to kinesthesia at the index finger, elbow, and knee. J Neurophysiol 2005;94:1699–706. [CrossRef]
  • Daffertshofer A, Lamoth CJ, Meijer OG, Beek PJ. Principal components analysis in studying coordination and variability: A tutorial. Clin Biomech 2004;19:415–28. [CrossRef]
  • Guo L, Xiong S. Accuracy of Base of Support Using an Inertial Sensor Based Motion Capture System. Sensors (Basel) 2017;17:2091. [CrossRef]
  • Segers V, Aerts P, Lenoir M, De Clercq D. Spatiotemporal characteristics of the walk-to-run and run-to-walk transition when gradually changing speed. Gait Posture 2006;24:247–54. [CrossRef]
  • Fothergill S. Examining the effect of real-time visual feedback on the quality of rowing technique. Procedia Eng 2010;2:3083–8 [CrossRef]
  • Hiley MJ, Yeadon MR. Optimisation of high bar circling technique for consistent performance of a triple piked somersault dismount. J Biomech 2008;41:1730–5. [CrossRef]
  • Novacheck TF. The biomechanics of running. Gait Posture 1998;7:77– 95. [CrossRef]
  • Barra J, Pérennou D, Thilo KV, Gresty MA, Bronstein AM. The awareness of body orientation modulates the perception of visual vertical. Neuropsychologia 2012;50:2492–8. [CrossRef]
  • Assaiante C, Barlaam F, Cignetti F, Vaugoyeau M. Body schema building during childhood and adolescence: a neurosensory approach. Neurophysiol Clin 2014;44:3–12. [CrossRef]
  • Barrios JA, Crossley KM, Davis IS. Gait retraining to reduce the knee adduction moment through real-time visual feedback of dynamic knee alignment. J Biomech 2010;43:2208–13. [CrossRef]
  • Christiansen CL, Bade MJ, Davidson BS, Dayton MR, Stevens-Lapsley JE. Effects of Weight-bearing biofeedback training on functional movement patterns following total knee arthroplasty: a randomized controlled trial. J Orthop Sports Phys Ther 2015;45:647–55. [CrossRef]
  • Kearney E, Shellikeria S, Martino R, Yunusova Y. Augmented visual feedback-aided interventions for motor rehabilitation in Parkinson’s disease: a systematic review. Disabil Rehabil 2019;41:995–1011. [CrossRef]
  • Pogonchenkova IV, Khan MA, Korchazhkina NB, Novikova EV, Bokova IA, Lyan NA. The application of the physical factors for the medical rehabilitation of the children presenting with neurogenic dysfunction of the bladder. Vopr Kurortol Fizioter Lech Fiz Kult 2017;94:53–8. [CrossRef]
  • Imaizumi S, Asai T, Hiromitsu K, Imamizu H. Voluntarily controlled but not merely observed visual feedback affects postural sway. Peer J 2018;6:e4643. [CrossRef]
  • Semprini M, Laffranchi M, Sanguineti V, Avanzino L, Icco RD, Michieli LD, Chiappalone M. Technological Approaches for Neurorehabilitation: From Robotic Devices to Brain Stimulation and Beyond. Front Neurol 2018;9. [CrossRef]
  • Ribeiro VV, de Oliveira AG, da Silva Vitor J, Ramos AC, Brasolotto AG, Silverio KCA,. Effectiveness of Voice Therapy Associated With Electromyographic Biofeedback in Women With Behavioral Dysphonia: Randomized Placebo-Controlled Double-Blind Clinical Trial. J Voice 2019;33:381.e11–22. [CrossRef]
  • Smits BL, Polman RC, Otten B, Pepping GJ, Hettinga FJ. Cycling in the Absence of Task-Related Feedback: Effects on Pacing and Performance. Front Physiol 2016;10;7:348. [CrossRef]
  • Meyns P, de Mettelinge TR, van der Spank J, Coussens M, Van Waelvelde H. Motivation in pediatric motor rehabilitation: A systematic search of the literature using the self-determination theory as a conceptual framework. Dev Neurorehabil 2018;21:371– 90. [CrossRef]

Fizik Tedavi ve Rehabilitasyon Uygulamalarında Kullanılabilecek Anlık Denge Kontrolü ve Biyolojik Geri Bildirimi Sağlayan Giyilebilir Sensör Tasarımı

Year 2020, Issue: 3, 412 - 417, 01.09.2020

Abstract

Denge ve performansın iyileştirilmesi için motor bilgilerinin arttırılması yoluyla statik ve dinamik görevlerde motor kontrolünü destekleyen biyolojik geri besleme, rehabilitasyon sırasında hastalara, fizik tedavi ve rehabilitasyon uzman doktorları ile fizyoterapistlere yardımcı olmak için kullanılmaktadır. Postürel kontrol ve denge eksikliği, günlük yaşam aktiviteleri sırasında hastaların mobilizasyonu ve bağımsız performansları üzerinde en büyük etkiye sahiptir. Bir bireyin “statik” dengesi, sabit dururken veya bir seferde tek bir görevi yerine getirirken kabul edilebilir olsa da; “dinamik” denge sorunları, mobilizasyon sırasında veya bir seferde birden fazla görev yaparken ortaya çıkabilir. Bu nedenle, hastanın gerçek zamanlı dinamik dengesinin farkında olmak hem hasta hem de uzman doktor ile fizyoterapist için önemlidir. Bu araştırmada, ortopedik ve nöromusküler hastalıkların fizik tedavi ve rehabilitasyonu sırasında kullanılmak üzere tasarlanan dokunsal ve görsel biyolojik geri bildirim mekanizması geliştirilmiştir

References

  • Alexander RM. Bipedal animals and their differences from humans. J Anat 2004;204:321–30. https://www.ncbi.nlm.nih.gov/pmc/articles/ PMC1571302/
  • Pau M, Ibba PM, Attene G. Fatigue-induced balance impairment in young soccer players. J Athl Train 2014;49:454–61. [CrossRef]
  • Friedrich EVC, Mc Farland DJ, Neuper C, Vaughan TM, Brunner P, Wolpaw JR. A scanning protocol for a sensorimotor rhythm- based brain-computer interface. Biol Psychol 2009;80:169–75. [CrossRef ]
  • Bohnsack Mc Lagan NK, Cusumano JP, Dingwell JB. Adaptability of stride-to-stride control of stepping movements in human walking. J Biomech 2016;49:229–37. [CrossRef]
  • Bourne RB, Chesworth BM, Davis AM, Mahomed NN, Charron KDJ. Patient satisfaction after total knee arthroplasty: who is satisfied and who is not?. Clin Orthop Relat Res 2010;468:57–63. [CrossRef]
  • Christensen JC, La Stayo PC, Marcus RL, Stoddard GJ, Bo Foreman K, Mizner RL, et al. Visual knee-kinetic biofeedback technique normalizes gait abnormalities during high-demand mobility after total knee arthroplasty. Knee 2018;25:73–82. [CrossRef]
  • Kondilopoulos N, Rousanoglou EN, Boudolos KD. Inertial sensing of the motion speed effect on the sit-to-walk activity. Gait Posture 2018;61:111–6. [CrossRef]
  • Jiang GP, Jiao XB, Wu SK, Ji ZQ, Liu WT, Chen X, Wang HH. Balance, Proprioception, and Gross Motor Development of Chinese Children Aged 3 to 6 Years. J Mot Behav 2018;50:343–52. [CrossRef]
  • Collins DF, Refshauge KM, Todd G, Gandevia SC. Cutaneous receptors contribute to kinesthesia at the index finger, elbow, and knee. J Neurophysiol 2005;94:1699–706. [CrossRef]
  • Daffertshofer A, Lamoth CJ, Meijer OG, Beek PJ. Principal components analysis in studying coordination and variability: A tutorial. Clin Biomech 2004;19:415–28. [CrossRef]
  • Guo L, Xiong S. Accuracy of Base of Support Using an Inertial Sensor Based Motion Capture System. Sensors (Basel) 2017;17:2091. [CrossRef]
  • Segers V, Aerts P, Lenoir M, De Clercq D. Spatiotemporal characteristics of the walk-to-run and run-to-walk transition when gradually changing speed. Gait Posture 2006;24:247–54. [CrossRef]
  • Fothergill S. Examining the effect of real-time visual feedback on the quality of rowing technique. Procedia Eng 2010;2:3083–8 [CrossRef]
  • Hiley MJ, Yeadon MR. Optimisation of high bar circling technique for consistent performance of a triple piked somersault dismount. J Biomech 2008;41:1730–5. [CrossRef]
  • Novacheck TF. The biomechanics of running. Gait Posture 1998;7:77– 95. [CrossRef]
  • Barra J, Pérennou D, Thilo KV, Gresty MA, Bronstein AM. The awareness of body orientation modulates the perception of visual vertical. Neuropsychologia 2012;50:2492–8. [CrossRef]
  • Assaiante C, Barlaam F, Cignetti F, Vaugoyeau M. Body schema building during childhood and adolescence: a neurosensory approach. Neurophysiol Clin 2014;44:3–12. [CrossRef]
  • Barrios JA, Crossley KM, Davis IS. Gait retraining to reduce the knee adduction moment through real-time visual feedback of dynamic knee alignment. J Biomech 2010;43:2208–13. [CrossRef]
  • Christiansen CL, Bade MJ, Davidson BS, Dayton MR, Stevens-Lapsley JE. Effects of Weight-bearing biofeedback training on functional movement patterns following total knee arthroplasty: a randomized controlled trial. J Orthop Sports Phys Ther 2015;45:647–55. [CrossRef]
  • Kearney E, Shellikeria S, Martino R, Yunusova Y. Augmented visual feedback-aided interventions for motor rehabilitation in Parkinson’s disease: a systematic review. Disabil Rehabil 2019;41:995–1011. [CrossRef]
  • Pogonchenkova IV, Khan MA, Korchazhkina NB, Novikova EV, Bokova IA, Lyan NA. The application of the physical factors for the medical rehabilitation of the children presenting with neurogenic dysfunction of the bladder. Vopr Kurortol Fizioter Lech Fiz Kult 2017;94:53–8. [CrossRef]
  • Imaizumi S, Asai T, Hiromitsu K, Imamizu H. Voluntarily controlled but not merely observed visual feedback affects postural sway. Peer J 2018;6:e4643. [CrossRef]
  • Semprini M, Laffranchi M, Sanguineti V, Avanzino L, Icco RD, Michieli LD, Chiappalone M. Technological Approaches for Neurorehabilitation: From Robotic Devices to Brain Stimulation and Beyond. Front Neurol 2018;9. [CrossRef]
  • Ribeiro VV, de Oliveira AG, da Silva Vitor J, Ramos AC, Brasolotto AG, Silverio KCA,. Effectiveness of Voice Therapy Associated With Electromyographic Biofeedback in Women With Behavioral Dysphonia: Randomized Placebo-Controlled Double-Blind Clinical Trial. J Voice 2019;33:381.e11–22. [CrossRef]
  • Smits BL, Polman RC, Otten B, Pepping GJ, Hettinga FJ. Cycling in the Absence of Task-Related Feedback: Effects on Pacing and Performance. Front Physiol 2016;10;7:348. [CrossRef]
  • Meyns P, de Mettelinge TR, van der Spank J, Coussens M, Van Waelvelde H. Motivation in pediatric motor rehabilitation: A systematic search of the literature using the self-determination theory as a conceptual framework. Dev Neurorehabil 2018;21:371– 90. [CrossRef]
There are 26 citations in total.

Details

Primary Language Turkish
Journal Section Research Article
Authors

Hande Argunşah Bayram

Begüm Yalçın

Publication Date September 1, 2020
Published in Issue Year 2020Issue: 3

Cite

EndNote Bayram HA, Yalçın B (September 1, 2020) Fizik Tedavi ve Rehabilitasyon Uygulamalarında Kullanılabilecek Anlık Denge Kontrolü ve Biyolojik Geri Bildirimi Sağlayan Giyilebilir Sensör Tasarımı. Acıbadem Üniversitesi Sağlık Bilimleri Dergisi 3 412–417.