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Orthoses: A Systematic Review

Yıl 2021, Cilt: 2 Sayı: 2, 135 - 149, 30.12.2021

Öz

The purpose of this review paper was to investigate some of the existing studies in the open literature that have novel innovations in the field of orthotics. There are some methods to regain the functions of injured or damaged limbs. It is worth mentioning that orthoses are of paramount importance among these methods. Orthoses are used as an external device to improve the structure and function of an organ in the body. In addition, orthoses prevent pain and deformity development in the limb. There are different types and applications of orthoses and their usage areas are quite wide. Moreover, orthoses are fabricated from different materials such as metal, leather, plastic or a combination of different materials, prefabricated or individually, according to the desired organ by the technical orthopedic specialist. This paper comprehensively reviews the studies that brought innovations to the orthotics literature. Consequently, this review paper provides researchers a useful reference on orthosis parameters such as modelling, material, geometry, and size optimization for key biomechanics applications.

Kaynakça

  • [1] Fleischer, C., Reinicke, C., & Hommel, G. (2005, August). Predicting the intended motion with EMG signals for an exoskeleton orthosis controller. In 2005 IEEE/RSJ International Conference on Intelligent Robots and Systems (pp. 2029-2034). IEEE.
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  • [4] Lam, W. K., Leong, J. C. Y., Li, Y. H., Hu, Y., & Lu, W. W. (2005). Biomechanical and electromyographic evaluation of ankle foot orthosis and dynamic ankle foot orthosis in spastic cerebral palsy. Gait & posture, 22(3), 189-197.
  • [5] Ates, S., Haarman, C. J., & Stienen, A. H. (2017). SCRIPT passive orthosis: design of interactive hand and wrist exoskeleton for rehabilitation at home after stroke. Autonomous Robots, 41(3), 711-723.
  • [6] Kao, P. C., & Ferris, D. P. (2009). Motor adaptation during dorsiflexion-assisted walking with a powered orthosis. Gait & posture, 29(2), 230-236.
  • [7] Grissom, S. P., & Blanton, S. (2001). Treatment of upper motoneuron plantarflexion contractures by using an adjustable ankle-foot orthosis. Archives of physical medicine and rehabilitation, 82(2), 270-273.
  • [8] Miyazaki, S., Yamamoto, S., & Kubota, T. (1997). Effect of ankle-foot orthosis on active ankle moment in patients with hemiparesis. Medical and Biological Engineering and Computing, 35(4), 381-385.
  • [9] Danino, B., Erel, S., Kfir, M., Khamis, S., Batt, R., Hemo, Y., ... & Hayek, S. (2015). Influence of orthosis on the foot progression angle in children with spastic cerebral palsy. Gait & posture, 42(4), 518-522.
  • [10] Arazpour, M., Bani, M. A., Hutchins, S. W., & Jones, R. K. (2013). The physiological cost index of walking with mechanical and powered gait orthosis in patients with spinal cord injury. Spinal Cord, 51(5), 356-359.
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Yıl 2021, Cilt: 2 Sayı: 2, 135 - 149, 30.12.2021

Öz

Kaynakça

  • [1] Fleischer, C., Reinicke, C., & Hommel, G. (2005, August). Predicting the intended motion with EMG signals for an exoskeleton orthosis controller. In 2005 IEEE/RSJ International Conference on Intelligent Robots and Systems (pp. 2029-2034). IEEE.
  • [2] ALSANCAK, S. (2000). Ortez ve Protez Tarihçesi. Ankara Sağlık Hizmetleri Dergisi, 1(1), 27-33.
  • [3] Burdett, R. G., Borello-France, D., Blatchly, C., & Potter, C. (1988). Gait comparison of subjects with hemiplegia walking unbraced, with ankle-foot orthosis, and with Air-Stirrup® brace. Physical Therapy, 68(8), 1197-1203.
  • [4] Lam, W. K., Leong, J. C. Y., Li, Y. H., Hu, Y., & Lu, W. W. (2005). Biomechanical and electromyographic evaluation of ankle foot orthosis and dynamic ankle foot orthosis in spastic cerebral palsy. Gait & posture, 22(3), 189-197.
  • [5] Ates, S., Haarman, C. J., & Stienen, A. H. (2017). SCRIPT passive orthosis: design of interactive hand and wrist exoskeleton for rehabilitation at home after stroke. Autonomous Robots, 41(3), 711-723.
  • [6] Kao, P. C., & Ferris, D. P. (2009). Motor adaptation during dorsiflexion-assisted walking with a powered orthosis. Gait & posture, 29(2), 230-236.
  • [7] Grissom, S. P., & Blanton, S. (2001). Treatment of upper motoneuron plantarflexion contractures by using an adjustable ankle-foot orthosis. Archives of physical medicine and rehabilitation, 82(2), 270-273.
  • [8] Miyazaki, S., Yamamoto, S., & Kubota, T. (1997). Effect of ankle-foot orthosis on active ankle moment in patients with hemiparesis. Medical and Biological Engineering and Computing, 35(4), 381-385.
  • [9] Danino, B., Erel, S., Kfir, M., Khamis, S., Batt, R., Hemo, Y., ... & Hayek, S. (2015). Influence of orthosis on the foot progression angle in children with spastic cerebral palsy. Gait & posture, 42(4), 518-522.
  • [10] Arazpour, M., Bani, M. A., Hutchins, S. W., & Jones, R. K. (2013). The physiological cost index of walking with mechanical and powered gait orthosis in patients with spinal cord injury. Spinal Cord, 51(5), 356-359.
  • [11] Allemand, Y., Stauffer, Y., Clavel, R., & Brodard, R. (2009, June). Design of a new lower extremity orthosis for overground gait training with the WalkTrainer. In 2009 IEEE International Conference on Rehabilitation Robotics (pp. 550-555). IEEE.
  • [12] Bates, B. T., Osternig, L. R., Mason, B., & James, L. S. (1979). Foot orthotic devices to modify selected aspects of lower extremity mechanics. The American journal of sports medicine, 7(6), 338-342.
  • [13] Chen, B., Zi, B., Zeng, Y., Qin, L., & Liao, W. H. (2018). Ankle-foot orthoses for rehabilitation and reducing metabolic cost of walking: Possibilities and challenges. Mechatronics, 53, 241-250.
  • [14] Meng, Q., Hu, J., & Zhu, Y. (2008). Properties of shape memory polyurethane used as a low-temperature thermoplastic biomedical orthotic material: influence of hard segment content. Journal of Biomaterials Science, Polymer Edition, 19(11), 1437-1454.
  • [15] Zou, D., He, T., Dailey, M., Smith, K. E., Silva, M. J., Sinacore, D. R., ... & Hastings, M. K. (2014). Experimental and computational analysis of composite ankle-foot orthosis. Journal of rehabilitation research and development, 51(10), 1525.
  • [16] Chu, T. M., & Reddy, N. P. (1995). Stress distribution in the ankle-foot orthosis used to correct pathological gait. Journal of rehabilitation research and development, 32, 349-360.
  • [17] Bartonek, Å., Eriksson, M., & Gutierrez-Farewik, E. M. (2007). A new carbon fibre spring orthosis for children with plantarflexor weakness. Gait & posture, 25(4), 652-656.
  • [18] Del Bianco, J., & Fatone, S. (2008). Comparison of silicone and posterior leaf spring ankle-foot orthoses in a subject with Charcot-Marie-Tooth disorder. JPO: Journal of Prosthetics and Orthotics, 20(4), 155-162.
  • [19] Goiriena, A., Retolaza, I., Cenitagoya, A., Martinez, F., Riano, S., & Landaluze, J. (2009, April). Analysis of bowden cable transmission performance for orthosis applications. In 2009 IEEE International Conference on Mechatronics (pp. 1-6). IEEE.
  • [20] Lyons, G. M., Sinkjær, T., Burridge, J. H., & Wilcox, D. J. (2002). A review of portable FES-based neural orthoses for the correction of drop foot. IEEE Transactions on neural systems and rehabilitation engineering, 10(4), 260-279.
  • [21] Alamdari, A., Haghighi, R., & Krovi, V. (2018). Stiffness modulation in an elastic articulated-cable leg-orthosis emulator: Theory and experiment. IEEE Transactions on Robotics, 34(5), 1266-1279.
  • [22] Rietman, J. S., Goudsmit, J., Meulemans, D., Halbertsma, J. P. K., & Geertzen, J. H. B. (2004). An automatic hinge system for leg orthoses. Prosthetics and Orthotics International, 28(1), 64-68.
  • [23] Belforte, G., Gastaldi, L., & Sorli, M. (2001). Pneumatic active gait orthosis. Mechatronics, 11(3), 301-323.
  • [24] Noël, M., Cantin, B., Lambert, S., Gosselin, C. M., & Bouyer, L. J. (2008). An electrohydraulic actuated ankle foot orthosis to generate force fields and to test proprioceptive reflexes during human walking. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 16(4), 390-399.
  • [25] Banala, S. K., Kulpe, A., & Agrawal, S. K. (2007, April). A powered leg orthosis for gait rehabilitation of motor-impaired patients. In Proceedings 2007 IEEE International Conference on Robotics and Automation (pp. 4140-4145). IEEE.
  • [26] Patar, A., Jamlus, N., Makhtar, K., Mahmud, J., & Komeda, T. (2012). Development of dynamic ankle foot orthosis for therapeutic application. Procedia Engineering, 41, 1432-1440.
  • [27] Boehler, A. W., Hollander, K. W., Sugar, T. G., & Shin, D. (2008, May). Design, implementation and test results of a robust control method for a powered ankle foot orthosis (AFO). In 2008 IEEE International Conference on Robotics and Automation (pp. 2025-2030). IEEE.
  • [28] Andrikopoulos, G., Nikolakopoulos, G., & Manesis, S. (2011, June). A survey on applications of pneumatic artificial muscles. In 2011 19th Mediterranean Conference on Control & Automation (MED) (pp. 1439-1446). IEEE.
  • [29] Low, J. H., Ang, M. H., & Yeow, C. H. (2015, August). Customizable soft pneumatic finger actuators for hand orthotic and prosthetic applications. In 2015 IEEE International Conference on Rehabilitation Robotics (ICORR) (pp. 380-385). IEEE.
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  • [72] Telfer, S., Pallari, J., Munguia, J., Dalgarno, K., McGeough, M., & Woodburn, J. (2012). Embracing additive manufacture: implications for foot and ankle orthosis design. BMC musculoskeletal disorders, 13(1), 1-9.
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  • [74] Cha, Y. H., Lee, K. H., Ryu, H. J., Joo, I. W., Seo, A., Kim, D. H., & Kim, S. J. (2017). Ankle-foot orthosis made by 3D printing technique and automated design software. Applied bionics and biomechanics, 2017.
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Toplam 75 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Yapay Zeka
Bölüm Derlemeler
Yazarlar

Hamid Asadi Dereshgi 0000-0002-8500-6625

Hüseyin Dal

Dilan Demir

Necip Furkan Türe

Yayımlanma Tarihi 30 Aralık 2021
Yayımlandığı Sayı Yıl 2021 Cilt: 2 Sayı: 2

Kaynak Göster

APA Asadi Dereshgi, H., Dal, H., Demir, D., Türe, N. F. (2021). Orthoses: A Systematic Review. Journal of Smart Systems Research, 2(2), 135-149.
AMA Asadi Dereshgi H, Dal H, Demir D, Türe NF. Orthoses: A Systematic Review. JoinSSR. Aralık 2021;2(2):135-149.
Chicago Asadi Dereshgi, Hamid, Hüseyin Dal, Dilan Demir, ve Necip Furkan Türe. “Orthoses: A Systematic Review”. Journal of Smart Systems Research 2, sy. 2 (Aralık 2021): 135-49.
EndNote Asadi Dereshgi H, Dal H, Demir D, Türe NF (01 Aralık 2021) Orthoses: A Systematic Review. Journal of Smart Systems Research 2 2 135–149.
IEEE H. Asadi Dereshgi, H. Dal, D. Demir, ve N. F. Türe, “Orthoses: A Systematic Review”, JoinSSR, c. 2, sy. 2, ss. 135–149, 2021.
ISNAD Asadi Dereshgi, Hamid vd. “Orthoses: A Systematic Review”. Journal of Smart Systems Research 2/2 (Aralık 2021), 135-149.
JAMA Asadi Dereshgi H, Dal H, Demir D, Türe NF. Orthoses: A Systematic Review. JoinSSR. 2021;2:135–149.
MLA Asadi Dereshgi, Hamid vd. “Orthoses: A Systematic Review”. Journal of Smart Systems Research, c. 2, sy. 2, 2021, ss. 135-49.
Vancouver Asadi Dereshgi H, Dal H, Demir D, Türe NF. Orthoses: A Systematic Review. JoinSSR. 2021;2(2):135-49.