A Review Study for Robotic Exoskeletons Rehabilitation Devices

Authors

  • Rrafal Alrawi Prosthetics and Orthotics Engineering Department, College of Engineering , Al-Nahrain University, Baghdad, Iraq .
  • Wajdi Sadik Aboud Prosthetics and Orthotics Engineering Department, College of Engineering, Al-Nahrain University, Baghdad, Iraq.
  • Sallehuddin Mohamed Haris INDICES Research Group, Department of Mechanical & Manufacturing Engineering, Faculty of Engineering & the Built Environment, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia.

Keywords:

Lower Limb, Exoskeletons, Gait, Rehabilitation, Passive and Active

Abstract

Nowadays, robotic exoskeletons demonstrated great abilities to replace traditional rehabilitation processes for activating neural abilities performed by physiotherapists. The main aim of this review study is to determine a state-of-the-art robotic exoskeleton that can be used for the rehabilitation of the lower limb of people who have mobile disabilities as a result of stroke and musculoskeletal conditions. The study presented the anatomy of the lower limb and the biomechanics of human gait to explain the mechanism of the limb, which helps in constructing a robotic exoskeleton. A state-of-the-art review of more than 100 articles related to robotic exoskeletons and their constructions, functionality, and rehabilitation capabilities are accurately implemented. Moreover, the study included a review of upper limb rehabilitation that has been studied locally and successfully applied to patients who exhibited significant improvements. Results of recent studies herald an abundant future for robotic exoskeletons used in the rehabilitation of the lower extremity. Significant improvement in the mechanism and design, as well as the quality, were observed. Also, impressive results were obtained from the performance when used by patients. This study concludes that working and improving the robotic devices continuously in accordance with the cases are necessary to be treated with the best results and the lowest cost.

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References

Kazerooni, H.; Steger, R.; Huang, L. Hybrid control of the Berkeley Lower Extremity Exoskeleton (BLEEX). Int. J. Robot. Res. 2006, 25, 561–573.

Ranaweera, R.K.P.S.; Gopura, R.A.R.C.; Jayawardena, T.S.S.; Mann, G.K.I. Development of A Passively Powered Knee Exoskeleton for Squat Lifting. J. Robot. Netw. Artif. Life 2018, 5, 45.

Li, N.; Yang, J.; Feng, X.; Zhang, J.; Yang, X.; Zhang, Z. A summary of 30 years’ research on risk factors of stroke mortality in China. Chin. J. Behav. Med. Brain Sci. 2017, 26, 765–768.

Anderson MK, Hall SJ, Martin M: Sports Injury Management, 2nd ed. Baltimore, Lippincott Williams & Wilkins, 2000.

Birrer RB (ed): Sports Medicine for the Primary Care Physician, 2nd ed. Boca Raton, FL, CRC Press, 1994.

Clay JH, Pounds DM: Basic Clinical Message Therapy: Integrating Anatomy and Treatment. Baltimore, Lippincott Williams & Wilkins, 2003.

R. L. (Richard L. Drake, W. Vogl, A. W. M. Mitchell, and H. Gray, Gray?s anatomy for students. 2020.

K. Shaffer, “Clinical Anatomy by Systems by Richard S. Snell,” Clin. Anat., vol. 20, no. 2, pp. 223–224, Mar. 2007, doi: 10.1002/ca.20419

B. Chen et al., “A wearable exoskeleton suit for motion assistance to paralysed patients,” J. Orthop. Transl., vol. 11, pp. 7–18, 2017, doi: 10.1016/j.jot.2017.02.007.

Al-Maliky F.T., Chiad J.S. “Study and evaluation of four bar polycentric knee used in the prosthetic limb for transfemoral amputee during the gait cycle” Materials Today: Proceedings, 2021, 42, pp. 2706–2712

R. Stopforth, “Customizable rehabilitation lower limb exoskeleton system,” Int. J. Adv. Robot. Syst., vol. 9, pp. 1–7, 2012, doi: 10.5772/53087

Whitesides, T.E. Orthopaedic Basic Science: Biology and Biomechanics of the Musculoskeletal System, 2nd ed.; American Academy of Orthopaedic Surgeons: Rosemont, IL, USA, 2001; Volume 83, p. 481.

Norkus SA, Floyd RT. The anatomy and mechanisms of syndesmotic ankle sprains. J Athl Train 2001 Jan; 36: 68e73.

E. J. C. Dawe and J. Davis, “(vi) Anatomy and biomechanics of the foot and ankle,” Orthopaedics and Trauma, vol. 25, no. 4, pp. 279–286, Aug. 2011, doi: 10.1016/j.mporth.2011.02.004.

Y. Vereshchaga and W. Baumgartner, “Knowledge Acquisition from a Biomechanical System: Human Gait Transition as an Example,” Br. Biomed. Bull., vol. 06, no. 02, 2018, doi: 10.21767/2347-5447.1000313.

F. M. Kadhim, J. S. Chiad, and A. M. Takhakh, “Design and Manufacturing Knee Joint for Smart Transfemoral Prosthetic,” IOP Conf. Ser. Mater. Sci. Eng., vol. 454, no. 1, 2018, doi: 10.1088/1757-899X/454/1/012078

F. M. Kadhim, A. M. Takhakh, and J. S. Chiad, “Modeling and evaluation of smart economic transfemral prosthetic,” Defect Diffus. Forum, vol. 398 DDF, no. January, pp. 48–53, 2020, doi: 10.4028/www.scientific.net/DDF.398.48.

T. J. Luli?, A. Suši?, and J. Kodvanj, “Biomechanical analysis of walking: Effects of gait velocity and arm swing amplitude,” Period. Biol., vol. 112, no. 1, pp. 13–17, 2010.

S. N. L. A., I. I. S. Md, and J. C. Tan, “Torque Analysis of the Lower Limb Exoskeleton Robot Design,” ARPN J. Eng. Appl. Sci., vol. 10, no. 19, pp. 9140–9149, 2015.

Y. Han and X. Wang, “The biomechanical study of lower limb during human walking,” Sci. China Technol. Sci., vol. 54, no. 4, pp. 983–991, 2011, doi: 10.1007/s11431-011-4318-z.

A. D. Kuo, “The six determinants of gait and the inverted pendulum analogy: A dynamic walking perspective,” Hum. Mov. Sci., vol. 26, no. 4, pp. 617–656, 2007, doi: 10.1016/j.humov.2007.04.003.

R. Bartlett, Introduction to Sports Biomechanics Analysing Human Movement Patterns, 2nd ed., vol. 50 Suppl 1. 2007.

Y. A. Shafeeq, J. S. Chiad, and Y. Y. Kahtan, “Study, Analysis, The Vibration and Stability for the Artificial Hand During its Daily Working,” International Journal of Mechanical Engineering and Technology (IJMET), 2018, 9(13), PP 1706-1716.

Y. Yin, Biomechanical Principles on Force Generation and Control of Skeletal Muscle and their Applications in Robotic Exoskeleton. CRC Press Taylor & Francis Group, 2020.

M. Whittle, Gait analysis : an introduction. Butterworth-Heinemann, 2007.

S. K. Banala, S. H. Kim, S. K. Agrawal, and J. P. Scholz, “Robot Assisted Gait Training With Active Leg Exoskeleton (ALEX),” IEEE Transactions on Neural Systems and Rehabilitation Engineering, vol. 17, no. 1, pp. 2–8, Feb. 2009, doi: 10.1109/TNSRE.2008.2008280.

D. S. Pamungkas, W. Caesarendra, S. Susanto, H. Soebakti, and R. Analia, “Overview: Types of lower limb exoskeletons,” Electron., vol. 8, no. 11, pp. 1–12, 2019, doi: 10.3390/electronics8111283

J. A. Saglia, N. G. Tsagarakis, J. s, Dai, and D. G. Caldwell, “Control Strategies for Ankle Rehabilitation using a High-Performance Ankle Exerciser,” 2010, doi: 978-1-4244-5040-4/10/

Gait | Joint Structure and Function: A Comprehensive Analysis, 5e | F.A. Davis PTCollection|McGrawHillMedical.Availableonline:https://fadavispt.mhmedical.com/content.aspx?bookid=1862&sectionid=136086727 (accessed on 16 September 2019).

C. L. Vaughan, B. L. Davis, and J. C. O?connor, “2nd Edition 2nd Edition DYNAMICS OF HUMAN GAIT DYNAMICS OF HUMAN GAIT,” 1999.

Kim, Y. and Cook, A., Manipulation and Mobility Aids, Electronic Devices for Rehabilitation, Webster et al, Eds. London, U.K.: Chapman and Hall, 1985.

M. D. C. Sanchez-Villamañan, J. Gonzalez-Vargas, D. Torricelli, J. C. Moreno, and J. L. Pons, “Compliant lower limb exoskeletons: A comprehensive review on mechanical design principles,” J. Neuroeng. Rehabil., vol. 16, no. 1, pp. 1–16, 2019, doi: 10.1186/s12984-019-0517-9.

G. Onose et al., “Mechatronic wearable exoskeletons for bionic bipedal standing and walking: A new synthetic approach,” Front. Neurosci., vol. 10, no. SEP, pp. 1–9, 2016, doi: 10.3389/fnins.2016.00343.

G. M. Cestari, D. Sanz-Merodio, F.C. Arevalo, E, “ARES, a variable stiffness actuator with embedded force sensor for the ATLAS exoskeleton.” Industrial Robot: An International Journal, pp. 518–526, 2014.

K. Kong and D. Jeon, “Design and control of an exoskeleton for the elderly and patients,” IEEE/ASME Trans. Mechatronics, vol. 11, no. 4, pp. 428–432, 2006, doi: 10.1109/TMECH.2006.878550.

Y. Hong et al., “Lower extremity exoskeleton: review and challenges surrounding the technology and its role in rehabilitation of lower limbs,” Aust. J. Basic Appl. Sci., vol. 7, no. 7, pp. 520–524, 2013.

Malcolm, P.; Derave, W.; Galle, S.; de Clercq, D. A Simple Exoskeleton That Assists Plantarflexion Can Reduce the Metabolic Cost of Human Walking. PLoS ONE 2013, 8, e56137.

.-C. K. Lin, M.-S. Ju, S.-M. Chen, and B.-W. Pan, “A Specialized Robot for Ankle Rehabilitation and Evaluation Transcranial Direct Current Stimulation on Spatial Working Memory View project Development of Haptic Feedback System for Surgical Robots in Laparoscopic Surgery View project A Specialized Robot for Ankle Rehabilitation and Evaluation,” 2008.

Banchadit, W.; Temram, A.; Sukwan, T.; Owatchaiyapong, P.; Suthakorn, J. Design and implementation of a new motorized-mechanical exoskeleton based on CGA Patternized Control. In Proceedings of the 2012 IEEE International Conference on Robotics and Biomimetics, ROBIO 2012—Conference Digest, Guangzhou, China, 11–14 December 2012; pp. 1668–1673.

Krebs, H., Volpe, B., Aisen, M. and Hogan, N., Increasing productivity and quality of care: Robot-aided neuro-rehabilitation, J. Rehab. Res. Devel., vol. 37, no. 6, pp. 639–652, 2000.

Kiguchi, K. and Fukuda, T., A 3DOF exoskeleton for upper-limb motion assist: consideration of the effect of bi-articular muscles, Proc. IEEE Int. Conf. Robotics Automation, N. Orl., FLA, pp. 2424–2429, 2004.

Loaiza, J., Arzola, N., Evolution and trends in the development of hand prosthesis, DYNA, 169, pp. 191-200, 2011.

Drouin, J., Valovich-Mcleod, T., Shultz, S., Gansneder, B. and Perrin, D., Reliability and validity of the Biodex system 3 pro isokinetic dynamometer velocity, torque and position measurements, Eur. J. Appl. Physiol. 91, pp. 22-29, 2004.

Brochure Biodex Catalog 50 Summer 2011. Available: http://www.biodex.com/physmedcatalog/unpriced [cited 9th Feb. 2012].

Lünenburger, L., Colombo, G., Riener, R., Biofeedback for robotics gait rehabilitation, J. of NeuroEngineering and Rehabilitation, 2007

Lokomat® - Enhanced Functional Locomotion Therapy. Available: http://www.hocoma.com/en/products/lokomat/

Al-Maliky F.T., Chiad J.S. “Study and evaluation of four bar polycentric knee used in the prosthetic limb for transfemoral amputee during the gait cycle” Materials Today: Proceedings, 2021, 42, pp. 2706–2712

Monaco, V.; Galardi, G.; Coscia, M.; Martelli, D.; Micera, S. Design and evaluation of NEUROBike: A neuro-rehabilitative platform for bedridden post-strike patients. IEEE Trans. Neural Syst. Rehabil. Eng. 2012, vol 20, numb6, 845–852.

Kolominsky-Rabas PL, Heuschmann PU: Incidence, etiology and longterm prognosis of stroke. Fortschr Neurol Psychiatr 2002, 70:657-62.

Jorgensen HS, Nakayama H, Raaschou HO, Olsen TS: Recovery of walking function in stroke patients: the Copenhagen stroke study. Arch Phys Med Rehabil 1995, 76:27-32.

Carr J, Shepherd R: Stroke Rehabilitation: Guidelines for exercises and training. London: Butterworth Heinemann; 2003.

Barbeau H, Visintin M: Optimal outcomes obtained with body-weight support combined with treadmill training in stroke subjects. Arch Phys Med Rehabil 2003, 84(10):1458-65.

Dobkin BH, Apple D, Barbeau H, Basso M, Behrman A, Deforge D, Ditunno J, Dudley G, Elashoff R, Fugate L, Harkema S, Saulino M, Scott M: Methods for a randomized trial of weight-supported treadmill training versus conventional training for walking during inpatient rehabilitation after incomplete traumatic spinal cord injury. Neurorehabil Neural Repair 2003, 17(3):153-67.

C Wang, Fang Y, Guo S. Multi-objective optimization of a parallel ankle rehabilitation robot using modifed diferential evolution algorithm. Chin J Mech Eng. 2015;28(4):702–15.

K. E. Gordon, G. S. Sawicki, and D. P. Ferris, “Mechanical performance of artificial pneumatic muscles to power an ankle–foot orthosis,” J. Biomech., vol. 39, no. 10, pp. 1832–1841, 2006.

J. A. Norris, K. P. Granata, M. R. Mitros, E. M. Byrne, and A. P. Marsh, “Effect of augmented plantarflexion power on preferred walking speed and economy in young and older adults,” Gait Posture, vol. 25, no. 4, pp. 620–627, Apr. 2007.

E. H. F. Van Asseldonk, R. Ekkelenkamp, J. F. Veneman, F. C. T. Van der Helm, and H. van der Kooij, “Selective control of a subtask of walking in a robotic gait trainer(LOPES),” in Proc. IEEE 10th Int. Conf. Rehabil. Robot., Jun. 2007, pp. 841–848.

M. Hassan, H. Kadone, K. Suzuki, and Y. Sankai, “Wearable gait measurement system with an instrumented cane for exoskeleton control,” Sensors, vol. 14, no. 1, pp. 1705–1722, Jan. 2014.

O. Mazumder, A. S. Kundu, P. K. Lenka, and S. Bhaumik, “Ambulatory activity classification with dendogram-based support vector machine: Application in lower-limb active exoskeleton,” Gait Posture, vol. 50, pp. 53–59, Oct. 2016.

J. Ochoa, D. Sternad, and N. Hogan, “Treadmill vs. Overground walking: Different response to physical interaction,” J. Neurophysiol., vol. 118, no. 4, pp. 2089–2102, Oct. 2017.

T. Yan, A. Parri, V. Ruiz Garate, M. Cempini, R. Ronsse, and N. Vitiello, “An oscillator-based smooth real-time estimate of gait phase for wearable robotics,” Auto. Robots, vol. 41, no. 3, pp. 759–774, Mar. 2017.

L. N. Awad et al., “A soft robotic exosuit improves walking in patients after stroke,” Sci. Transl. Med., vol. 9, no. 400, Jul. 2017, Art. no. eaai9084.

A. Esquenazi, S. Lee, A. Wikoff, A. Packel, T. Toczylowski, and J. Feeley, “A comparison of locomotor therapy interventions: Partialbodyweight–supported treadmill, Lokomat, and G-EO training inpeople with traumatic brain injury,” PM&R, vol. 9, no. 9, pp. 839–846, Sep. 2017.

G. S. Sawicki, A. Domingo, and D. P. Ferris, “The effects of powered ankle-foot orthoses on joint kinematics and muscle activation during walking in individuals with incomplete spinal cord injury,” J. Neuroeng. Rehabil., vol. 3, no. 1, p. 3, 2006.

O. Jansen et al., “Hybrid Assistive Limb exoskeleton HAL in the rehabilitation of chronic spinal cord injury: Proof of concept; the results in 21 patients,” World Neurosurg., vol. 110, pp. e73–e78, Feb. 2018.

Jazernik, S.; Colombo, G.; Morari, M. Automatic gait pattern adaptation algorithms for rehabilitation with a 4-DOF robotic orthosis. IEEE Transact. Robot. Autom. 2004, 20, 574–582.

Y. Hong et al., “Lower extremity exoskeleton: review and challenges surrounding the technology and its role in rehabilitation of lower limbs,” Aust. J. Basic Appl. Sci., vol. 7, no. 7, pp. 520–524, 2013.

Lenzi, T.; Carrozza, M.C.; Agrawal, S.K. Powered hip exoskeletons can reduce the user’s hip and ankle muscle activations during walking. IEEE Trans. Neural Syst. Rehabil. Eng. 2013, 21, 938–948.

Walking Assist Device with Stride Management System | Research paper site of Honda R&D Co., Ltd. Available online: https://www.hondarandd.jp/point.php?pid=122&lang=en (accessed on 5 September 2019).

Giovacchini, F.; Vannetti, F.; Fantozzi, M.; Cempini, M.; Cortese, M.; Parri, A.; Vitiello, N. A light-weight active orthosis for hip movement assistance. Robot. Auton. Syst. 2015, 73, 123–134.

Baud, R.; Ortlieb, A.; Olivier, J.; Bouri, M.; Bleuler, H. HIBSO hip exoskeleton: Toward a wearable and autonomous design. Mech. Mach. Sci. 2018, 48, 185–195.

Asbeck, A.T.; Schmidt, K.;Walsh, C.J. Soft exosuit for hip assistance. Robot. Auton. Syst. 2015, 73, 102–110]

Miyoshi, T.; Hiramatsu, K.; Yamamoto, S.I.; Nakazawa, K.; Akai, M. Robotic gait trainer in water: Development of an underwater gait-training orthosis. Disabil. Rehabil. 2008, 30, 81–87.

Nascimento, B.G.; Vimieiro, C.B.; Nagem, D.A.; Pinotti, M. Hip orthosis powered by pneumatic artificial muscle: Voluntary activation in absence of myoelectrical signal. Artif. Organs 2008, 32,317–322.

Vimieiro, C.B.S.; do Nascimento, B.G.; Nagem, D.A.P.; Pinotti, M. Development of a hip orthosis using pneumatic artificial muscles. In Proceeding of TMSi, São Paulo, Spain, 18–19 July 2005.

Kawamura, T.; Takanaka, K. Development of an orthosis for walking assistance using pneumatic artificial muscle-a quantitative assessment of the effect of assistance. In Proceedings of the International Conference on Rehabilitation Robotics, Seattle, WA, USA, 24–26 June 2013.

P. K. Jamwal, S. Xie, and K. C. Aw, “Kinematic design optimization of a parallel ankle rehabilitation robot using modified genetic algorithm,” Robot. Autom. Syst., vol. 57, pp. 1018–1027, 2009.

Deaconescu, T.T.; Deaconescu, A.I. Pneumatic muscle actuated equipment for continuous passive motion. IAENG Trans. Eng. Technol. 2009, doi:10.1063/1.3256258.

Sawicki, G.S.; Fessis, D.P. A pneumatically powered knee-ankle-foot orthosis (KAFO) with myoelectric activation and inhibition. J. Neuro-Eng. Rehabil. 2009, 6, 23:1–23:16.

Sridar, S.; Nguyen, P.H.; Zhu, M.; Lam, Q.P.; Polygerinos, P. Development of a soft-inflatable exosuit for knee rehabilitation. In Proceedings of the IEEE International Conference on Intelligent Robots and Systems, Vancouver, AB, Canada, 24–28 September 2017; pp. 3722–3727.

Witte, K.A.; Fatschel, A.M.; Collins, S.H. Design of a lightweight, tethered, torque-controlled knee exoskeleton. In Proceedings of the IEEE International Conference on Rehabilitation Robotics, London, UK, 17–20 July 2017; pp. 1646–1653.

Wang, J.; Li, X.; Huang, T.H.; Yu, S.; Li, Y.; Chen, T.; Su, H. Comfort-Centered Design of a Lightweight and Backdrivable Knee Exoskeleton. IEEE Robot. Autom. Lett. 2018, 3, 4265–4272.

Yu, S.; Huang, T.H.; Wang, D.; Lynn, B.; Sayd, D.; Silivanov, V.; Su, H. Design and Control of a Quasi-Direct Drive Soft Hybrid Knee Exoskeleton for Injury Prevention during Squatting. arXiv 2019, arXiv:1902.07106.

Sawicki, G.S.; Fessis, D.P. A pneumatically powered knee-ankle-foot orthosis (KAFO) with myoelectric activation and inhibition. J. Neuro-Eng. Rehabil. 2009, 6, 23:1–23:16.

A. Roy, H. I. Krebs, D. J. Williams, C. T. Bever, L. W. Forrester, R. M. Macko, et al., "Robot-aided neurorehabilitation: A novel robot for ankle rehabilitation," IEEE Transactions on Robotics, vol. 25, pp. 569-582, 2009.

K. E. Gordon, G. S. Sawicki, and D. P. Ferris, "Mechanical performance of artificial pneumatic muscles to power an ankle-foot orthosis," Journal of Biomechanics, vol. 39, pp. 1832-1841, Jul. 2006.

J. R. Koller, D. A. Jacobs, D. P. Ferris, and C. D. Remy, "Learning to walk with an adaptive gain proportional myoelectric controller for a robotic ankle exoskeleton," Journal of NeuroEngineering and Rehabilitation, vol. 12, 2015.

J. A. Blaya and H. Herr, "Adaptive Control of a Variable-Impedance Ankle-Foot Orthosis to Assist Drop-Foot Gait," IEEE Transactions on Neural Systems and Rehabilitation Engineering, vol. 12, pp. 24-31, 2004

K. P. Michmizos, S. Rossi, E. Castelli, P. Cappa, and H. I. Krebs, "Robot-Aided Neurorehabilitation: A Pediatric Robot for Ankle Rehabilitation," IEEE Transactions on Neural Systems and Rehabilitation Engineering, vol. 23, pp. 1056-1067, 2015.

A. Erdogan, B. Celebi, A. C. Satici, and V. Patoglu, "AssistOn-Ankle: a reconfigurable ankle exoskeleton with series-elastic actuation," Autonomous Robots, pp. 1-16, 2016.

M. Noël, B. Cantin, S. Lambert, C. M. Gosselin, and L. J. Bouyer, "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, vol. 16, pp. 390-399, 2008.

S. Hussain, P. K. Jamwal, and M. H. Ghayesh, "Single Joint Robotic Orthoses for Gait Rehabilitation: An Educational Technical Review," Journal of Rehabilitation Medicine vol. 48, pp. 333-338, 2016.

K. A. Shorter, G. F. Kogler, E. Loth, W. K. Durfee, and E. T. Hsiao-Wecksler, "A portable powered ankle-foot orthosis for rehabilitation," Journal of Rehabilitation Research and Development, vol. 48, pp. 459-472, 2011

M. Girone, G. Burdea, and M. Bouzit, ““Rutgers Ankle” orthopedic rehabilitation interface,” Proceedings of the Asme Dynamic Systems and Control Division, vol. 67, pp. 305–312, 1999.

J.Yoon and J. Ryu , A new family of 4-DOF parallel mechanisms (1T-3R and 2T-2R) with two platforms and its application to a footpad device. In:ASME 2004 international design engineering technical conferences and computers and information in engineering conference, Vol 2: 28th Biennial Mechanisms and Robotics Conference, Parts A and B. 2004, p. 257-65.

Dai JS, Zhao T, Nester C. Sprained ankle physiotherapy-based mechanism synthesis and stifness analysis of a robotic rehabilitation device. Autonom Robots. 2004;16(2):207–18

Liu G, Gao J, Yue H, et al. Design and kinematics analysis of parallel robots for ankle rehabilitation. IEEE/RSJ international conference on intelligent robots & systems. IEEE, 2006;253–8

Saglia J A, Tsagarakis N G, Dai J S, A high performance 2-dof overactuated parallel mechanism for ankle rehabilitation. 2009 IEEE international conference on robotics and automation. IEEE, 2009;2180-2186

Saglia JA, Tsagarakis NG, Dai JS, Inverse-kinematics-based control of a redundantly actuated platform for rehabilitation. Proc Instit Mech Eng. 2009;223(1):53–70.

Saglia J A, Tsagarakis N G, Dai J S, . Control strategies for ankle rehabilitation using a high-performance ankle exerciser. 2010 IEEE international conference on robotics and automation (ICRA). IEEE, 2010;2221–7.

Saglia JA, Tsagarakis NG, Dai JS, . A high-performance redundantly actuated parallel mechanism for ankle rehabilitation. Int J Robot Res. 2009;28(9):1216–27.

Hamid R, Mozafar S, Alireza R, . Path planning of the hybrid parallel robot for ankle rehabilitation. Robotica. 2016; 34:173–84.

Rastegarpanah A, Rakhodaei H, Saadat M, . Path-planning of a hybrid parallel robot using stifness and workspace for foot rehabilitation. Adv Mech Eng. 2018; 10:1–10.

. Ai Q, Zhu C, Zuo J, et al. Disturbance-estimated adaptive backstepping sliding mode control of a pneumatic muscles-driven ankle rehabilitation robot. Sensors. 2018;18(1):66

Ayas MS, Altas IH, Sahin E. Fractional order-based trajectory tracking control of an ankle rehabilitation robot. Trans Instit Measur Control. 2016;40(2):550–64

Tsoi Y H, Xie S Q. Design and control of a parallel robot for ankle rehabiltation. In: 15th international conference on mechatronics and machine vision in practice. 2008, p. 515-520.

Jamwal PK, Xie SQ, Tsoi YH, . Forward kinematics modelling of a parallel ankle rehabilitation robot using modifed fuzzy inference. Mech Mach Theory. 2010;45(11):1537–54.

Wang C, Fang Y, Guo S, Chen Y. Design and kinematical performance analysis of a 3 ? RUS/RRR redundantly actuated parallel mechanism for ankle rehabilitation. J Mech Robot. 2013;5(4):041003-041003-11.

Wang C, Fang Y, Guo S. Multi-objective optimization of a parallel ankle rehabilitation robot using modifed diferential evolution algorithm. Chin J Mech Eng. 2015;28(4):702–15.

Wang C, Fang Y, Guo S, . Design and kinematic analysis of redundantly actuated parallel mechanisms for ankle rehabilitation. Robotica. 2015;33(02):366–84.

Cazalilla J, Vallés M, Mata V, . Adaptive control of a 3-DOF parallel manipulator considering payload handling and relevant parameter models. Robot Comput Integr Manufact. 2014, p. 468–77

Vallés Marina, Cazalilla José, Valera Ángel, . A 3-PRS parallel manipulator for ankle rehabilitation: towards a low-cost robotic rehabilitation. Robotica. 2017;35:1939–57.

Zhang L, Li J, Dong M, . Design and workspace analysis of a parallel ankle rehabilitation robot (PARR). J Healthc Eng. 2019;4:1–10

Dong M, Kong Y, Li J, . Kinematic calibration of a parallel 2-UPS/ RRR ankle rehabilitation robot. Journal of Healthcare Engineering, 2020, 3053629.

M. K. A. bin Ismail, M. N. Shah, and W. A. Mustafa, “Fabrication of Parallel Ankle Rehabilitation Robot,” in Lecture Notes in Mechanical Engineering, 2021, pp. 623–637. doi: 10.1007/978-981-16-0866-7_53.

Zou, Y., Zhang, A., Zhang, Q., Zhang, B., Wu, X., & Qin, T. (2022). Design and Experimental Research of 3-RRS Parallel Ankle Rehabilitation Robot. Micromachines, 13(6).

Park, Y.L.; Chen, B.R.; Young, D.; Stirling, L.;Wood, R.J.; Goldfield, E.; Nagpal, R. Bio-inspired active soft orthotic device for ankle foot pathologies. In Proceedings of the 2011 IEEE/RSJ International Conference on Intelligent Robots and Systems, Francisco, CA, USA, 25–30 September 2011; pp. 4488–4495.

C.-C. K. Lin, M.-S. Ju, S.-M. Chen, and B.-W. Pan, “A Specialized Robot for Ankle Rehabilitation and Evaluation Transcranial Direct Current Stimulation on Spatial Working Memory View Project Development of Haptic Feedback System for Surgical Robots in Laparoscopic Surgery View project A Specialized Robot for Ankle Rehabilitation and Evaluation,” 2008.

Ranaweera, R.K.P.S.; Gopura, R.A.R.C.; Jayawardena, T.S.S.; Mann, G.K.I. Development of A Passively Powered Knee Exoskeleton for Squat Lifting. J. Robot. Netw. Artif. Life 2018, 5, 45.

Morris, M. A Review of Rehabilitation Strategies for Stroke Recovery. ASME Early Career Tech. Conf. 2015, 11, 24–31.

U. Keller, Schölch, S.; Albisser, U.; Rudhe, C.; Curt, A.; Riener, R.; Klamroth-Marganska, V. Robot-assisted arm assessments in spinal cord injured patients: A consideration of concept study. PLoS ONE 2015, 10, e0126948

Reinkensmeyer, D.J.; Kahn, L.E.; Averbuch, M.; McKenna-Cole, A.; Schmit, B.D.; Zev Rymer, W. Understanding and treating arm movement impairment after chronic brain injury: Progress with the ARM guide. J. Rehabil. Res. Dev. 2000, 37, 653–662.

Gassert, R.; Dietz, V. Rehabilitation robots for the treatment of sensorimotor deficits: A neurophysiological perspective. J. Neuroeng. Rehabil. 2018, 15, 1–15.

N. Sabri, and W. S. Aboud, "Smart robotic exoskeleton: A 3-dof for wrist-forearm rehabilitation." Journal of Robotics and Control (JRC) 2, no. 6 (2021): 476-483.

N. Sabri, and W. S. Aboud "Designing and Construction a Low-Cost Robotic Exoskeleton for Wrist Rehabilitation" Journal of Mechanical Engineering Research and Developments, Vol. 43, No. 4, pp. 180-192

N. Sabri, and W. S. Aboud " Robotic Exoskeleton: A Compact, Portable, and Constructing Using 3D Printer Technique for Wrist-Forearm Rehabilitation” Al-Nahrain Journal for Engineering Sciences NJES 23(3)238-248,2020,http://doi.org/10.29194/NJES.23030238

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Published

08-07-2023

How to Cite

[1]
R. Alrawi, W. Sadik Aboud, and S. Mohamed Haris, “A Review Study for Robotic Exoskeletons Rehabilitation Devices ”, NJES, vol. 26, no. 2, pp. 63–73, Jul. 2023, Accessed: Nov. 23, 2024. [Online]. Available: https://nahje.com/index.php/main/article/view/1024

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