[1] COLLABORATORS G B D S. Global, regional, and national burden of stroke, 1990-2016: a systematic analysis for the Global Burden of Disease Study 2016 [J]. Lancet Neurol, 2019, 18(5): 439-58.
[2] WU S, CHENG Y, WU B, et al. Stroke research in 2019: towards optimising treatment and prevention [J]. Lancet Neurol, 2020, 19(1): 2-3.
[3] LESLI, SKOLARUS, WILLIAM, et al. Marked Regional Variation in Acute Stroke Treatment Among Medicare Beneficiaries [J]. Stroke A Journal of Cerebral Circulation, 2015,
[4] STINEAR C M, LANG C E, ZEILER S, et al. Advances and challenges in stroke rehabilitation [J]. Lancet Neurol, 2020,
[5] ORTLIEB A, BOURI M, BAUD R, et al. An assistive lower limb exoskeleton for people with neurological gait disorders [J]. IEEE Int Conf Rehabil Robot, 2017, 2017(441-6.
[6] MCGLINCHEY M P, JAMES J, MCKEVITT C, et al. The effect of rehabilitation interventions on physical function and immobility-related complications in severe stroke: a systematic review [J]. BMJ Open, 2020, 10(2): e033642.
[7] CHEN G, CHAN C K, GUO Z, et al. A review of lower extremity assistive robotic exoskeletons in rehabilitation therapy [J]. Crit Rev Biomed Eng, 2013, 41(4-5): 343-63.
[8] CHEN B, ZHONG C H, ZHAO X, et al. A wearable exoskeleton suit for motion assistance to paralysed patients [J]. J Orthop Translat, 2017, 11(7-18.
[9] SANCHEZ-VILLAMANAN M D C, GONZALEZ-VARGAS J, TORRICELLI D, et al. Compliant lower limb exoskeletons: a comprehensive review on mechanical design principles [J]. J Neuroeng Rehabil, 2019, 16(1): 55.
[10] BORTOLE M, VENKATAKRISHNAN A, ZHU F, et al. The H2 robotic exoskeleton for gait rehabilitation after stroke: early findings from a clinical study [J]. J Neuroeng Rehabil, 2015, 12(54.
[11] WINSTEIN C J, WOLF S L, DROMERICK A W, et al. Effect of a Task-Oriented Rehabilitation Program on Upper Extremity Recovery Following Motor Stroke: The ICARE Randomized Clinical Trial [J]. JAMA, 2016, 315(6): 571-81.
[12] YTTERBERG C, KRISTENSEN H K, TISTAD M, et al. Factors related to met needs for rehabilitation 6 years after stroke [J]. PLoS One, 2020, 15(1): e0227867.
[13] TAKETOMI M, SHIMIZU Y, KADONE H, et al. Hybrid Assistive Limb Intervention in a Patient with Late Neurological Deterioration after Thoracic Myelopathy Surgery due to Ossification of the Ligamentum Flavum [J]. Case Rep Orthop, 2018, 2018(6171760.
[14] LEE S H, LEE H J, CHANG W H, et al. Gait performance and foot pressure distribution during wearable robot-assisted gait in elderly adults [J]. J Neuroeng Rehabil, 2017, 14(1): 123.
[15] SEO K, LEE J, PARK Y J. Autonomous hip exoskeleton saves metabolic cost of walking uphill [J]. IEEE Int Conf Rehabil Robot, 2017, 2017(246-51.
[16] YAN H, YANG C J. Design and validation of a lower limb exoskeleton employing the recumbent cycling modality for post-stroke rehabilitation [J]. P I Mech Eng C-J Mec, 2014, 228(18): 3517-25.
[17] HORTAL E, UBEDA A, IANEZ E, et al. EEG-Based Detection of Starting and Stopping During Gait Cycle [J]. Int J Neural Syst, 2016, 26(7): 1650029.
[18] RODRIGUEZ-UGARTE M, IANEZ E, ORTIZ M, et al. Improving Real-Time Lower Limb Motor Imagery Detection Using tDCS and an Exoskeleton [J]. Front Neurosci, 2018, 12(757.
[19] ANDROWIS G J, PILKAR R, RAMANUJAM A, et al. Electromyography Assessment During Gait in a Robotic Exoskeleton for Acute Stroke [J]. Front Neurol, 2018, 9(630.
[20] RAJASEKARAN V, LOPEZ-LARRAZ E, TRINCADO-ALONSO F, et al. Volition-adaptive control for gait training using wearable exoskeleton: preliminary tests with incomplete spinal cord injury individuals [J]. J Neuroeng Rehabil, 2018, 15(1): 4.
[21] SCHWARTZ I, SAJIN A, FISHER I, et al. The Effectiveness of Locomotor Therapy Using Robotic-Assisted Gait Training in Subacute Stroke Patients: A Randomized Controlled Trial [J]. Pm & R the Journal of Injury Function & Rehabilitation, 2009, 1(6): 516-23.
[22] MOLTENI F, GASPERINI G, GAFFURI M, et al. Wearable robotic exoskeleton for overground gait training in sub-acute and chronic hemiparetic stroke patients: preliminary results [J]. Eur J Phys Rehabil Med, 2017, 53(5): 676-84.
[23] CALABRO R S, NARO A, RUSSO M, et al. Shaping neuroplasticity by using powered exoskeletons in patients with stroke: a randomized clinical trial [J]. J Neuroeng Rehabil, 2018, 15(1): 35.
[24] CHO J E, YOO J S, KIM K E, et al. Systematic Review of Appropriate Robotic Intervention for Gait Function in Subacute Stroke Patients [J]. Biomed Res Int, 2018, 2018(4085298.
[25] JAYARAMAN A, O'BRIEN M K, MADHAVAN S, et al. Stride management assist exoskeleton vs functional gait training in stroke: A randomized trial [J]. Neurology, 2019, 92(3): e263-e73.
[26] FRISOLI A, ROCCHI F, MARCHESCHI S, et al. A new force-feedback arm exoskeleton for haptic interaction in virtual environments; proceedings of the Eurohaptics Conference, 2005 and Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems, 2005 World Haptics 2005 First Joint, F, 2005 [C].
[27] VLUGGEN T, VAN HAASTREGT J C M, TAN F E S, et al. Factors associated with successful home discharge after inpatient rehabilitation in frail older stroke patients [J]. BMC Geriatr, 2020, 20(1): 25.
[28] AFSCHRIFT M, DE GROOTE F, DE SCHUTTER J, et al. The effect of muscle weakness on the capability gap during gross motor function: a simulation study supporting design criteria for exoskeletons of the lower limb [J]. Biomed Eng Online, 2014, 13(111.
[29] OLNEY S J, RICHARDS C. Hemiparetic gait following stroke. Part I: Characteristics [J]. Gait & Posture, 4(2): 0-148.
[30] ZHANG C, ZHU Y, FAN J, et al. Design of a quasi-passive 3 DOFs ankle-foot wearable rehabilitation orthosis [J]. Biomed Mater Eng, 2015, 26 Suppl 1(S647-54.
[31] VACHALOVA I, HECKMAN J G. Differential diagnosis of foot drop: foot drop stroke syndrome [J]. Journal of Surgical Orthopaedic Advances, 2014, 23(2): 122-3.
[32] BONINI-ROCHA A C, DE ANDRADE A L S, MORAES A M, et al. Effectiveness of Circuit-Based Exercises on Gait Speed, Balance, and Functional Mobility in People Affected by Stroke: A Meta-Analysis [J]. PM R, 2018, 10(4): 398-409.
[33] PARK E J, KANG J, SU H, et al. Design and preliminary evaluation of a multi-robotic system with pelvic and hip assistance for pediatric gait rehabilitation [J]. IEEE Int Conf Rehabil Robot, 2017, 2017(332-9.
[34] KOOPMAN B, VAN ASSELDONK E H, VAN DER KOOIJ H. Selective control of gait subtasks in robotic gait training: foot clearance support in stroke survivors with a powered exoskeleton [J]. J Neuroeng Rehabil, 2013, 10(3.
[35] LIN L C, CHUANG H S. Analyzing the locomotory gaitprint of Caenorhabditis elegans on the basis of empirical mode decomposition [J]. PLoS One, 2017, 12(7): e0181469.
[36] COCK A D, WILLEMS T, WITVROUW E, et al. A functional foot type classification with cluster analysis based on plantar pressure distribution during jogging [J]. Gait & Posture, 23(3): 0-347.
[37] HUANG P Y B, DENG LF, ZHU WY, XIA J, HUANG QY. . Gait features and foot plantar pressure distribution of nurse natural walking on flat ground [J]. Zhongguo Zuzhi Gongcheng Yanjiu, 2012, 16(7)): 1259-62.
[38] HU J, HOU Z G, PENG L, et al. sEMG-Based Single-Joint Active Training with iLeg-A Horizontal Exoskeleton for Lower Limb Rehabilitation [J]. Lect Notes Comput Sc, 2014, 8836(535-42.
[39] LERNER Z F, DAMIANO D L, BULEA T C. A lower-extremity exoskeleton improves knee extension in children with crouch gait from cerebral palsy [J]. Sci Transl Med, 2017, 9(404):
[40] WANG W, LI K, YUE S, et al. Associations between lower-limb muscle activation and knee flexion in post-stroke individuals: A study on the stance-to-swing phases of gait [J]. Plos One, 2017, 12(9): e0183865.
[41] MOLTENI F, GASPERINI G, CANNAVIELLO G, et al. Exoskeleton and End-Effector Robots for Upper and Lower Limbs Rehabilitation: Narrative Review [J]. PM R, 2018, 10(9S2): S174-S88.
[42] VISINTIN M. A new approach of retain gait in stroke patients through body weight support and treadmill stimulation [J]. Stroke, 1998, 29(
[43] PATTERSON K K, GAGE W H, BROOKS D, et al. Evaluation of gait symmetry after stroke: A comparison of current methods and recommendations for standardization [J]. 31(2): 0-246.
[44] BRODERICK P, HORGAN F, BLAKE C, et al. Mirror therapy for improving lower limb motor function and mobility after stroke: A systematic review and meta-analysis [J]. Gait & Posture, 2018, 63(
[45] TISSERAND R, ARMAND S, ALLALI G, et al. Cognitive-motor dual-task interference modulates mediolateral dynamic stability during gait in post-stroke individuals [J]. Human Movement Science, 2018, 58(175-84.
[46] DUNNING K, O'DELL M W, KLUDING P, et al. Peroneal Stimulation for Foot Drop After Stroke: A Systematic Review [J]. American Journal of Physical Medicine & Rehabilitation, 2015, 94(8): 649.
[47] NUNZIO A M D, ZUCCHELLA C, SPICCIATO F, et al. Biofeedback rehabilitation of posture and weightbearing distribution in stroke: A center of foot pressure analysis [J]. Functional Neurology, 2014, 29(2): 1-8.
[48] YANG D J, PARK S K, KIM J H, et al. Effect of changes in postural alignment on foot pressure and walking ability of stroke patients [J]. Journal of Physical Therapy Science, 27(9): 2943-5.
[49] YANG S R, HEO S Y, LEE H J. Immediate effects of kinesio taping on fixed postural alignment and foot balance in stroke patients [J]. Journal of Physical Therapy Science, 27(11): 3537-40.
[50] JAKUBOWITZ E, YAO D, WINDHAGEN H, et al. [Treatment Options for Neurogenic Drop Foot: A Systematic Literature Research] [J]. 2017,
[51] BULDT A K, FORGHANY S, LANDORF K B, et al. Foot posture is associated with plantar pressure during gait: A comparison of normal, planus and cavus feet
[J]. Gait & Posture, 62(235-40.
[52] ROY S H, CHENG M S, CHANG S S, et al. A Combined sEMG and Accelerometer System for Monitoring Functional Activity in Stroke [J]. IEEE Transactions on Neural Systems & Rehabilitation Engineering, 2010, 17(6): 585-94.
[53] YOUNG A J, FERRIS D P. State of the Art and Future Directions for Lower Limb Robotic Exoskeletons [J]. IEEE Trans Neural Syst Rehabil Eng, 2017, 25(2): 171-82.
[54] CHEUNG E Y Y, NG T K W, YU K K K, et al. Robot-Assisted Training for People With Spinal Cord Injury: A Meta-Analysis [J]. Arch Phys Med Rehabil, 2017, 98(11): 2320-31 e12.
[55] PUENTES S, KADONE H, KUBOTA S, et al. Reshaping of Gait Coordination by Robotic Intervention in Myelopathy Patients After Surgery [J]. Front Neurosci, 2018, 12(99.
[56] STRAUDI S, BENEDETTI M G, VENTURINI E, et al. Does robot-assisted gait training ameliorate gait abnormalities in multiple sclerosis? A pilot randomized-control trial [J]. NeuroRehabilitation, 2013, 33(4): 555-63.
[57] KANG M G, YUN S J, SHIN H I, et al. Effects of robot-assisted gait training in patients with Parkinson's disease: study protocol for a randomized controlled trial [J]. Trials, 2019, 20(1): 15.
[58] DENG W, PAPAVASILEIOU I, QIAO Z, et al. Advances in Automation Technologies for Lower Extremity Neurorehabilitation: A Review and Future Challenges [J]. IEEE Rev Biomed Eng, 2018, 11(289-305.
[59] CHANG W H, KIM M S, HUH J P, et al. Effects of robot-assisted gait training on cardiopulmonary fitness in subacute stroke patients: a randomized controlled study [J]. Neurorehabil Neural Repair, 2012, 26(4): 318-24.