PDF(452 KB)
Evaluation of recovery effect of finger motor dysfunction in patients with stroke after treated with force feedback perceptual rehabilitation training
Yawen LIAN,Yinghua LI,Guoxing XU,Xixi XIE,Zhenlan LI
PDF(452 KB)
PDF(452 KB)
Evaluation of recovery effect of finger motor dysfunction in patients with stroke after treated with force feedback perceptual rehabilitation training
)Objective To discuss the effect of the force feedback perceptual rehabilitation training on finger motor function of the patients with finger motor dysfunction after stroke, and to provide the basis for the clinical application and promotion of the force feedback perceptual rehabilitation training. Methods A total of 86 patients with hand dysfunction after stroke were randomly divided into experimental group (n=43) and control group (n=43),and 3 cases in each group fell off from the experiment, and 80 cases were ultimately completed. On this basis, the patients in two groups received the conventional rehabilitation training for 40 min. The patients in control group received the conventional hand function training for 20 min, while the patients in experimental group received the force feedback perception rehabilitation training for 20 min, once per day, 5 days per week, for a total of 6 weeks. The hand function recovery of the patients were evaluated before and after treatment by Action Research Arm Test (ARAT),grip strength, modified Ashworth scale (MAS), total active motion (TAM), Fugl-Meyer motor function assessment-upper limb (FMA-UL) finger motor part score,and Barthel index (BI). Results Before treatment, there were no statistically significant differences in ARAT total score, grip strength, MAS grade, TAM, FMA-UL finger motor part score, and BI score of the patients between two groups (P>0.05). After treated for 6 weeks, the ARAT scores, grip strengths, TAM, FMA-UL finger motor part scores, and BI scores of the patients in two groups were all increased than those before treatment (P<0.05), while the MAS grades of the patients had no significant differences (P>0.05). After treated for 6 weeks, compared with control group,the grasp score and grip score in ARAT score, and the difference of total ARAT score of the patients in experimental group were increased (P<0.05), the TAM after treatment and the differences of grip strength, TAM, and FMA-UL finger motor part score of the patients before and after treatment were increased (P<0.05), while the pinch scores and gross movement scores in ARAT score, MAS grades, and the differences of BI score before and after treatment had no significant differences(P>0.05). Conclusion Force feedback perceptual rehabilitation training is helpful in improving the finger motor function of the patients with finger motor dysfunction after stroke.
Force feedback perceptual / Stroke / Finger motor dysfunction / Rehabilitation treatment
R743.3
| 1 | ZHAO Y F, ZHANG X J, CHEN X Y, et al. Neuronal injuries in cerebral infarction and ischemic stroke: from mechanisms to treatment (Review)[J]. Int J Mol Med, 2022, 49(2): 15. |
| 2 | 王陇德, 吉训明, 康德智, 等. 《中国卒中中心报告2020》概要[J]. 中国脑血管病杂志, 2021, 18(11): 737-743. |
| 3 | MICERA S, CALEO M, CHISARI C, et al. Advanced neurotechnologies for the restoration of motor function[J]. Neuron, 2020, 105(4): 604-620. |
| 4 | REZAEE Z, KAURA S, SOLANKI D, et al. Deep cerebellar transcranial direct current stimulation of the dentate nucleus to facilitate standing balance in chronic stroke survivors-a pilot study[J]. Brain Sci, 2020, 10(2): 94. |
| 5 | CIENFUEGOS M, KIM T, SCHACK T. Variations of sensorimotor representation (structure):the functional interplay between object features and goal-directed grasping actions[J]. Brain Sci, 2022, 12(7): 873. |
| 6 | HASHIDA R, MATSUSE H, BEKKI M, et al. Evaluation of motor-assisted gloves (SEM glove) for patients with functional finger disorders: a clinical pilot study[J]. Kurume Med J, 2019, 65(2): 63-70. |
| 7 | VAHDAT S, DARAINY M, THIEL A,et al. A single session of robot-controlled proprioceptive training modulates functional connectivity of sensory motor networks and improves reaching accuracy in chronic stroke[J]. Neurorehabil Neural Repair, 2019, 33(1): 70-81. |
| 8 | 彭 斌,吴 波.中国急性缺血性脑卒中诊治指南2018[J].中华神经科杂志,2018,51 (9):666-682. |
| 9 | 中华医学会神经病学分会脑血管病学组. 中国脑出血诊治指南(2019)[J].中华神经科杂志,2019,52(12):994-1005. |
| 10 | WU J Y, CHENG H, ZHANG J Q, et al. Robot-assisted therapy for upper extremity motor impairment after stroke: a systematic review and meta-analysis[J]. Phys Ther, 2021, 101(4): pzab010. |
| 11 | LIU F W, CHEN C C, HONG W J, et al. Selectively disrupted sensorimotor circuits in chronic stroke with hand dysfunction[J]. CNS Neurosci Ther, 2022,28(5): 677-689. |
| 12 | CHEN X W, LIU F Q, YAN Z H, et al. Therapeutic effects of sensory input training on motor function rehabilitation after stroke[J]. Medicine, 2018, 97(48): e13387. |
| 13 | 毕文倩, 张锴文, 刘 金, 等. 智能机器人康复手套对脑卒中偏瘫患者手功能的疗效[J]. 中国康复, 2023, 38(3): 131-135. |
| 14 | 赵江莉, 毛玉瑢, 徐智勤, 等. 中文版上肢动作研究量表在早期脑梗死患者中的效度[J]. 中国康复理论与实践, 2019, 25(8): 946-955. |
| 15 | SEO N J, LAKSHMINARAYANAN K, LAUER A W,et al. Use of imperceptible wrist vibration to modulate sensorimotor cortical activity[J]. Exp Brain Res, 2019, 237(3): 805-816. |
| 16 | NILSSON M, INGVAST J, WIKANDER J, et al. The Soft Extra Muscle system for improving the grasping capability in neurological rehabilitation[A].In:IEEE.2012 IEEE-EMBS Conference on Biomedical Engineering and Sciences[C].Malaysia:Langkawi, 2012: 412-417. |
| 17 | NAM C, RONG W, LI W M, et al. The effects of upper-limb training assisted with an electromyography-driven neuromuscular electrical stimulation robotic hand on chronic stroke[J]. Front Neurol, 2017, 8: 679. |
| 18 | KELLER J, ?TěTKá?OVá I, MACRI V, et al. Virtual reality-based treatment for regaining upper extremity function induces cortex grey matter changes in persons with acquired brain injury[J]. J Neuroeng Rehabil, 2020, 17(1): 127. |
| 19 | GOU X X, ZHANG X, ZHENG X X, et al. Effect of hand intensive training on upper limb function of stroke patients with hemiplegia[J]. Comput Math Methods Med, 2022, 2022: 6844680. |
| 20 | KIM D H, LEE K D, BULEA T C, et al. Increasing motor cortex activation during grasping via novel robotic mirror hand therapy: a pilot fNIRS study[J]. J Neuroeng Rehabil, 2022, 19(1): 8. |
| 21 | OSUAGWU B A C, TIMMS S, PEACHMENT R,et al.Home-based rehabilitation using a soft robotic hand glove device leads to improvement in hand function in people with chronic spinal cord injury: a pilot study[J]. J Neuroeng Rehabil, 2020, 17(1): 40. |
/
| 〈 |
|
〉 |
AI Summary
