脊髓损伤患者适应性身体活动及其健康效益：基于ICF的Scoping综述

doi:10.3969/j.issn.1006-9771.2023.12.004

《中国康复理论与实践》 ›› 2023, Vol. 29 ›› Issue (12): 1395-1404.doi: 10.3969/j.issn.1006-9771.2023.12.004

脊髓损伤患者适应性身体活动及其健康效益：基于ICF的Scoping综述

石孝宇¹^,²^,³, 杨剑¹()

1.华东师范大学体育与健康学院，上海市 200241
2.伊犁师范大学体育学院，新疆伊宁市 835000
3.伊犁师范大学大学生体质监测中心重点实验室，新疆伊宁市 835000

收稿日期:2023-11-30 出版日期:2023-12-25 发布日期:2023-12-28
通讯作者: 杨剑(1970-)，男，汉族，江苏徐州市人，博士，教授，世界卫生组织国际分类家族合作中心专家委员，主要研究方向：儿童青少年体育与健康、儿童青少年健康、ICF、康复科学、健康心理学、锻炼心理学、康复心理学。E-mail： yangjianxz@sina.com
作者简介:石孝宇(1988-)，男，汉族，河南商丘市人，博士研究生，讲师，主要研究方向：运动心理学、康复心理学、身体活动与健康促进。
基金资助:
教育部人文社科研究项目(22YJA890032)

Adaptive physical activity and its health benefits for patients with spinal cord injury based on ICF: a scoping review

SHI Xiaoyu¹^,²^,³, YANG Jian¹()

1. College of Physical Education and Health, East China Normal University, Shanghai 200241, China
2. Physical Culture Institute, Yili Normal University, Yining, Xinjiang 835000, China
3. Key Laboratory of College Students' Physical Fitness Monitoring Center, Yili Normal University, Yining, Xinjiang 835000, China

Received:2023-11-30 Published:2023-12-25 Online:2023-12-28
Contact: YANG Jian, E-mail: yangjianxz@sina.com
Supported by:
Humanities and Social Sciences Research Project of Ministry of Education(22YJA890032)

摘要/Abstract

摘要：

目的基于《国际功能、残疾和健康分类》(ICF)，对脊髓损伤患者的适应性身体活动方案及其健康效益进行Scoping综述。

方法采用主题词与自由词结合方式，在PubMed、Web of Science、EBSCO和中国知网检索脊髓损伤患者参与适应性身体活动相关文献，检索时限2017年1月至2022年7月。对脊髓损伤患者身体活动及其健康效益的相关证据进行Scoping综述。

结果最终纳入8篇英文文献，来自澳大利亚、美国、爱沙尼亚、加拿大、荷兰和巴西，涉及150例脊髓损伤患者，研究类型涉及7项随机对照研究，1项非随机对照研究。主要来源于脊髓损伤、神经医学、肌肉神经学、身体活动等领域期刊，发表时间主要集中在2017年至2021年。纳入文献中研究对象均患有完全性或不完全性脊髓损伤，主要表现为截瘫、四肢瘫，损伤等级范围为A~D。主要功能障碍涉及ICF的身体功能方面有b710关节活动功能、b715关节稳定功能、b720骨骼活动功能、b730肌肉力量功能、b735肌张力功能、b750运动反射功能、b760随意运动控制功能、b770步态功能；涉及活动和参与功能有d410改变身体的基本姿势、d415保持一种身体姿势、d420移动自身、d445手和手臂的使用、d450步行、d455到处移动、d570照顾个人的健康、d610获得商品和服务、d910社区生活、d920娱乐和休闲；涉及环境因素有e1151个人日常生活中用的辅助用品和技术，e1401文化、娱乐和体育用的辅助用品和技术。身体活动干预场所主要包括居家、社区、医疗或康复机构。身体活动类型为预防类、健康促进类、治疗类、康复类。脊髓损伤患者均已经完成在医疗和康复机构的急性和亚急性康复治疗，回归家庭和社区，有的不定期到医疗康复机构接受服务。身体活动形式包括力量训练结合常规护理、短期抗阻力训练、水疗和机器人跑步机活动、功能性电刺激和治疗性运动、基于动力机器外骨骼的渐进式运动训练、电刺激辅助的腿部自行车结合手动自行车、不同强度的急性运动。活动频率为每次12~60 min，每周2~3次，持续3~16周，活动强度大多为中~高。身体活动对脊髓损伤患者的健康效益主要体现在身体与心理健康、活动与行为健康、环境因素、生活质量与福祉4个方面。在身体与心理健康方面，有助于改善肌肉功能(肌肉力量、力量感知)、步行功能(步行速度、步行距离)、呼吸系统和循环系统功能(峰值摄氧量、有氧耐力、心肺功能、降低心肺疾病风险等)、免疫系统相关功能，改善心理社会功能(疲劳程度)。在活动与行为健康方面，有助于提高活动技能和能力。在环境因素方面，证实一些辅助设备的可用性与有效性。在生活质量和福祉方面，能够提高生活自理能力和生活质量。

结论基于ICF，本研究构建了脊髓损伤患者身体活动及其健康效果的PICO架构。脊髓损伤患者的身体活动可以在家庭、社区或者医疗和康复机构等环境中进行，脊髓损伤患者的身体活动特点为基于轮椅的适应性身体活动，主要分为两类：基于轮椅完成的各种有氧运动、抗阻运动，以及基于辅助运动设备或者干预方法(如机器人跑步机、动力机器外骨骼、功能性电刺激等)完成的身体活动。脊髓损伤患者的身体活动频率为每次12~60 min，每周2~3次，持续3~16周，活动强度大多为中~高。治疗师、运动康复专业人员可以通过多种形式，如线上或线下指导监督练习以及一对一指导等，为脊髓损伤患者提供指导和支持。通过参与身体活动，脊髓损伤患者可以获得的健康效益包括增强体质，提高心肺功能、有氧耐力，改善心理社会功能，提高身体活动参与水平，减少久坐行为，提高生活自理能力和生活质量。

关键词: 脊髓损伤, 身体活动, 适应性体育, Scoping综述

Abstract:

Objective To analyze adaptive physical activity interventions and their health benefits for patients with spinal cord injury (SCI) based on International Classification of Functioning, Disability and Health (ICF).

Methods A combination of subject headings and free words was employed to search for relevant literature on physical activity in patients with SCI in PubMed, Web of Science, EBSCO and CNKI, from January, 2017 to July, 2022. A scoping review was conducted.

Results Eight English articles were included, from Australia, the United States, Estonia, Canada, Netherlands and Brazil. The study involved 150 patients with SCI and included seven randomized controlled trials and one non-randomized controlled trial. These literatures were primarily from journals in the fields of SCI, neurology, neuromuscular medicine and physical activity, with publication dates concentrated between 2017 and 2021. The included studies involved participants with complete or incomplete SCI, presenting with paraplegia, tetraplegia, and various levels of injury severity (grades A to D). The main functional disorders related to ICF included b710 mobility of joint functions, b715 stability of joint functions, b720 mobility of bone functions, b730 muscle power functions, b735 muscle tone functions, b750 motor reflex functions, b760 control of voluntary movement functions and b770 gait pattern functions; the functions involved in activities and participation included d410 changing basic body position, d415 maintaining a body position, d420 transferring oneself, d445 hand and arm use, d450 walking, d455 moving around, d570 looking after one's health, d610 acquiring a place to live, d910 community life, d920 recreation and leisure; the environmental factors involved were e1151 assistive products and technology for personal use in daily living, and e1401 assistive products and technology for culture, recreation and sport. Physical activity intervention sites mainly included home, community, medical or rehabilitation institutions. The physical activity could be classified into prevention, health promotion, treatment and rehabilitation. Patients with SCI had completed acute and subacute rehabilitation in medical and rehabilitation institutions, and returned to their families and communities, and some of them received services in medical and rehabilitation institutions from time to time. The forms of physical activity included strength training combined with routine nursing, short-term resistance training, hydrotherapy and robot treadmill activities, functional electrical stimulation and therapeutic exercise, progressive exercise training based on exoskeleton of power machine, leg bicycle assisted by electrical stimulation combined with manual bicycle, and acute exercise with different intensity. The activity frequency was twelve to 60 minutes a time, two to three times a week, lasting for three to 16 weeks, and the activity intensity was mainly medium to high. The health benefits of physical activity on patients with SCI were mainly reflected in four aspects: physical and mental health, activity and behavior health, environmental factors, quality of life and well-being. In terms of physical and mental health, it helped to improve muscle function (muscle strength, strength perception), walking function (walking speed, walking distance), respiratory and circulatory system functions (peak oxygen uptake, aerobic endurance, cardiopulmonary function, reducing the risk of cardiopulmonary diseases, etc.), immune system related functions, and improving psychosocial function (fatigue degree). In terms of activity and behavioral health, it was helpful to improve activity skills and abilities. In terms of environmental factors, the availability and effectiveness of some auxiliary equipment were confirmed. In terms of quality of life and well-being, it could improve self-living ability and quality of life.

Conclusion This study established a PICO framework for adaptive physical activity and its health effects in patients with SCI based on ICF. Physical activity for patients with SCI can be conducted in various settings, including home, community, or medical and rehabilitation institutions. The physical activities of patients with SCI are characterized by wheelchair-based adaptive physical activities, which are mainly divided into two categories: various aerobic exercises and resistance exercises based on wheelchairs, and physical activities based on auxiliary exercise equipment or intervention methods (such as robot treadmill, power machine exoskeleton, functional electrical stimulation, etc.). The frequency of physical activity in patients with SCI is twelve to 60 minutes a time, two to three times a week, lasting for three to 16 weeks, and the activity intensity is maily medium to high. Therapists and rehabilitation professionals can provide guidance and support through various means, such as online or offline supervision and one-on-one coaching, to promote the health benefits of physical activity for patients with SCI, including improved physical and psychological function, enhanced activity levels, reduced sedentary behavior, and increased self-care abilities and quality of life.

Key words: spinal cord injury, physical activity, adaptive sports, scoping review

中图分类号:

R651.2

石孝宇, 杨剑. 脊髓损伤患者适应性身体活动及其健康效益：基于ICF的Scoping综述[J]. 《中国康复理论与实践》, 2023, 29(12): 1395-1404.

SHI Xiaoyu, YANG Jian. Adaptive physical activity and its health benefits for patients with spinal cord injury based on ICF: a scoping review[J]. 《Chinese Journal of Rehabilitation Theory and Practice》, 2023, 29(12): 1395-1404.

图/表 3

表1

Scoping综述研究架构"

人群(Population)	干预(Intervention)	比较(Comparison)	结局(Outcome)
健康状况脊髓损伤(康复期) 完全性不完全性损伤等级受伤时间年龄功能状况身体功能 b710 关节活动功能 b715 关节稳定功能 b720 骨骼活动功能 b730 肌肉力量功能 b735 肌张力功能 b750 运动反射功能 b760 随意运动控制功能 b770 步态功能活动和参与 d410 改变身体的基本姿势 d415 保持一种身体姿势 d420 移动自身 d445 手和手臂的使用 d450 步行 d455 到处移动 d570 照顾个人的健康 d610 获得商品和服务 d910 社区生活 d920 娱乐和休闲环境 e1151 个人日常生活中用的辅助用品和技术 e1401 文化、娱乐和体育用的辅助用品和技术	身体活动场所居家社区医疗或康复机构身体活动干预属性预防类健康促进类治疗类康复类身体活动方案活动方式活动频率活动强度活动持续时间活动支持与指导人员	参与活动组与不参与活动组比较参与活动前后比较参与不同活动方式的组间比较参与不同强度的活动组比较	身体和心理健康肌肉功能(肌肉力量、力量感知) 步行功能(步行速度、步行距离) 呼吸系统和循环系统功能(峰值摄氧量、有氧耐力、心肺功能、降低心肺疾病风险、颈动脉硬化等) 免疫系统心理社会功能(疲劳程度) 活动和行为健康活动(运动技能、日常生活和活动性相关的活动) 身体活动参与(身体活动水平、有氧健身水平) 环境因素辅助设备使用生活质量与福祉生活质量	身体和心理健康 b730 肌肉力量功能 b770 步态功能 b450 辅助呼吸功能 b455 运动耐受功能 b460 与心血管和呼吸功能相关的感觉 b435 免疫系统功能 b122 整体心理社会功能 b130 能量和驱力功能活动和行为健康 d155 掌握技能 d410 改变身体的基本姿势 d415 保持一种身体姿势 d499 未特指的活动 d570 照顾个人的健康 d9201 运动环境因素 e1401 文化、娱乐和体育用的辅助用品和技术生活质量与福祉 d910社区生活 d920娱乐和休闲

表1

图1

表2

纳入文献基本特征"

作者	国家	样本特征	健康及功能状况	身体活动场所	身体活动干预属性	身体活动方案	比较	健康结局指标
Bye等^[1] (2017)	澳大利亚	n = 30 (干预组15例，对照组15例)；年龄25~65岁，平均46岁	不完全性脊髓损伤损伤程度：神经水平C₁~L₃，运动水平C₁~L₃ 受伤时间：1.4~3.1个月，平均2个月	医疗或康复机构	治疗类康复类	活动方式：力量训练、日常生活活动的步态和功能训练(如转移、行走、滚动和推动手动轮椅训练) 活动频率：每次4组训练，每组10次，共计40次收缩训练，组间休息2 min，前两组每组进行10次等长收缩(持续4 s，间隔4 s)，后两组进行向心收缩；每周3次活动强度：中~高活动持续时间：12周活动指导与支持人员：职业治疗师	参与身体活动与单独的常规护理组比较	身体和心理健康部分瘫痪肌肉的力量增强；力量感知功能改善活动和行为健康未提及环境因素未提及生活质量与福祉未提及
Bye等^[10](2019)	澳大利亚	n = 10 (干预组5例，对照组5例) 年龄> 18岁	不完全性脊髓损伤，部分瘫痪(肘屈肌、肘伸肌、膝屈肌或膝伸肌) 损伤程度：神经水平C₃~L₁，运动水平C₃~L₃ 受伤时间：受伤后5个月~14年	社区	健康促进类	活动方式：抗阻训练活动频率：每次4组训练，每组10次，共计40次收缩训练，组间休息2 min，前两组每组进行10次等长收缩(持续4 s，间隔4 s)，后两组进行向心收缩；每周3次活动强度：中~高活动持续时间：6周活动指导与支持人员：熟练物理治疗师	参与身体活动前后比较	身体和心理健康平均最大等长肌肉力量增加14% 活动和行为健康未提及环境因素未提及生活质量与福祉未提及
Gorman等^[11] (2019)	美国	n = 31 (干预组16例，对照组15例) 年龄18~65岁	不完全性脊髓损伤损伤程度：神经水平C₂~T₁₂，损伤等级C~D 受伤时间：至少12个月	医疗或康复机构	治疗类康复类	活动方式：机器人跑步机、水疗活动频率：每次45 min，每周3次活动强度：中~高活动持续时间：12周活动指导与支持人员：职业治疗师	参与不同身体活动方式比较	身体和心理健康峰值摄氧量显著改善；心肺功能显著改善；心肺风险显著降低活动和行为健康未提及环境因素未提及生活质量与福祉未提及
Bergmann等^[12] (2020)	爱沙尼亚	n = 10 (干预组5例，对照组5例) 年龄18~55岁	不完全性脊髓损伤、四肢瘫损伤程度：神经水平S₄~S₅，损伤等级B~C；受伤时间：至少12个月	居家	预防类治疗类康复类	活动方式运动康复：每个练习12次重复，分3组完成功能性电刺激：热身和恢复阶段的频率设置为3 Hz。在实施阶段，8 Hz 18 s，2 Hz 2 s，18 Hz 10 s等，交替连续重复，没有停顿活动频率：每次12~45 min，每周2次活动强度：低~中活动持续时间：6周活动指导与支持人员：熟练物理治疗师	参与不同身体活动方式比较；身体活动与功能性电刺激组合方式以及两者结合方式的比较	身体和心理健康背肌和腹直肌力量显著增强；疲劳程度得到缓解活动和行为健康未提及环境因素未提及生活质量与福祉自我照顾能力得到改善
Gagnon等^[13] (2018)	加拿大	n = 14 (干预组7例，对照组7例) 年龄26.7~63.1岁	完全性脊髓损伤损伤程度：神经水平T₄~T₁₀，损伤等级A~B 受伤时间：未提及	社区	健康促进类康复类	活动方式：基于动力机器外骨骼的渐进式运动训练(可穿戴机器人外骨骼EKSOTM 1.1) 活动频率：每次45~60 min，每周3次活动强度：中~高活动持续时间：6~8周活动指导与支持人员：熟练物理治疗师	参与身体活动前后比较	身体和心理健康步行速度显著提高活动和行为健康姿势控制能力得到显著改善环境因素机器人外骨骼辅助脊髓损伤患者是可行的，可安全使用生活质量与福祉未提及
Jansen等^[14] (2021)	荷兰	n = 10 (干预组5例，对照组5例) 年龄28~65岁	完全性脊髓损伤损伤程度：神经水平T₄~T₁₁，损伤等级A~C 受伤时间：至少96个月	医疗或康复机构	治疗类康复类	活动方式：电刺激辅助的腿部自行车、手动自行车活动频率：每次40~45 min，每周2次活动强度：中~高活动持续时间：16周活动指导与支持人员：职业治疗师	参与不同身体活动比较	身体和心理健康不会导致全身血管适应性改变活动和行为健康未提及环境因素未提及生活质量与福祉未提及
Ma等^[15](2019)	加拿大	n = 28 (干预组14例，对照组14例) 平均年龄45岁	完全性脊髓损伤损伤程度：损伤等级A 受伤时间：196.8个月	家庭	健康促进类康复类	活动方式：有氧运动活动频率：每次15 min，每周5次(其中第1次为治疗师指导，后4次自主练习) 活动强度：中~高活动持续时间：8周活动指导与支持人员：熟练物理治疗师	干预组与对照组比较	身体和心理健康心理社会预测指标显著改善；颈动脉硬化得到改善活动和行为健康中等到剧烈体力活动增加了5倍，体力活动增加了17%；有氧健身水平提高了19%；掌握自我管理锻炼的技能环境因素未提及生活质量与福祉改善健康相关的生活质量
Alves等^[16](2021)	巴西	n = 17 (干预组9例，对照组8例)；年龄> 18岁	完全性脊髓损伤、截瘫损伤程度：损伤等级A~C 受伤时间：至少12个月	社区	健康促进类康复类	活动方式：适用于轮椅的跑步机活动频率：每次30 min，每周2次活动强度：中~高活动持续时间：3周活动指导与支持人员：社区卫生人员	参与不同身体活动比较	身体和心理健康峰值摄氧量显著改善；急性系统性抗炎细胞因子反应明显减弱；疲劳程度得到缓解活动和行为健康未提及环境因素未提及生活质量与福祉未提及

表2

参考文献 28

[1]	BYE E A, HARVEY L A, GAMBHIR A, et al. Strength training for partially paralysed muscles in people with recent spinal cord injury: a within-participant randomised controlled trial[J]. Spinal Cord, 2017, 55(5): 460-465. doi: 10.1038/sc.2016.162 pmid: 27922626
[2]	WOUDA M F, LUNDGAARD E, BECKER F, et al. Effects of moderate- and high-intensity aerobic training program in ambulatory subjects with incomplete spinal cord injury: a randomized controlled trial[J]. Spinal Cord, 2018, 56(10): 955-963. doi: 10.1038/s41393-018-0140-9
[3]	CHAMBERLAIN J D, BUZZELL A, GMÜNDER H P, et al. Comparison of all-cause and cause-specific mortality of persons with traumatic spinal cord injuries to the general swiss population: results from a National Cohort Study[J]. Neuroepidemiology, 2019, 52(3-4): 205-213. doi: 10.1159/000496976 pmid: 30763935
[4]	HARVEY L A. Physiotherapy rehabilitation for people with spinal cord injuries[J]. J Physiother, 2016, 62(1): 4-11. doi: 10.1016/j.jphys.2015.11.004 pmid: 26701156
[5]	MILLER L E, HERBERT W G. Health and economic benefits of physical activity for patients with spinal cord injury[J]. Clinicoecon Outcomes Res, 2016, 8(5): 551-558. doi: 10.2147/CEOR
[6]	World Health Organization. WHO guidelines on physical activity and sedentary behaviour[M]. Geneva: World Health Organization, 2020.
[7]	邱卓英, 李伦, 陈迪, 等. 基于世界卫生组织国际健康分类家族康复指南研究:理论架构和方法体系[J]. 中国康复理论与实践, 2020, 26(2): 125-135. doi: 10.3969/j.issn.1006-9771.2020.02.001
	QIU Z Y, LI L, CHEN D, et al. Research on rehabilitation guidelines using World Health Organization Family International Classifications: framework and approaches[J]. Chin J Rehabil Theory Pract, 2020, 26(2): 125-135.
[8]	邱卓英, 郭键勋, 李伦, 等. 世界卫生组织康复指南«健康服务体系中的康复»:背景、理论架构与方法、主要内容和实施[J]. 中国康复理论与实践, 2020, 26(1): 16-20. doi: 10.3969/j.issn.1006-9771.2020.01.003
	QIU Z Y, KWOK J F K, LI L, et al. WHO Rehabilitation in Health System: background, framework and approach, contents and implementation[J]. Chin J Rehabil Theory Pract, 2020, 26(1): 16-20.
[9]	王国祥, 姜静远, 邱卓英, 等. 康复体育政策架构、优先领域及其核心内容:基于WHO康复政策内容分析[J]. 中国康复理论与实践, 2022, 28(12): 1380-1389. doi: 10.3969/j.issn.1006-9771.2022.12.002
	WANG G X, JIANG J Y, QIU Z Y, et al. Framework, core contents and priority of rehabilitation of physical activity and exercise in health service: a content analysis of WHO rehabilitation policies[J]. Chin J Rehabil Theory Pract, 2022, 28(12): 1380-1389.
[10]	BYE E A, HARVEY L A, GLINSKY J V, et al. A preliminary investigation of mechanisms by which short-term resistance training increases strength of partially paralysed muscles in people with spinal cord injury[J]. Spinal Cord, 2019, 57(9): 770-777. doi: 10.1038/s41393-019-0284-2 pmid: 31092897
[11]	GORMAN P H, SCOTT W, VANHIEL L, et al. Comparison of peak oxygen consumption response to aquatic and robotic therapy in individuals with chronic motor incomplete spinal cord injury: a randomized controlled trial[J]. Spinal Cord, 2019, 57(6): 471-481. doi: 10.1038/s41393-019-0239-7 pmid: 30659286
[12]	BERGMANN M, ZAHHAROVA A, ERELINE J, et al. Single session exercises and concurrent functional electrical stimulation are more effective on muscles' force generation than only exercises in spinal cord injured persons: a feasibility study[J]. J Musculoskelet Neuronal Interact, 2020, 20(4): 472-479. pmid: 33265074
[13]	GAGNON D H, ESCALONA M J, VERMETTE M, et al. Locomotor training using an overground robotic exoskeleton in long-term manual wheelchair users with a chronic spinal cord injury living in the community: lessons learned from a feasibility study in terms of recruitment, attendance, learnability, performance and safety[J]. J Neuroeng Rehabil, 2018, 15(1): 12. doi: 10.1186/s12984-018-0354-2 pmid: 29490678
[14]	JANSEN E, DE GROOT S, SMIT C A, et al. Vascular adaptations in nonstimulated areas during hybrid cycling or handcycling in people with a spinal cord injury: a pilot study of 10 cases[J]. Spinal Cord Ser Cases, 2021, 7(1): 54. doi: 10.1038/s41394-021-00417-2 pmid: 34193818
[15]	MA J K, WEST C R, MARTIN GINIS K A. The effects of a patient and provider co-developed, behavioral physical activity intervention on physical activity, psychosocial predictors, and fitness in individuals with spinal cord injury: a randomized controlled trial[J]. Sports Med, 2019, 49(7): 1117-1131. doi: 10.1007/s40279-019-01118-5 pmid: 31119717
[16]	ALVES E D S, DOS SANTOS R V T, DE LIRA F S, et al. Effects of intensity-matched exercise at different intensities on inflammatory responses in able-bodied and spinal cord injured individuals[J]. J Spinal Cord Med, 2021, 44(6): 920-930. doi: 10.1080/10790268.2020.1752976
[17]	EDWARDS D J, FORREST G, CORTES M, et al. Walking improvement in chronic incomplete spinal cord injury with exoskeleton robotic training (WISE): a randomized controlled trial[J]. Spinal Cord, 2022, 60(6): 522-532. doi: 10.1038/s41393-022-00751-8 pmid: 35094007
[18]	ALASHRAM A R, ANNINO G, PADUA E. Robot-assisted gait training in individuals with spinal cord injury: a systematic review for the clinical effectiveness of Lokomat[J]. J Clin Neurosci, 2021, 91(1): 260-269. doi: 10.1016/j.jocn.2021.07.019
[19]	NIGHTINGALE T E, METCALFE R S, VOLLAARD N B, et al. Exercise guidelines to promote cardiometabolic health in spinal cord injured humans: time to raise the intensity?[J]. Arch Phys Med Rehabil, 2017, 98(8): 1693-1704. doi: 10.1016/j.apmr.2016.12.008
[20]	MORONE G, PIRRERA A, IANNONE A, et al. Development and use of assistive technologies in spinal cord injury: a narrative review of reviews on the evolution, opportunities, and bottlenecks of their integration in the health domain[J]. Healthcare (Basel), 2023, 11(11): 1646.
[21]	DOLBOW D R, GORGEY A S, JOHNSTON T E, et al. Electrical stimulation exercise for people with spinal cord injury: a healthcare provider perspective[J]. J Clin Med, 2023, 12(9): 3150. doi: 10.3390/jcm12093150
[22]	FANG C Y, LIEN A S, TSAI J L, et al. The effect and dose-response of functional electrical stimulation cycling training on spasticity in individuals with spinal cord injury: a systematic review with meta-analysis[J]. Front Physiol, 2021, 12(9): 756200. doi: 10.3389/fphys.2021.756200
[23]	VAN SILFHOUT L, VÁŇA Z, PĔTIOKÝ J, et al. Highest ambulatory speed using Lokomat gait training for individuals with a motor-complete spinal cord injury: a clinical pilot study[J]. Acta Neurochir (Wien), 2020, 162(4): 951-956. doi: 10.1007/s00701-019-04189-5 pmid: 31873795
[24]	BIN L, WANG X, JIATONG H, et al. The effect of robot-assisted gait training for patients with spinal cord injury: a systematic review and meta-analysis[J]. Front Neurosci, 2023, 17(1): 1252651. doi: 10.3389/fnins.2023.1252651
[25]	PELLETIER C A, TOTOSY DE ZEPETNEK J O, MACDONALD M J, et al. A 16-week randomized controlled trial evaluating the physical activity guidelines for adults with spinal cord injury[J]. Spinal Cord, 2015, 53(5): 363-367. doi: 10.1038/sc.2014.167 pmid: 25266695
[26]	WATSON P K, ARORA M, MIDDLETON J W, et al. Leisure-time physical activity in people with spinal cord injury-predictors of exercise guideline adherence[J]. Int J Public Health, 2022, 67(5): 1605235. doi: 10.3389/ijph.2022.1605235
[27]	MARTIN GINIS K A, LATIMER-CHEUNG A E, WEST C R. Commentary on "The First Global Physical Activity and Sedentary Behavior Guidelines for People Living with Disability"[J]. J Phys Act Health, 2021, 18(4): 348-349. doi: 10.1123/jpah.2020-0871 pmid: 33741746
[28]	RAUCH A, HINRICHS T, OBERHAUSER C, et al. Do people with spinal cord injury meet the WHO recommendations on physical activity?[J]. Int J Public Health, 2016, 61(1): 17-27. doi: 10.1007/s00038-015-0724-5 pmid: 26303072

脊髓损伤患者适应性身体活动及其健康效益：基于ICF的Scoping综述

Adaptive physical activity and its health benefits for patients with spinal cord injury based on ICF: a scoping review

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