Upper limb kinematics after cervical spinal cord injury: a review

被引:46
作者
Mateo, Sebastien [1 ,2 ,3 ,5 ]
Roby-Brami, Agnes [4 ]
Reilly, Karen T. [1 ]
Rossetti, Yves [1 ,2 ]
Collet, Christian [3 ]
Rode, Gilles [1 ,2 ,5 ]
机构
[1] Univ Lyon 1, Lyon Neurosci Res Ctr, CNRS, ImpAct Team,INSERM U1028,UMR5292, F-69676 Lyon, France
[2] Hosp Civils Lyon, Hop Henry Gabrielle, F-69000 Lyon, France
[3] Univ Lyon 1, Ctr Rech & Innovat Sport, EA 647, F-69621 Villeurbanne, France
[4] Univ Paris 06, Inst Syst Intelligents & Robot, CNRS, Equipe Agathe INSERM 1150,UMR 7222, F-75006 Paris, France
[5] Hop Henry Gabrielle, Serv Med Phys & Readaptat, F-69230 St Genis Laval, France
关键词
Tetraplegia; SCI; Upper limb; Reaching; Reach-to-grasp; Kinematic; SURGICAL REHABILITATION; ELBOW EXTENSION; MOTOR IMAGERY; TRICEPS; INDIVIDUALS; MOVEMENTS; SHOULDER; TETRAPLEGIA; ANTAGONIST; PREHENSION;
D O I
10.1186/1743-0003-12-9
中图分类号
R318 [生物医学工程];
学科分类号
0831 ;
摘要
Although a number of upper limb kinematic studies have been conducted, no review actually addresses the key-features of open-chain upper limb movements after cervical spinal cord injury (SCI). The aim of this literature review is to provide a clear understanding of motor control and kinematic changes during open-chain upper limb reaching, reach-to-grasp, overhead movements, and fast elbow flexion movements after tetraplegia. Using data from MEDLINE between 1966 and December 2014, we examined temporal and spatial kinematic measures and when available electromyographic recordings. We included fifteen control case and three series case studies with a total of 164 SCI participants and 131 healthy control participants. SCI participants efficiently performed a broad range of tasks with their upper limb and movements were planned and executed with strong kinematic invariants like movement endpoint accuracy and minimal cost. Our review revealed that elbow extension without triceps brachii relies on increased scapulothoracic and glenohumeral movements providing a dynamic coupling between shoulder and elbow. Furthermore, contrary to normal grasping patterns where grasping is prepared during the transport phase, reaching and grasping are performed successively after SCI. The prolonged transport phase ensures correct hand placement while the grasping relies on wrist extension eliciting either whole hand or lateral grip. One of the main kinematic characteristics observed after tetraplegia is motor slowing attested by increased movement time. This could be caused by (i) decreased strength, (ii) triceps brachii paralysis which disrupts normal agonist-antagonist co-contractions, (iii) accuracy preservation at movement endpoint, and/or (iv) grasping relying on tenodesis. Another feature is a reduction of maximal superior reaching during overhead movements which could be caused by i) strength deficit in agonist muscles like pectoralis major, ii) strength deficit in proximal synergic muscles responsible for scapulothoracic and glenohumeral joint stability, iii) strength deficit in distal synergic muscles preventing the maintenance of elbow extension by shoulder elbow dynamic coupling, iv) shoulder joint ankyloses, and/ or v) shoulder pain. Further studies on open chain movements are needed to identify the contribution of each of these factors in order to tailor upper limb rehabilitation programs for SCI individuals.
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页数:12
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