Studying upper extremity range of motion using 3D kinematic analysis and surface electromyography (EMG) may come to be an important tool for clinical decision-making and measuring results in patients with cerebrovascular accidents (CVA).1 Compared to gait analysis, 3D analysis of the upper extremities presents an array of difficulties. Firstly, the upper extremities do not engage in only one relevant functional activity. Secondly, the functional activities of upper extremities vary greatly within the general population, unlike gait, which follows a typical pattern. Third, the upper extremities, and the shoulder joint in particular, have a very wide range of motion compared to the lower extremities. All of these factors make movement analysis of the upper extremities very problematic. Upper extremity kinematics have been studied previously.2 Until now, however, no studies have examined the function of the upper extremities using 3D systems. Previous studies have analysed daily life activities (DLA) in healthy subjects3–6 and in patients with various neurological conditions.7–10 Few studies of CVA patients evaluate kinematics in DLA,11,12 and to our knowledge, none of those studies uses EMG activity in its analysis.

This cerebrovascular lesion affects brain areas and structures (the basal ganglia, for example) which are directly involved in performing DLA. Throughout the process of learning to creep, crawl and walk upright, these structures create priority pathways for extremity nerve roots. These pathways will constitute the easiest instructions for synchronising hand movements.13,14 A hand movement to carry out a specific task originates in the cortex, but the position of the wrist, elbow and shoulder is adopted according to the basal ganglia's motor schemas. Additionally, the cerebellum, which is the motor coordination centre, is closely linked to these activities and facilitates cortical activity in distal movement. The motor system's continuous processing of afferent sensory signals prepares for motor actions and refines the performance of fine motor tasks. Through this continuous processing, the central nervous system (CNS) gathers information proceeding from a number of sensory channels, thereby enabling completion of specific tasks.15

Following the physiological brain lesion, CVA patients mainly present motor limitations on the side of the body contralateral to the damaged hemisphere. This means that changes occur in motor patterns for the upper extremity on the affected side, which is contralateral to the damaged brain hemisphere, as well as in the trunk and the upper extremity ipsilateral to the damaged brain hemisphere.16 In any case, the body develops compensatory motor strategies, and repetitive use of these strategies may cause musculoskeletal disorders. Measuring existing motor limitations and compensatory motor strategies lets us target the motor disorder precisely,11 and therefore decreases the need for developing compensatory motor strategies.

The purpose of this study is to analyse the kinematic and chronological differences in muscle activation that may be present in CVA patients and healthy subjects in the task of drinking water from a cup. Our study's hypothesis is that the upper extremity limitations in CVA patients will produce a compensatory motor strategy in patients when they drink water from a cup. This compensatory strategy will affect other muscles, mainly those in the trunk. Additionally, we believe that the muscle activation sequence will vary in order to compensate for the muscles specific to the motor pattern.

We observed a decreased range of motion along the sagittal plane of the elbow and shoulder during a drinking task in CVA patients with respect to healthy subjects. These differences had a significant effect on the shoulder joint range of motion. Trunk articulation ranges of motion were significantly larger in patients than in control subjects. This was also true for shoulder range of motion along the frontal plane (Table 1).

The most significant differences observed in the muscle activation sequence were in the superior trapezius, which was activated during the entire task in the CVA patient group. However, in healthy subjects, it was only activated during the steps of lifting the cup to the lips and returning it to the table. The anterior, medial and posterior deltoid fibres were activated and co-contracted in CVA patients during the first 3 steps of the drinking task: beginning the capture process by moving the hand from its initial position to the cup, grasping the cup, and lifting it to the lips. In control subjects, deltoid activity was more specific. Anterior fibres were mainly activated in 2 steps of the activity: beginning the capture process by moving the hand from its initial position to the cup, and grasping the cup. Medial fibres were activated during the steps of transporting the cup to the lips and returning it to the table. Lastly, posterior deltoid fibres were only activated during the last step of the task, which was releasing the cup and returning the hand to its initial position. The biceps brachii showed similar activation sequences in both groups. However, there were differences in the activation sequences of the triceps brachii. In CVA patients, this muscle activated during 2 events: beginning the capture process by moving the hand from its initial position to the cup, and transporting the cup to the lips. In the control group, the triceps was not activated during transport of the cup, but rather during the last step, that is, releasing the cup and returning the hand to its initial position. In the patient group, we observed activation of the extensor and flexor muscles of the wrist during the steps of grasping and releasing the cup. In the control subjects, wrist extensors were activated in the steps of grasping and releasing the cup, and wrist flexors were mainly activated during transport of the cup to the lips.

The purpose of this study was to analyse 3D kinematics and the muscle activation sequence of the upper extremity during the task of drinking from a cup in both CVA patients and healthy subjects.

The main finding is decreased joint range of motion along the sagittal plain of the upper extremity in CVA patients compared to controls, which was anticipated. Decreased range of motion affects the two analysed articulations (shoulder and elbow), and this complicates the task of drinking by making movement less fluid and increasing the risk of dropping the cup. This deficit is compensated for through an increase in trunk motion, with larger ranges of motion for flexion-extension and inclination. Along the frontal plane of the shoulder, abduction–adduction range of motion increases, which aids in performing the activity and completing the task of drinking the water in the cup.

Results from the study by Murphy et al.11 coincide with our own in that stroke patients demonstrated increased shoulder abduction and decreased elbow extension, in addition to increased anterior displacement of the trunk. Other studies18,19 have also observed increased mobilisation of the trunk in stroke patients performing reaching activities. Increased mobilisation of the trunk in stroke patients has been reported as an indicator of greater severity.20 Functional evaluations of stroke patients should therefore include an analysis of trunk displacement.

The muscle activation sequence reported by EMG describes activity chronologies that differ between control subjects and CVA patients. The latter show a compensation pattern that is mainly driven by the superior trapezius. In patients with CVA, the deltoid fibres show poorly disassociated activity. Deltoid fibres are mainly responsible for completing the first steps in the task. These initial steps, which include beginning the activity, extending the arm and raising the arm to bring the hand to the mouth, take place less fluidly, one by one. There is a decrease in synergic activity by the superior trapezius and the different deltoid fibres. Posterior fibres of the deltoids and triceps brachii in stroke patients do not participate in the last steps in the activity (lowering the arm and returning it to its original position) as they do in control subjects. These motions are performed by the superior trapezius. Therefore, the motion of descending and retracting the upper extremity to return it to its initial position, driven in control subjects by posterior fibres in the deltoids and triceps, is driven by the muscle action of the superior trapezius in stroke patients.

At present, some authors state that techniques based on recovering movement are less effective than those based on compensation mechanisms.21 Studies using surface EMG and 3D kinematic analysis to evaluate DLAs provide sufficient information about impaired muscles and limited joint range of motion during performance of an activity. At the same time, they deliver information about the muscles involved in compensation strategies, and their joint kinematics. By knowing which muscles are active, which are deficient, and what kinematic compensation strategies are used, we can design specific treatment with no need to recur to compensatory therapy methods.

The limits of the study are the number of movements and list of DLAs that were analysed. This is a pilot study within a line of research whose objectives include expanding the sample size, analysing other joints such as the wrist, evaluating other planes of motion and measuring other highly relevant variables such as joint kinetics and muscle strength. In addition, studies including data from both impaired and healthy upper extremities provide information about the biomechanical or neuroplastic origin of movement disorders in the side of the body ipsilateral to the lesioned brain hemisphere.16

The knowledge we gather from optoelectronic movement analysis systems together with surface EMG is fundamental in order to make clinical decisions and monitor the patient properly. A 3D analysis of the movements required to drink from a cup permits precise measurement of the ranges of motion of the articulations involved in performing this daily life activity.

This study was carried out as part of the research project Hybrid NeuroProsthetic and NeuroRobotic Devices for Functional Compensation and Rehabilitation of Motor Disorders (HYPER) within the programme CONSOLIDER-Ingenio 2010 and the 6th Spanish National Plan for scientific research, development and technological innovation 2008–2011.