Posture Of Upper Limb Research Articles

Quantification of Upper Limb Motion During Gait in Children with Hemiplegic Cerebral Palsy

Movements of the lower limbs during gait have been widely investigated using gait analysis, while data on upper limb movements are scanty. The aim of the present study was to quantify upper limb motion during gait in children with hemiplegic cerebral palsy (CP). Gait of 13 children with hemiplegic CP was acquired using a full-body marker set to obtain the arm kinematics. Our results demonstrated that movement of the plegic arm was characterized by an abducted intra-rotated shoulder and a more flexed elbow position with reduced range of motion during the entire gait cycle compared to controls. The controlateral non-plegic side also showed abnormalities, in particular at the shoulder joint, which was abducted at the beginning of gait cycle. These data showed that gait of children with hemiplegic CP is generally characterized by abnormal upper limb position not only on the plegic side but also on the non-plegic side.

Recovery of submaximal upper limb force production is correlated with better arm position control and motor impairment early after a stroke

Objective This study determined whether recovery of upper limb position control using submaximal force production correlates with an improvement in functional arm impairment during early recovery from stroke. Methods Ten consecutive inpatients were recruited from a stroke unit. Each patient was in early recovery (<8 weeks post-lesion) from their first ever stroke. Evaluations of submaximal continuous force production and position control, maximal force production at the shoulder and a clinical outcome measure of motor impairment (Fugl-Meyer score; FM) were performed 20 days post-stroke as a baseline and then once a week for the following four weeks. Results Submaximal force production and its modulation during a position-holding task improved in early recovery after stroke, whereas maximal force production did not. Better modulation of submaximal force production enabled improved arm position control which was significantly correlated to the changes in FM score of motor impairment during recovery. Conclusions This study demonstrated that improvement in submaximal force modulation can operate as a mechanism enabling better motor behaviour such as arm position control during early recovery from a stroke. Significance Future rehabilitation strategies may benefit from adding submaximal force development and modulation to early interventions after stroke.

2P2-B10 光学センサーを用いた上肢運動機能リハビリテーション計測装置の開発(リハビリテーションロボティクス・メカトロニクス)

Rehabilitation exercises which maintain a patient's interest and quantitative evaluation of rehabilitation are required. To solve these problems, we have development of measuring equipment for upper limb motor function rehabilitation using optical sensor. This system consists of an optical sensor device, a personal computer and calculator program for upper limb position. When users move the optical sensor, the motion measuring equipment calculates position. We measured the optical sensor position and migration length during a sanding task and wiping. The accuracy of the optical sensor trajectories was similar in all actual measured value. These results can be use for the development of rehabilitation training programs and evaluation methods.

농작업에서 발생하는 하지자세의 근골격계 질환 위험도 평가를 위한 인간공학적 평가도구 개발

Objective: To develop an ergonomic evaluation tool which can be apply to assess the lower-limb postures associated with farming tasks. Background: In general, most of existing ergonomic assessment tools was developed to investigate the work-related musculoskeletal disorders of the upper-limb postures in manufacturing industry. Methods: As the first step of development of the evaluation tool, 13 lower-limb postures that were commonly observed in farming task were investigated by the subjective discomfort ratings, heart rates, and muscle activities. And then, an ergonomic evaluation tool for the lower-limb postures was developed based on results of the first experiment. Lastly, the ergonomic checklist which was developed in the current study was compared with other existing ergonomic assessment tools. Results: Based on the results of comparisons between a newly developed assessment tool and other existing assessment tools, it was found that a newly developed tool can perceive more sensitively for the various lower-limb postures than other assessment tools. Conclusions: Lower-limb posture assessment tool which can evaluate and assess risks of lower-limb WMSDs which were prevalent in farming tasks more easily and accurately was developed in this study. The lower-limb assessment tool can also be utilized to prevent WMSDs related with lower-limbs as well as improve working environments.

Adult‐onset leg dystonia due to a missense mutation in THAP1

THAP1 encodes a transcription factor that contains an atypical zinc finger domain and regulates cell proliferation in the context of cell cycle progression.1 An Exon 2 insertion/deletion frameshift mutation in THAP 1 produces DYT 6 dystonia in Amish-Mennonites.1 Two early, follow-up studies identified 11 additional sequence variants in familial, primarily early-onset, primary dystonia.2 More recently, a heterogeneous collection of THAP1 sequence variants has been associated with varied anatomical distributions and onset ages of both familial and sporadic primary dystonia. Adult-onset dystonia characteristically begins in the craniocervical or brachial areas and tends to remain confined to these regions, whereas dystonia manifesting before the age of 30 usually starts in a leg or arm and then becomes more generalized.3 Peripheral trauma and other sensorimotor perturbations may induce dystonia in genetically predisposed individuals.4,5 Adult-onset focal lower extremity dystonia usually involves foot inversion.6 A 63-year-old, right-handed American man of Danish ancestry, and without known Amish-Mennonite roots, presented with a 12-year history of gait difficulties, initially manifesting as intermittent “flopping” of his left foot and paresthesias over the lateral aspect of his left leg. He had not undergone lumbo-sacral spine surgery. Over time, the patient began to notice that his left leg would feel “tight, like a bow” while ambulating. He also found that he would “need to walk quicker to feel more stable.” Indeed, his wife has noticed that he seems to walk at a “double-step” now. He has not found other gait adaptations that will alleviate his problem nor is a diurnal variation apparent; the feeling of “tightness” in his leg is only apparent while ambulating. A couple of years before presentation, the patient retired from the post office, because of deterioration in his handwriting, associated with “shaking” and a feeling of “tightness” in his forearm and hand. The latter has not been alleviated by alcohol consumption or writing in different positions. The patient does not have much difficulty with tasks, such as eating, pouring, or dressing. His deceased father was diagnosed with “torticollis” after sustaining a neck injury at age 16, and a living, paternal aunt developed “neck shaking and twitching,” allegedly after undergoing thyroid surgery in her 20s. The patient’s examination was notable for mild, left L5/S1 distribution weakness. His gait revealed excessive contraction of his left hamstrings and gastrocnemius as he made a step with his left leg; having him walk backward and run did not alleviate his gait dysfunction notably (see video, segment 1). The patient had a severe writing tremor, yet only a subtle postural and action upper limb tremor, and no action tremor on pouring (see video, segments 2 and 3), suggesting that his writing tremor is likely dystonic. No adventitial neck movements or abnormal cervical or upper limb postures were evident. Electromyography revealed evidence of a relatively mild, quiescent, left L5/S1 radiculopathy. Sequencing of THAP1 in the forward and reverse directions revealed a c.446T>C sequence variant, producing substitution of a strongly hydrophobic isoleucine residue with a threonine (l149T) in the nuclear localization signal domain of THAP1. The patient’s paternal aunt, alluded to above, was found to harbor the same c.446T>C sequence variant. The patient has not responded to a levodopa trial and has not been interested in pursuing other treatment options, such as botulinum toxin injections. Our patient’s history of present illness, family history, neurologic and neurophysiologic examinations, and THAP1 mutation demonstrate that adult-onset, primary dystonia may begin in a lower extremity, may not be associated with foot inversion, and reinforces that the anatomic site of onset of a primary dystonia may be influenced by trauma and/or a structural lesion, potentially producing a multifocal dystonic state.

Wherever is my arm? Impaired upper limb position accuracy in Complex Regional Pain Syndrome

Knowledge of the position of one’s limbs is an essential component of daily function and relies on complex interactions of sensorimotor body schema-related information. Those with Complex Regional Pain Syndrome (CRPS) express difficulty in knowing where their affected limb is positioned. The aim of this study was to determine the degree to which experimental data supported the reported difficulty in limb position sense. A controlled experimental design was used to measure upper limb position accuracy amongst those with CRPS of one arm. Position accuracy was individually measured in both arms and compared to a known target position. Video captured each of 36 trials (half with arm in full view and half with vision obscured). The error in degrees between actual and known targets was determined using video analysis software. The Brief Pain Inventory measured pain. A subjective mental image representation of both upper limbs was documented. The CRPS group had moderate pain intensity and were significantly less accurate in positioning both the affected and unaffected limbs compared to controls ( p < 0.001). Position accuracy of the CRPS affected limb significantly improved with vision (8.3° in view, 10.7° not in view). Subjective mental representations of the affected limb were visualised as distorted. Evidence of bilateral arm positioning impairments in unilateral arm CRPS suggests that central mechanisms are involved. Cortical reorganisation in regions associated with the body schema (i.e. primary somatosensory and parietal cortices) is proposed as an explanation. The exact relationship between pain and limb position deficits requires further exploration.

Upper limb posture and submaximal hand tasks influence shoulder muscle activity

The aim of this study was to investigate the effects of a light hand tool exertion task on shoulder muscle activation during different postures of shoulder flexion and humeral rotation. The use of hand tools is linked with many cumulative trauma disorders of the upper extremity ( Chaffin et al., 2006). Generally, there was an increase in muscle activity as the degree of shoulder flexion increased. Pectoralis major and inferior trapezius emerged as major contributors in internal and external rotation, respectively. Generally, the inferior trapezius reached greater levels of activation than the other eight recorded shoulder muscles, and exceeded suggested activation recommendations ( Jonsson, 1978). Common industry and ergonomic guidelines suggest a general posture of reduced shoulder flexion and neutral humeral rotation. Our results suggest that in order to reduce risky levels of inferior trapezius activation, light hand tool tasks (such as drilling) should be performed at neutral elevation and −45° internal rotation, or for slightly higher activations (but still low risk) at 60° shoulder flexion and −45° internal rotation. Relevance to industry Identification of muscle activation patterns with respect to posture and hand forces during light hand tool tasks helps establish work layout geometries in job design, and will provide the worker increased work endurance with lower risk exposures during task performance.

3D Measurement of Forearm and Upper Arm during Throwing Motion using Body Mounted Sensor

The aim of this study is to propose the measurement method of three-dimensional (3D) movement of forearm and upper arm during pitching motion of baseball using inertial sensors without serious consideration of sensor installation. Although high accuracy measurement of sports motion is achieved by using optical motion capture system at present, it has some disadvantages such as the calibration of cameras and limitation of measurement place. Whereas the proposed method for 3D measurement of pitching motion using body mounted sensors provides trajectory and orientation of upper arm by the integration of acceleration and angular velocity measured on upper limb. The trajectory of forearm is derived so that the elbow joint axis of forearm corresponds to that of upper arm. Spatial relation between upper limb and sensor system is obtained by performing predetermined movements of upper limb and utilizing angular velocity and gravitational acceleration. The integration error is modified so that the estimated final position, velocity and posture of upper limb agree with the actual ones. The experimental results of the measurement of pitching motion show that trajectories of shoulder, elbow and wrist estimated by the proposed method are highly correlated to those from the motion capture system within the estimation error of about 10 [%].

Effects of combined wrist flexion/extension and forearm rotation and two levels of relative force on discomfort

This study investigated perceived discomfort in an isometric wrist flexion task. Independent variables were wrist flexion/extension (55%, 35% flexion, neutral, 35% and 55% extension ranges of motion (ROM)), forearm rotation (60%, 30% prone, neutral, 30% and 60% supine ROM) and two levels of flexion force (10% and 20% maximum voluntary contraction (MVC)). Discomfort was significantly affected by flexion force, forearm rotation and a two-way interaction of force with forearm rotation (each p < 0.05). High force for 60%ROM forearm pronation and supination resulted in increasingly higher discomfort for these combinations. Flexion forces were set relative to the MVC in each wrist posture and this appears to be important in explaining a lack of significant effect (p = 0.34) for flexion/extension on discomfort. Regression equations predicting discomfort were developed and used to generate iso-discomfort contours, which indicate regions where the risk of injury should be low and others where it is likely to be high. Regression equations predicting discomfort and iso-discomfort contours are presented, which indicate combinations of upper limb postures for which discomfort is predicted to be low, and others where it is likely to be high. These are helpful in the study of limits for risk factors associated with upper limb musculoskeletal injury in industry.

Sensor Evaluation for Wearable Strain Gauges in Neurological Rehabilitation

Conductive elastomers are a novel strain sensing technology which can be unobtrusively embedded into a garment's fabric, allowing a new type of sensorized cloths for motion analysis. A possible application for this technology is remote monitoring and control of motor rehabilitation exercises. The present work describes a sensorized shirt for upper limb posture recognition. Supervised learning techniques have been employed to compare classification models for the analysis of strains, simultaneously measured at multiple points of the shirt. The instantaneous position of the limb was classified into a finite set of predefined postures, and the movement was decomposed in an ordered sequence of discrete states. The amount of information given by the observation of each sensor during the execution of a specific exercise was quantitatively estimated by computing the information gain for each sensor, which in turn allows the data-driven optimization of the garment. Real-time feedback on exercise progress can also be provided by reconstructing the sequence of consecutive positions assumed by the limb.

An Examination of Shoulder Postures and Moments of Force Among Different Skill Levels in the Wool Harvesting Industry

The wool harvesting industry employs workers of varying skill levels that differ in both quality and number of harvested fleeces. As it was unknown how skill affected parameters such as joint posture and loading, the current study comparatively examined 140 wool harvesting workers representing 4 skill levels during wool harvesting competitions. Three-dimensional upper limb postures and peak and cumulative shoulder moments were calculated for each worker. Results indicated that elite wool harvesters, in general, used different shoulder postures to perform the harvesting tasks and were thus exposed to different shoulder moments as compared to the lower skill levels. It is plausible that these adopted postures allow the higher class workers to perform their job with higher quality and greater speed as compared to the lower ranked workers. Postural-based training may help improve technique in lower ranked workers and enable these workers to achieve higher ranked status.

Reliability of assessing upper limb postures among workers performing manufacturing tasks

The purpose of this study was to determine the inter- and intra-rater reliability of assessing upper limb postures of workers performing manufacturing tasks. Assessment of neck, shoulder, and wrist postures of 20 manufacturing employees was conducted by two raters observing digital video files using Multimedia Video Task Analysis (MVTA). Generalizability theory was used to estimate the inter- and intra-rater reliability. The results demonstrated good to excellent inter-rater reliability for neck and shoulder postures and fair to excellent inter-rater reliability for wrist postures. Intra-rater posture assessment demonstrated good to excellent reliability for both raters in all postures of the neck, shoulder, and wrist. This study demonstrated that posture assessment of manufacturing workers using MVTA is a reliable method.

Position sense asymmetry

Asymmetries in upper limb position sense have been explained in the context of a left limb advantage derived from differences in hemispheric specialization in the processing of kinesthetic information. However, it is not clearly understood how the comparison of perceptual information associated with passive limb displacement and the corresponding matching movement resulting from the execution of a motor command contributes to these differences. In the present study, upper limb position sense was investigated in 12 right-hand-dominant young adults performing wrist position matching tasks which varied in terms of interhemispheric transfer, memory retrieval and whether the reference position was provided by the same or opposite limb. Right and left hand absolute matching errors were similar when the reference and matching positions were produced by the same hand but were 36% greater when matching the reference position with the opposite hand. When examining the constant errors generated from matching movements made with the same hand that provided the reference, the right and left hand matching errors (approximately 3 degrees) were similar. However, when matching with the opposite limb, a large overshoot (P < 0.05) characterized the error when the right hand matched the left hand reference while a large undershoot (P < 0.05) characterized the error when the left hand matched the right hand reference. The overshoot and undershoot were of similar magnitude (approximately 4 degrees). Although asymmetries in the central processing of proprioceptive information such as interhemispheric transfer may exist, the present study suggests that asymmetries in position sense predominantly result from a difference in the "gain of the respective proprioceptive sensory-motor loops". This new hypothesis is strongly supported by a dual-linear model representing the right and left hand sensory-motor systems as well as morphological and physiological data.

4. Effect of changes in pre-movement upper limb position on the anticipatory postural adjustment in the lower leg muscles in humans

4. Effect of changes in pre-movement upper limb position on the anticipatory postural adjustment in the lower leg muscles in humans

The effect of forearm support on children’s head, neck and upper limb posture and muscle activity during computer use

Use of computers by children has increased rapidly, however few studies have addressed factors which may reduce musculoskeletal stress during computer use by children. This study quantified the postural and muscle activity effects of providing forearm support when children used computers. Twelve male and 12 female children (10–12 years) who regularly used computers were recruited. Activities were completed using a computer with two workstation configurations, one of which provided for forearm support on the desk surface. 3D posture was analysed using an infra-red motion analysis system. Surface EMG was collected from five muscle groups in the neck/shoulder region and right upper limb. Providing a support surface resulted in more elevated and flexed upper limbs. The use of forearm or wrist support was associated with reduced muscle activity for most muscle groups. Muscle activity reductions with support were of sufficient magnitude to be clinically meaningful. The provision of a supporting surface for the arm is therefore likely to be useful for reducing musculoskeletal stresses associated with computing tasks for children.

A reinforcement learning based neural network architecture for obstacle avoidance in multi-fingered grasp synthesis

The ability to learn from interaction with the exterior world as well as variability are two main features of living organisms. The aim of this study is to present and discuss the property of a stochastic reinforcement learning based model of upper limb posture generation that exhibits both properties. The capacity of the model to discover suitable postures satisfying task and obstacle avoidance constraints is demonstrated by simulation. Also, task equivalent configurations that can be linked to recent findings in the motor control literature are generated by the proposed formalism due to its stochastic nature.

Estimation of Evaluation Function for Generating Upper Limb Posture during Task Execution

Generating the upper limb posture of a human arm is important when executing tasks involving position and force control. In this article, we derive the evaluation function to generate the upper limb posture of a human arm when connecting an RCA plug. We measure the upper limb posture of one subject, while connecting the plug, to determine factors in the evaluation function and of eight more subjects on different positional plugs, to estimate the factor values. Based from the experimental results, the evaluation function can be expressed as a weighted linear sum of nine factors such as power transmissibility of joints, torque, and manipulability measure of joints. It was shown that the generated upper limb posture is close enough to the measured posture. The most important constituent factors of the evaluation function are found to be manipulability measure of both elbow and wrist, and the wrist torque.

Pursuit Eye Movements Involve a Covert Motor Plan for Manual Tracking

When we make an aiming movement toward a moving visual object, eye-hand coupling is of paramount importance for accurate motor performance. Some studies have suggested that both gaze and manual tracking control systems are driven by a common command signal. However, it has never been demonstrated that a motor plan for the arm is produced even when the object is tracked by the eyes alone. By applying transcranial magnetic stimulation to the motor cortex, we show for the first time that ocular tracking is linked to an overall decrease in the excitability of the motor control system of the relaxed upper limb, as estimated from the amplitude of the motor evoked potentials recorded in contralateral hand and wrist muscles. Furthermore, this reduced excitability is modulated in a manner compatible with a subthreshold neural activation encoding a manual tracking response to the same target pursued by the eyes. In addition, excitability changes are contingent on upper-limb posture, because they are present only with a pronated forearm and not with a supinated hand position. We provide direct evidence that, if the arm is held in a congruent postural configuration, tracking a moving object always entails a coordinated motor plan, which involves both gaze and hand movements. Active inhibitory mechanisms are activated to prevent an overt arm movement, whenever a manual tracking is not requested. Our data provide strong evidence in favor of the existence of a common drive to both eye and hand tracking systems.

Vigabatrin improves paroxysmal dystonia in succinic semialdehyde dehydrogenase deficiency

Succinic semialdehyde dehydrogenase (SSADH; E.C. 1.2.1.24) deficiency (MIM#271980) is a rare defect of the gamma-aminobutyric acid (GABA) catabolic pathway, resulting in 4-hydroxybutyric acid (GHB) accumulation.1 We report the occurrence of an unusual paroxysmal movement disorder in two affected siblings born of healthy nonconsanguineous Italian parents. This 18-year-old boy presented during childhood with autism, motor stereotypies (trunk swinging), hyperactivity, clumsiness, and hypotonia. Generalized epilepsy manifested at age 7 years, and sleep disorder (compulsive limb movements) manifested at age 10 years. Starting from age 15 years, he had a transient discomfort in the lower limbs while walking. On examination at age 16 years, he presented severe mental retardation, dysarthria, motor stereotypies (chaotic gesticulation, trunk swinging), mild dystonic postures of upper limbs, and paroxysmal exercise-induced dystonia (PED). PED emerged after approximately 100 steps as large amplitude abductor movements of the legs, gait freezing, frightful expression, and occasionally, falling (video E-1 on the Neurology Web site at www.neurology.org); he was able to walk again after resting 5 to …

The impact of computer display height and desk design on 3D posture during information technology work by young adults

Computer display height and desk design to allow forearm support are two critical design features of workstations for information technology tasks. However there is currently no 3D description of head and neck posture with different computer display heights and no direct comparison to paper based information technology tasks. There is also inconsistent evidence on the effect of forearm support on posture and no evidence on whether these features interact. This study compared the 3D head, neck and upper limb postures of 18 male and 18 female young adults whilst working with different display and desk design conditions. There was no substantial interaction between display height and desk design. Lower display heights increased head and neck flexion with more spinal asymmetry when working with paper. The curved desk, designed to provide forearm support, increased scapula elevation/protraction and shoulder flexion/abduction.