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- Blomgren, Johannes, et al.
(författare)
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Effects of deep cervical flexor training on impaired physiological functions associated with chronic neck pain: a systematic review
- 2018
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Ingår i: BMC Musculoskeletal Disorders. - London : BMC. - 1471-2474. ; 19
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Tidskriftsartikel (refereegranskat)abstract
- Background:Neck pain is a major health issue with high rates of recurrence. It presents with a variety ofaltered sensorimotor functions. Exercise is a cornerstone of rehabilitation and many training methods areused. Exercise is evaluated in most randomized controlled trials on its pain relieving effects. No review hasassessed the effect of exercise on the altered physiological functions or determined if there are differentialeffects of particular training methods. This review investigated the effects of deep cervical flexor (DCF)training, a training method commonly used for patients with neck pain, and compared it to other trainingmethodsornotrainingonoutcomesofcervicalneuromuscular function, muscle size, kinematics and kinetics.Methods:Web of Science, Scopus, CINAHL, PubMed were searched from inception until January 2018. Twelverandomized controlled trials were included that compared DCF training as sole intervention to other trainingor no interventions in persons with neck pain. The Cochrane Risk of Bias tool was used to assess the methodquality. All outcome measures were analysed descriptively and meta-analyses were performed for measuresevaluated in three or more studies.Results:DCF training was compared to cervical endurance, strength, proprioception and mobility training,muscle stretching, and no intervention control groups. Physiological outcome measures includedneuromuscular co-ordination (craniocervical flexion test), functional tasks, muscle fatigability, muscle size,kinematics (joint position sense, posture and range of motion) and kinetics (strength, endurance andcontraction accuracy). Strong evidence was found for effectiveness of DCF training on neuromuscularcoordination, but it had no or small effects on strength and endurance at higher loads. DCF trainingimproved head and cervical posture, while evidence was limited or contradictory for other measures.Conclusions:DCF training can successfully address impaired neuromuscular coordination, but not cervicalflexor strength and endurance at higher contraction intensities. A multimodal training regime is proposedwhen the aim is to specifically address various impaired physiological functions associated with neck pain
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- Clark, Nicholas C., et al.
(författare)
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Proprioception in Musculoskeletal Rehabilitation : Part 2: Clinical Assessment and Intervention
- 2015
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Ingår i: Manual Therapy. - : Elsevier BV. - 1356-689X .- 1532-2769. ; 20:3, s. 378-387
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Tidskriftsartikel (refereegranskat)abstract
- IntroductionProprioception can be impaired in gradual-onset musculoskeletal pain disorders and following trauma. Understanding of the role of proprioception in sensorimotor dysfunction and methods for assessment and interventions is of vital importance in musculoskeletal rehabilitation. In Part 1 of this two-part Masterclass we presented a theory-based overview of the role of proprioception in sensorimotor control, causes and findings of altered proprioception in musculoskeletal conditions, and general principles of assessment and interventions.PurposeThe aim of this second part is to present specific methods for clinical assessment and interventions to improve proprioception in the spine and extremities.ImplicationsClinical assessment of proprioception can be performed using goniometers, inclinometers, laser-pointers, and pressure sensors. Manual therapy, taping, and bracing can immediately enhance proprioception and should be used to prepare for exercise interventions. Various types of exercise (active joint repositioning, force sense, co-ordination, muscle performance, balance/unstable surface, plyometric, and vibration training) should be employed for long-term enhancement of proprioception.
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- Falk, Jimmy, et al.
(författare)
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Increased co-contraction reaction during a surface perturbation is associated with unsuccessful postural control among older adults
- 2022
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Ingår i: BMC Geriatrics. - : Springer Nature. - 1471-2318 .- 1471-2318. ; 22:1
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Tidskriftsartikel (refereegranskat)abstract
- Background: As a strategy to maintain postural control, the stiffening strategy (agonist-antagonist co-contractions) is often considered dysfunctional and associated with poor physical capacity. The aim was to investigate whether increased stiffening is associated with unsuccessful postural control during an unpredictable surface perturbation, and which sensory and motor variables that explain postural stiffening.Methods: A sample of 34 older adults, 75.8 ± 3.8 years, was subjected to an unpredicted surface perturbation with the postural task to keep a feet-in-place strategy. The participants also completed a thorough sensory- and motor test protocol. During the surface perturbation, electromyography was measured from tibialis anterior and gastrocnemius to further calculate a co-contraction index during the feed-forward and feedback period. A binary logistic regression was done with the nominal variable, if the participant succeeded in the postural task or not, set as dependent variable and the co-contraction indexes set as independent variables. Further, the variables from the sensory and motor testing were set as independent variables in two separate Orthogonal Projections of Latent Structures (OPLS)-models, one with the feed-forward- and the other with the feedback co-contraction index as dependent variable.Results: Higher levels of ankle joint stiffening during the feedback, but not the feed-forward period was associated with postural task failure. Feedback stiffening was explained by having slow non-postural reaction times, poor leg muscle strength and being female whereas feed-forward stiffening was not explained by sensory and motor variables.Conclusions: When subjected to an unpredicted surface perturbation, individuals with higher feedback stiffening had poorer postural control outcome, which was explained by poorer physical capacity. The level of feed-forward stiffening prior the perturbation was not associated with postural control outcome nor the investigated sensory and motor variables. The intricate causal relationships between physical capacity, stiffening and postural task success remains subject for future research.
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- Falk, Jimmy, et al.
(författare)
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What Explains Successful or Unsuccessful Postural Adaptations to Repeated Surface Perturbations among Older Adults?
- 2021
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Ingår i: International Journal of Environmental Research and Public Health. - : MDPI. - 1661-7827 .- 1660-4601. ; 18:22
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Tidskriftsartikel (refereegranskat)abstract
- As we age there are natural physiological deteriorations that decrease the accuracy and flexibility of the postural control system, which increases the risk of falling. Studies have found that there are individual differences in the ability to learn to manage repeated postural threats. The aim of this study was to investigate which factors explain why some individuals are less proficient at adapting to recurrent postural perturbations. Thirty-five community dwelling older adults performed substantial sensory and motor testing and answered surveys regarding fall-related concerns and cognitive function. They were also subjected to three identical surface perturbations where both kinematics and electromyography was captured. Those that were able to adapt to the third perturbation were assigned to the group “Non-fallers” whereas those that fell during all perturbations were assigned to the group “Fallers”. The group designation dichotomized the sample in a hierarchical orthogonal projection of latent structures— the discriminant analysis model. We found that those who fell were older, had poorer physical performance, poorer strength and longer reaction times. The Fallers’ postural control strategies were more reliant on the stiffening strategy along with a more extended posture and they were less skillful at making appropriate feedforward adaptations prior to the third perturbation.
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- Forsberg, Karin, et al.
(författare)
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Concurrent Validity of Cervical Movement Tests Using VR Technology—Taking the Lab to the Clinic
- 2023
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Ingår i: Sensors. - : MDPI. - 1424-8220. ; 23:24
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Tidskriftsartikel (refereegranskat)abstract
- Reduced cervical range of motion (ROM) and movement velocity are often seen in people with neck pain. Objective assessment of movement characteristics is important to identify dysfunction, to inform tailored interventions, and for the evaluation of the treatment effect. The purpose of this study was to investigate the concurrent validity of a newly developed VR technology for the assessment of cervical ROM and movement velocity. VR technology was compared against a gold-standard three-dimensional optical motion capture system. Consequently, 20 people, 13 without and 7 with neck pain, participated in this quantitative cross-sectional study. ROM was assessed according to right/left rotation, flexion, extension, right/left lateral flexion, and four diagonal directions. Velocity was assessed according to fast cervical rotation to the right and left. The correlations between VR and the optical system for cervical ROM and velocity were excellent, with intraclass correlation coefficient (ICC) values > 0.95. The mean biases between VR and the optical system were ≤ 2.1° for the ROM variables, <12°/s for maximum velocity, and ≤3.0°/s for mean velocity. In conclusion, VR is a useful assessment device for ROM and velocity measurements with clinically acceptable biases. It is a feasible tool for the objective measurement of cervical kinematics in the clinic.
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- Jafari, Hedyeh, et al.
(författare)
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A novel data driven model of ageing postural control
- 2019
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Konferensbidrag (refereegranskat)abstract
- BackgroundPostural control is a complex system. Based on sensorimotor integration, the central nervous system (CNS) maintains balance by sending suitable motor commands to the muscles. Physiological decline due to ageing, affects balance performance through failing postural control – and in turn affects falls self-efficacy and activity participation. Understanding how the CNS adapts to these changes and predicts the appropriate motor commands to stabilize the body, has been a challenge for postural control research the latest years.AimsTo understand and model the performance of the central nervous system as the controller of the human body.MethodsModelling was based on postural control data from 45 older adults (70 years and older). Ankle, knee and hip joint kinematics were measured during quiet stance using a motion capture system. Principal component analysis was used in order to reduce the measured multidimensional kinematics from a set of correlated discrete time series to a set of principal components. The outcome was utilized to predict the motor commands. The adaptive behaviour of the CNS was modelled by recurrent neural network including the efference copy for rapid predictions. The data from joint kinematics and electromyography (EMG) signals of the lower limb muscles were measured and separated into training and test data sets.ResultsThe model can predict postural motor commands with very high accuracy regardless of a large physiological variability or balancing strategies. This model has three characteristics: a) presents an adaptive scheme to individual variability, 2) showcases the existence of an efference copy, and 3) is human experimental data driven.ConclusionThe model can adapt to physical body characteristics and individual differences in balancing behaviour, while successfully predict motor commands. It should therefore be utilised in the continued pursuit of a better understanding of ageing postural control.
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