Alberito Rodrigo de Carvalho scite author profile

We compare the effects of Nordic walking training (NW) and Free walk (FW) on functional parameters (motor symptoms, balance) and functional mobility (Timed Up and Go at Self-selected Speed - TUGSS, and at forced speed, TUGFS; Self-selected Walking Speed, SSW; locomotor rehabilitation index, LRI) of Parkinson's disease (PD) patients. The study included 33 patients with clinical diagnosis of idiopathic PD, and staging between 1 and 4 in the Hoehn and Yahr scale (H&Y) randomized into two groups: NW (N = 16) and FW (N = 17) for 6 weeks. Baseline characteristics were compared trough a one-way ANOVA. Outcomes were analyzed using the Generalized Estimation Equations (GEE) with a Bonferroni post-hoc. Data were analyzed using SPSS v.20.0. Improvements in UPDRS III (P < 0.001), balance scores (P < 0.035), TUGSS distance (P < 0.001), TUGFS distance (P < 0.001), SSW (P < 0.001), and LRI (P < 0.001) were found for both groups. However, the NW group showed significant differences (P < 0.001) when compared to the FW group for the functional mobility. We conclude the NW improves functional parameters and walking mobility demonstrating that NW is as effective as the FW, including benefits for FW on the functional mobility of people with PD.

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Landing-Takeoff Asymmetries Applied to Running Mechanics: A New Perspective for Performance

Rosa

Oliveira

Gomeñuka

et al. 2019

Front. Physiol.

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Background: Elastic bouncing is a physio-mechanical model that can elucidate running behavior in different situations, including landing and takeoff patterns and the characteristics of the muscle-tendon units during stretch and recoil in running. An increase in running speed improves the body’s elastic mechanisms. Although some measures of elastic bouncing are usually carried out, a general description of the elastic mechanism has not been explored in running performance. This study aimed to compare elastic bouncing parameters between the higher- and lower-performing athletes in a 3000 m test. Methods: Thirty-eight endurance runners (men) were divided into two groups based on 3000 m performance: the high-performance group (P high ; n = 19; age: 29 ± 5 years; mass: 72.9 ± 10 kg; stature: 177 ± 8 cm; 3000 time : 656 ± 32 s) and the low-performance group (P low ; n = 19; age: 32 ± 6 years; mass: 73.9 ± 7 kg; stature: 175 ± 5 cm; 3000 time : 751 ± 29 s). They performed three tests on different days: (i) 3000 m on a track; (ii) incremental running test; and (iii) a running biomechanical test on a treadmill at 13 different speeds from 8 to 20 km h −1 . Performance was evaluated using the race time of the 3000 m test. The biomechanics variables included effective contact time ( t ce ), aerial time ( t ae ), positive work time ( t push ), negative work time ( t break ), step frequency ( f step ), and elastic system frequency ( f sist ), vertical displacement ( S v ) in t ce and t ae ( S ce and S ae ), vertical force, and vertical stiffness were evaluated in a biomechanical submaximal test on treadmill. Results: The t ae , f sist , vertical force and stiffness were higher ( p < 0.05) and t ce and f step were lower ( p < 0.05) in P high , with no differences between groups in t push and t break . Conclusion: The elastic bouncing was optimized in runners of the best performance level, demonstrating a better use of elastic components.

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Neural mobilization and static stretching in an experimental sciatica model: an experimental study

Bertolini¹,

Silva²,

Mol³

et al. 2009

Rev. bras. fisioter.

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Nordic walking training in elderly, a randomized clinical trial. Part II: Biomechanical and metabolic adaptations

et al. 2020

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Background: Nordic walking is an attractive method of endurance training. Nevertheless, the biomechanic response due to the additional contribution of using poles in relation to free walking training has been less explored in the elderly. Purpose: This randomized parallel controlled trial aimed to assess the effects of 8 weeks of Nordic walking and free walking training on the walking economy, mechanical work, metabolically optimal speed, and electromyographic activation in elderly. Methods: Thirty-three sedentary elderly were randomized into Nordic walking (n = 16) and free walking group (n = 17) with equalized loads. Submaximal walking tests were performed from 1 to 5 km h −1 on the treadmill.Results: Walking economy was improved in both free and Nordic walking groups (x 2 4.91, p = 0.014) and the metabolically optimal speed was increased by approximately 0.5 km h −1 changing the speed-cost profile. The electromyographic activation in lower and upper limbs, pendular recovery, and total, external, and internal mechanical work remained unchanged (p > 0.05). Interestingly, the internal mechanical work associated with arm movement was higher in the Nordic walking group than in the free walking group after training, while the co-contraction from upper limb muscles was reduced similarly to both groups.Conclusions: Eight weeks of Nordic walking training effectively improved the walking economy and functionality as well as maintained the gait mechanics, similar to free walking training in elderly people. This enhancement in the metabolic economy may have been mediated by a reduction in the co-contraction from upper limb muscles. Trial registration: ClinicalTrails.gov NCT03096964

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