Your search keyword '"Roberto Sanchis"' showing total 5 results

1. Effect of Hamstring Tightness and Fatigue on Dynamic Stability and Agility in Physically Active Young Men

Author

Alberto Encarnación-Martínez, Antonio García-Gallart, Pedro Pérez-Soriano, Ignacio Catalá-Vilaplana, Julia Rizo-Albero, and Roberto Sanchis-Sanchis

Subjects

hamstring shortening, flexibility, one-leg balance, landing, Chemical technology, TP1-1185

Abstract

Hamstring extensibility has been defined as a factor to diminished dynamic stability and therefore increased risk of injury. The purpose of this study was to analyse the effects of hamstring tightness and fatigue on dynamic stability and agility. Nineteen participants were divided between the normal extensibility group (NEG) (n = 9, 82.2° ± 12.4°) and hamstrings tightness group (HTG) (n = 10, 64° ± 4.9°) using the passive straight leg raise test. To analyse dynamic stability and agility, they performed the modified Star Excursion Balance Test (mSEBT) and Dynamic Postural Stability Index (DPSI), and hexagon agility test, respectively, before and after a fatigue protocol. A two-way repeated measures ANOVA was used to determine differences among conditions: NEG vs. HTG, and rested vs. fatigued. HTG showed a significantly lower reach in the anterior direction in the mSEBT in pre- and post-fatigue than NEG. Participants in the NEG showed poor stability after landing in the mediolateral direction on DPSI post-fatigue. No significant changes were found in agility related with the group nor fatigue state. Participants with hamstring extensibility reduction has no differences in dynamic stability after landing nor agility after fatigue test, but significantly affects reaching distances during one-leg balance. As a conclusion, a reduction in range of motion in HTG was observed, but no other effects were observed on performance and dynamic stability after a local fatigue protocol depending on hamstring extensibility.

Published

2023

2. Effects of Central and Peripheral Fatigue on Impact Characteristics during Running

Author

Alberto Encarnación-Martínez, Antonio García-Gallart, Roberto Sanchis-Sanchis, and Pedro Pérez-Soriano

Subjects

impacts, peripheral, central, fatigue, running, Chemical technology, TP1-1185

Abstract

Fatigue and impact can represent an injury risk factor during running. The objective of this study was to compare the impact transmission along the locomotor system between the central and peripheral fatigued states during running. Tibial and head acceleration as well as shock attenuation in the time- and frequency-domain were analyzed during 2-min of treadmill running in the pre- and post-fatigue state in eighteen male popular runners (N = 18). The impact transmission was measured before and after a 30-min central fatigue protocol on the treadmill or a peripheral fatigue protocol in the quadricep and hamstring muscles using an isokinetic dynamometer. The time-domain acceleration variables were not modified either by peripheral or central fatigue (p > 0.05). Nevertheless, central fatigue increased the maximum (p = 0.006) and total (p = 0.007) signal power magnitude in the high-frequency range in the tibia, and the attenuation variable in the low- (p = 0.048) and high-frequency area (p = 0.000), while peripheral fatigue did not cause any modifications in the frequency-domain variables (p > 0.05). Furthermore, the attenuation in the low (p = 0.000)- and high-frequency area was higher with central fatigue than peripheral fatigue (p = 0.003). The results demonstrate that central fatigue increases the severity of impact during running as well as the attenuation of low and high components.

Published

2022

3. Higher Hamstrings Strength and Stability Are Related to Lower Kinematics Alteration during Running after Central and Peripheral Fatigue

Author

Alberto Encarnación-Martínez, Antonio García-Gallart, Roberto Sanchis-Sanchis, Irene Jimenez-Perez, Jose I. Priego-Quesada, and Pedro Pérez-Soriano

Subjects

running, fatigue, strength, stability, kinematics, Chemical technology, TP1-1185

Abstract

Fatigue can be classified as peripheral or central depending on the extent of its effects. Muscle strength reduction, associated with the appearance of fatigue during running, produces kinetics and kinematics modifications which could lead to an increased risk of injury. This study aimed to analyze the effect of peripheral and central fatigue protocols in running kinematics and to investigate the relationship between isokinetic strength and dynamic stability in fatigue related changes. Eighteen male recreational runners participated in the study. The dynamic postural stability index (DPSI) and quadriceps and hamstring isokinetic strength were assessed before the fatigue test. Then, angular kinematics during treadmill running were evaluated in pre- and post-fatigue states (central and peripheral). The results showed that runners with higher hamstring isokinetic strength and better DPSI had lower modifications after central fatigue of stance time, knee flexion, vertical and leg stiffness, and ankle dorsiflexion during the absorption and propulsion phases (r > 0.400, p < 0.05). Moreover, small changes in ankle dorsiflexion at initial contact after peripheral fatigue are related to a better DPSI and higher hamstring isokinetic strength (r > 0.400, p < 0.05). In summary, high values of hamstring isokinetic concentric strength and dynamic stability are related to lower increases of range of movements during running after central and peripheral fatigue. So, fatigue may affect to a lesser extent the running technique of those runners with higher hamstring strength and stability values.

Published

2022

4. Validity and Reliability of an Instrumented Treadmill with an Accelerometry System for Assessment of Spatio-Temporal Parameters and Impact Transmission

Author

Alberto Encarnación-Martínez, Pedro Pérez-Soriano, Roberto Sanchis-Sanchis, Antonio García-Gallart, and Rafael Berenguer-Vidal

Subjects

impact acceleration, spatio-temporal, instrumented treadmill, running, retraining, Chemical technology, TP1-1185

Abstract

Running retraining programs focused on concurrent feedback of acceleration impacts have been demonstrated to be a good strategy to reduce running-related injuries (RRI), as well as to improve running economy and reduce acceleration impacts and injury running incidence. Traditionally, impacts have been registered by mean of accelerometers attached directly to the athletes, which is inaccessible to the entire population, because it requires laboratory conditions. This study investigated the validity and reliability of a new device integrated directly into the treadmill, compared to a traditional acceleration impact system. Thirty healthy athletes with no history of RRI were tested on two separate days over the instrumented treadmill (AccTrea) and simultaneously with an acceleration impact system attached to the participant (AccAthl). AccTrea was demonstrated to be a valid and reliable tool for measuring spatio-temporal parameters like step length (validity intraclass correlation coefficient (ICC) = 0.94; reliability ICC = 0.92), step time (validity ICC = 0.95; reliability ICC = 0.96), and step frequency (validity ICC = 0.95; reliability ICC = 0.96) during running. Peak acceleration impact variables showed a high reliability for the left (reliability ICC = 0.88) and right leg (reliability ICC = 0.85), and peak impact asymmetry showed a modest validity (ICC = 0.55). These results indicated that the AccTrea system is a valid and reliable way to assess spatio-temporal variables, and a reliable tool for measuring acceleration impacts during running.

Published

2021

5. Validity and Reliability of an Instrumented Treadmill with an Accelerometry System for Assessment of Spatio-Temporal Parameters and Impact Transmission

Author

Roberto Sanchis-Sanchis, Pedro Pérez-Soriano, Alberto Encarnación-Martínez, Antonio García-Gallart, Rafael Berenguer-Vidal, Universidad de Alicante. Departamento de Didáctica General y Didácticas Específicas, and Research in Physical Education, Fitness and Performance (RIPEFAP)

Subjects

medicine.medical_specialty, Didáctica de la Expresión Corporal, Computer science, Acceleration, Validity, Instrumented treadmill, Accelerometer, lcsh:Chemical technology, Biochemistry, Article, Analytical Chemistry, Running, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Accelerometry, medicine, running, Humans, lcsh:TP1-1185, Electrical and Electronic Engineering, Treadmill, Gait, Instrumentation, Reliability (statistics), Impact acceleration, spatio-temporal, instrumented treadmill, Retraining, Reproducibility of Results, retraining, 030229 sport sciences, Atomic and Molecular Physics, and Optics, impact acceleration, Transmission (telecommunications), Exercise Test, Running economy, Spatio-temporal, 030217 neurology & neurosurgery

Abstract

Running retraining programs focused on concurrent feedback of acceleration impacts have been demonstrated to be a good strategy to reduce running-related injuries (RRI), as well as to improve running economy and reduce acceleration impacts and injury running incidence. Traditionally, impacts have been registered by mean of accelerometers attached directly to the athletes, which is inaccessible to the entire population, because it requires laboratory conditions. This study investigated the validity and reliability of a new device integrated directly into the treadmill, compared to a traditional acceleration impact system. Thirty healthy athletes with no history of RRI were tested on two separate days over the instrumented treadmill (AccTrea) and simultaneously with an acceleration impact system attached to the participant (AccAthl). AccTrea was demonstrated to be a valid and reliable tool for measuring spatio-temporal parameters like step length (validity intraclass correlation coefficient (ICC) = 0.94, reliability ICC = 0.92), step time (validity ICC = 0.95, reliability ICC = 0.96), and step frequency (validity ICC = 0.95, reliability ICC = 0.96) during running. Peak acceleration impact variables showed a high reliability for the left (reliability ICC = 0.88) and right leg (reliability ICC = 0.85), and peak impact asymmetry showed a modest validity (ICC = 0.55). These results indicated that the AccTrea system is a valid and reliable way to assess spatio-temporal variables, and a reliable tool for measuring acceleration impacts during running.

Published

2021