Your search keyword '"Ikuta, Ryohei"' showing total 7 results

1. Sex difference in frontal plane hip moment in response to lateral trunk obliquity during single-leg landing

Author

Taniguchi, Shohei, Ishida, Tomoya, Yamanaka, Masanori, Ueno, Ryo, Ikuta, Ryohei, Chijimatsu, Masato, Samukawa, Mina, Koshino, Yuta, Kasahara, Satoshi, and Tohyama, Harukazu

Published

2022

2. Subsequent Jumping Increases the Knee and Hip Abduction Moment, Trunk Lateral Tilt, and Trunk Rotation Motion During Single-Leg Landing in Female Individuals.

Author

Chijimatsu, Masato, Ishida, Tomoya, Yamanaka, Masanori, Taniguchi, Shohei, Ueno, Ryo, Ikuta, Ryohei, Samukawa, Mina, Ino, Takumi, Kasahara, Satoshi, and Tohyama, Harukazu

Subjects

ANTERIOR cruciate ligament injury prevention, TORSO physiology, HIP joint physiology, KNEE joint, STATISTICS, MANN Whitney U Test, REGRESSION analysis, T-test (Statistics), ABDUCTION (Kinesiology), PSYCHOLOGY of women, DESCRIPTIVE statistics, BIOMECHANICS, JUMPING, MOTION capture (Human mechanics), DATA analysis software, KINEMATICS

Abstract

Single-leg landings with or without subsequent jumping are frequently used to evaluate landing biomechanics. The purpose of this study was to investigate the effects of subsequent jumping on the external knee abduction moment and trunk and hip biomechanics during single-leg landing. Thirty young adult female participants performed a single-leg drop vertical jumping (SDVJ; landing with subsequent jumping) and single-leg drop landing (SDL; landing without subsequent jumping). Trunk, hip, and knee biomechanics were evaluated using a 3-dimensional motion analysis system. The peak knee abduction moment was significantly larger during SDVJ than during SDL (SDVJ 0.08 [0.10] N·m·kg−1·m−1, SDL 0.05 [0.10] N·m·kg−1·m−1, P =.002). The trunk lateral tilt and rotation angles toward the support-leg side and external hip abduction moment were significantly larger during SDVJ than during SDL (P <.05). The difference in the peak hip abduction moment between SDVJ and SDL predicted the difference in the peak knee abduction moment (P =.003, R2 =.252). Landing tasks with subsequent jumping would have advantages for evaluating trunk and hip control as well as knee abduction moment. In particular, evaluating hip abduction moment may be important because of its association with the knee abduction moment. [ABSTRACT FROM AUTHOR]

Published

2023

3. Landing instructions focused on pelvic and trunk lateral tilt decrease the knee abduction moment during a single-leg drop vertical jump

Author

Chijimatsu, Masato, Ishida, Tomoya, Yamanaka, Masanori, Taniguchi, Shohei, Ueno, Ryo, Ikuta, Ryohei, Samukawa, Mina, Ino, Takumi, Kasahara, Satoshi, and Tohyama, Harukazu

Published

2020

4. Landing Biomechanics During a Single-leg Landing With Lateral Trunk Obliquity in Female Athletes

Author

Taniguchi, Shohei, primary, Ishida, Tomoya, additional, Yamanaka, Masanori, additional, Ueno, Ryo, additional, Ikuta, Ryohei, additional, Chijimatsu, Masato, additional, Samukawa, Mina, additional, Koshino, Yuta, additional, Kasahara, Satoshi, additional, and Tohyama, Harukazu, additional

Published

2021

5. Quadriceps force and anterior tibial force occur obviously later than vertical ground reaction force: a simulation study

Author

Ueno, Ryo, Ishida, Tomoya, 1000040166757, Yamanaka, Masanori, Taniguchi, Shohei, Ikuta, Ryohei, 1000040360953, Samukawa, Mina, 1000060301917, Saito, Hiroshi, 1000060301884, Tohyama, Harukazu, Ueno, Ryo, Ishida, Tomoya, 1000040166757, Yamanaka, Masanori, Taniguchi, Shohei, Ikuta, Ryohei, 1000040360953, Samukawa, Mina, 1000060301917, Saito, Hiroshi, 1000060301884, and Tohyama, Harukazu

Abstract

Background: Although it is well known that quadriceps force generates anterior tibial force, it has been unclear whether quadriceps force causes great anterior tibial force during the early phase of a landing task. The purpose of the present study was to examine whether the quadriceps force induced great anterior tibial force during the early phase of a landing task. Methods: Fourteen young, healthy, female subjects performed a single-leg landing task. Muscle force and anterior tibial force were estimated from motion capture data and synchronized force data from the force plate. One-way repeated measures analysis of variance and the post hoc Bonferroni test were conducted to compare the peak time of the vertical ground reaction force, quadriceps force and anterior tibial force during the single-leg landing. In addition, we examined the contribution of vertical and posterior ground reaction force, knee flexion angle and moment to peak quadriceps force using multiple linear regression. Results: The peak times of the estimated quadriceps force (96.0 +/- 23.0 ms) and anterior tibial force (111.9 +/- 18.9 ms) were significantly later than that of the vertical ground reaction force (63.5 +/- 6.8 ms) during the single-leg landing. The peak quadriceps force was positively correlated with the peak anterior tibial force (R = 0.953, P < 0.001). Multiple linear regression analysis showed that the peak knee flexion moment contributed significantly to the peak quadriceps force (R-2 = 0.778, P < 0.001). Conclusion: The peak times of the quadriceps force and the anterior tibial force were obviously later than that of the vertical ground reaction force for the female athletes during successful single-leg landings. Studies have reported that the peak time of the vertical ground reaction force was close to the time of anterior cruciate ligament (ACL) disruption in ACL injury cases. It is possible that early contraction of the quadriceps during landing might induce ACL disruption

Published

2017

6. Quadriceps force and anterior tibial force occur obviously later than vertical ground reaction force: a simulation study

Author

Ueno, Ryo, primary, Ishida, Tomoya, additional, Yamanaka, Masanori, additional, Taniguchi, Shohei, additional, Ikuta, Ryohei, additional, Samukawa, Mina, additional, Saito, Hiroshi, additional, and Tohyama, Harukazu, additional

Published

2017

7. Quadriceps force and anterior tibial force occur obviously later than vertical ground reaction force: a simulation study.

Author

Ryo Ueno, Tomoya Ishida, Masanori Yamanaka, Shohei Taniguchi, Ryohei Ikuta, Mina Samukawa, Hiroshi Saito, Harukazu Tohyama, Ueno, Ryo, Ishida, Tomoya, Yamanaka, Masanori, Taniguchi, Shohei, Ikuta, Ryohei, Samukawa, Mina, Saito, Hiroshi, and Tohyama, Harukazu

Subjects

ANTERIOR cruciate ligament injuries, QUADRICEPS muscle, TIBIA, GROUND reaction forces (Biomechanics), MUSCULOSKELETAL system

Abstract

Background: Although it is well known that quadriceps force generates anterior tibial force, it has been unclear whether quadriceps force causes great anterior tibial force during the early phase of a landing task. The purpose of the present study was to examine whether the quadriceps force induced great anterior tibial force during the early phase of a landing task.Methods: Fourteen young, healthy, female subjects performed a single-leg landing task. Muscle force and anterior tibial force were estimated from motion capture data and synchronized force data from the force plate. One-way repeated measures analysis of variance and the post hoc Bonferroni test were conducted to compare the peak time of the vertical ground reaction force, quadriceps force and anterior tibial force during the single-leg landing. In addition, we examined the contribution of vertical and posterior ground reaction force, knee flexion angle and moment to peak quadriceps force using multiple linear regression.Results: The peak times of the estimated quadriceps force (96.0 ± 23.0 ms) and anterior tibial force (111.9 ± 18.9 ms) were significantly later than that of the vertical ground reaction force (63.5 ± 6.8 ms) during the single-leg landing. The peak quadriceps force was positively correlated with the peak anterior tibial force (R = 0.953, P < 0.001). Multiple linear regression analysis showed that the peak knee flexion moment contributed significantly to the peak quadriceps force (R 2 = 0.778, P < 0.001).Conclusion: The peak times of the quadriceps force and the anterior tibial force were obviously later than that of the vertical ground reaction force for the female athletes during successful single-leg landings. Studies have reported that the peak time of the vertical ground reaction force was close to the time of anterior cruciate ligament (ACL) disruption in ACL injury cases. It is possible that early contraction of the quadriceps during landing might induce ACL disruption as a result of excessive anterior tibial force in unanticipated situations in ACL injury cases. [ABSTRACT FROM AUTHOR]

Published

2017