Effects of flywheel resistance training on countermovement jump performance and vastus lateralis muscle stiffness: A controlled study.
Study Goal
The researchers aimed to determine the effects of an 8-week flywheel resistance training program on countermovement jump performance and resting stiffness of the vastus lateralis muscle in physically active adults.
Results Summary
The training group showed significant improvements in jump height, rate of force development, peak power, and peak force, while the control group did not. No significant changes were observed in resting muscle stiffness for either group.
Population
Physically active adults
Effective Dosage
Individually allocated high-load flywheel inertia (specific amount not detailed)
Duration
8 weeks
Interactions
None mentioned
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
8-week resistance training using flywheel (FW) device | increase | jump height | Physically active adults in training intervention group | +9% | statistically significant group differences | #1 |
8-week resistance training using flywheel (FW) device | increase | rate of force development | Physically active adults in training intervention group | +32% | statistically significant group differences | #2 |
8-week resistance training using flywheel (FW) device | increase | peak power | Physically active adults in training intervention group | +9% | statistically significant group differences | #3 |
8-week resistance training using flywheel (FW) device | increase | peak force | Physically active adults in training intervention group | +7% | statistically significant group differences | #4 |
8-week resistance training using flywheel (FW) device | increase | jump performance | Physically active adults in training intervention group | - | improved | #5 |
8-week resistance training using flywheel (FW) device | no change | resting shear wave modulus | Physically active adults in training intervention group | - | no significant changes | #6 |
8-week resistance training using flywheel (FW) device | decrease | VL stiffness | Physically active adults in training intervention group | -4% | decreased | #7 |
no intervention | decrease | jump height | Physically active adults in control group | -3% | statistically significant group differences | #8 |
no intervention | increase | rate of force development | Physically active adults in control group | +4% | statistically significant group differences | #9 |
no intervention | decrease | peak power | Physically active adults in control group | -1% | statistically significant group differences | #10 |
no intervention | decrease | peak force | Physically active adults in control group | -1% | statistically significant group differences | #11 |
no intervention | no change | resting shear wave modulus | Physically active adults in control group | - | no significant changes | #12 |
no intervention | increase | VL stiffness | Physically active adults in control group | +6% | increased | #13 |
This study aimed to investigate the effects of an 8-week resistance training using flywheel (FW) device on countermovement jump (CMJ) performance and resting stiffness of the vastus lateralis (VL) muscle. Physically active adults were randomly assigned to a training intervention group (T; n = 18) and a control group (C; n = 13), which received no intervention. Jump performance variables and ultrasound-assessed resting VL shear modulus were measured before and after the intervention. Analysis of covariance revealed statistically significant group differences in jump height (T = +9%; C = -3%), rate of force development (T = +32%; C = +4%), peak power (T = +9%; C = -1%), and peak force (T = +7%; C = -1%). Jump performance improved only in the training group (all CMJ variables p < 0.05). Conversely, no significant changes within groups were observed in the resting shear wave modulus results (p > 0.05). VL stiffness decreased in the training group (-4%) and increased in the control group (+6%). Our results suggest that resistance training using FW device with individually allocated high-load FW inertia induces significant improvements in jump performance, which are not underpinned by changes in VL muscle stiffness.