| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 6206764 | Gait & Posture | 2013 | 6 Pages |
â¢Mechanical energy profiles of ankle joint and distal foot structures were examined.â¢Results are from healthy subjects walking level-ground at four different speeds.â¢Ankle joint and distal foot structures produce counteracting energy profiles.â¢Work-ratios of the combined ankle and foot system increase with faster walking speeds.â¢Work-ratios of the combined ankle and foot are not greater than 1.0 at various speeds.
Over the last half-century, the field of prosthetic engineering has continuously evolved with much attention being dedicated to restoring the mechanical energy properties of ankle joint musculatures during gait. However, the contributions of 'distal foot structures' (e.g., foot muscles, plantar soft tissue) have been overlooked. Therefore, the purpose of this study was to quantify the total mechanical energy profiles (e.g., power, work, and work-ratio) of the natural ankle-foot system (NAFS) by combining the contributions of the ankle joint and all distal foot structures during stance in level-ground steady state walking across various speeds (0.4, 0.6, 0.8 and 1.0Â statures/s). The results from eleven healthy subjects walking barefoot indicated ankle joint and distal foot structures generally performed opposing roles: the ankle joint performed net positive work that systematically increased its energy generation with faster walking speeds, while the distal foot performed net negative work that systematically increased its energy absorption with faster walking speeds. Accounting for these simultaneous effects, the combined ankle-foot system exhibited increased work-ratios with faster walking. Most notably, the work-ratio was not significantly greater than 1.0 during the normal walking speed of 0.8Â statures/s. Therefore, a prosthetic design that strategically exploits passive-dynamic properties (e.g., elastic energy storage and return) has the potential to replicate the mechanical energy profiles of the NAFS during level-ground steady-state walking.
