Medially wedged foot orthoses generate greater biomechanical effects than thin-flexible foot orthoses during a unilateral drop jump task on level and inclined surfaces

• Published in: Clinical biomechanics (Bristol) Vol. 112; p. 106193
• Main Authors: Dami, Ahmed, Payen, Eléna, Farahpour, Nader, Robb, Kelly, Isabelle, Pier-Luc, Moisan, Gabriel
• Format: Journal Article
• Language: English
• Published: England Elsevier Ltd 01.02.2024
• Subjects: Biomechanical Phenomena; Cross-Sectional Studies; Foot; Foot Orthoses; Humans; Knee Joint; Locomotion; Lower Extremity; Orthotic devices; Biomechanical phenomena; Locomotion; Foot orthoses; Lower extremity; Orthotic devices
• ISSN: 0268-0033; 1879-1271
• DOI: 10.1016/j.clinbiomech.2024.106193

Foot orthoses are therapeutic insoles designed to induce various effects on lower limb biomechanics. However, conflicting findings in previous research, highlight the need to better understand how foot orthoses with different features affect lower limb biomechanics during challenging tasks, particularly during unilateral drop jump landings. Seventeen participants with flat feet were recruited to participate in this cross-sectional descriptive study that examined the effects of thin-flexible foot orthoses and medially wedged foot orthoses on lower limb biomechanics during unilateral drop jump landings on level and valgus inclined surfaces. Midfoot, ankle, knee, and hip angles and moments were calculated and compared across conditions with repeated measures ANOVAs, using a statistical parametric mapping approach. Medially wedged and thin-flexible foot orthoses reduced ankle pronation and arch flattening during unilateral drop jump landings on level and valgus inclined surfaces. Medially wedged foot orthoses further decreased midfoot dorsiflexion and ankle eversion angles compared to thin-flexible foot orthoses. Medially wedged foot orthoses also generated greater effects on ankle kinetics and hip kinematics during unilateral drop jump landings. Medially wedged foot orthoses are more effective than thin-flexible foot orthoses in optimizing lower limb biomechanics during unilateral drop jump landings. While the biomechanical effects did not increase on inclined surfaces, medially wedged foot orthoses generated greater effects on proximal joints, highlighting their potential to improve hip stability and enhance overall lower limb function. Personalized foot orthoses selection based on specific biomechanical profiles should be further explored to optimize orthotic interventions benefiting individuals with musculoskeletal conditions. •Medially wedged foot orthoses generated the greatest biomechanical effects.•Similar foot orthoses' effects were observed during landing on both surfaces.•Foot orthoses mainly effected the distal segments of the lower limb.