A method for subject-specific modelling and optimisation of the cushioning properties of insole materials used in diabetic footwear

Panagiotis E. Chatzistergos (Lead / Corresponding author), Roozbeh Naemi, Nachiappan Chockalingam

Research output: Contribution to journalArticlepeer-review

46 Citations (Scopus)

Abstract

This study aims to develop a numerical method that can be used to investigate the cushioning properties of different insole materials on a subject-specific basis.Diabetic footwear and orthotic insoles play an important role for the reduction of plantar pressure in people with diabetes (type-2). Despite that, little information exists about their optimum cushioning properties.A new in-vivo measurement based computational procedure was developed which entails the generation of 2D subject-specific finite element models of the heel pad based on ultrasound indentation. These models are used to inverse engineer the material properties of the heel pad and simulate the contact between plantar soft tissue and a flat insole. After its validation this modelling procedure was utilised to investigate the importance of plantar soft tissue stiffness, thickness and loading for the correct selection of insole material.The results indicated that heel pad stiffness and thickness influence plantar pressure but not the optimum insole properties. On the other hand loading appears to significantly influence the optimum insole material properties. These results indicate that parameters that affect the loading of the plantar soft tissues such as body mass or a person's level of physical activity should be carefully considered during insole material selection.

Original languageEnglish
Pages (from-to)531-538
Number of pages8
JournalMedical Engineering and Physics
Volume37
Issue number6
Early online date27 Apr 2015
DOIs
Publication statusPublished - Jun 2015

Keywords

  • Contact analysis
  • Diabetic foot
  • Finite element
  • Heel-pad
  • Hyperfoam
  • Inverse engineering
  • Plantar pressure
  • Plantar soft tissue
  • Ultrasound indentation

ASJC Scopus subject areas

  • Biophysics
  • Biomedical Engineering

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