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Abstract

In podiatry, polymeric orthopedic insoles are widespread, to optimize athletic performances or for diabetic care. Despite computer-aided design development, the choice of materials, their distribution in the sole and their thickness is empirical. The research question of this study is to determine the relationship between the properties of the materials of a sole, the stacking of these materials, and the overall mechanical response of the sole. Cohort studies are inefficient to solve this complex problem, due to numerous parameters, nor to elucidate the effort transmission through the insoles. In this study, finite element simulations are used for the prediction of the pressure distribution at the interface between the foot and the insole for a range of commercial podiatric insole materials with Shore hardness between 18 and 60 (3 ethylene vinyl acetate copolymers, Poron© polyurethane and an elastomer). After measuring the mechanical properties of these materials, the simulated pressure distribution under various insoles was compared to measured pressure distribution. For 15 configurations, simulated pressure agrees with measured pressure for 84% of the sensors. In addition to validating the finite element methodology for podiatric insoles, the hyper foam law parameters determined for each material in this study can be used to predict the mechanical reaction of insole - foot systems.

Keywords

insole foam materials finite element method plantar pressure measurement podiatric insole polymer properties ethylene vinyl acetate (EVA)polyurethane elastomer hyper foam orthopedics

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References

Deschamps

Matricali

Roosen

, et al. Classification of forefoot plantar pressure distribution in persons with diabetes: a novel perspective for the mechanical management of diabetic foot? PLoS One 2013; 8: e79924.

Nouman

Chong

DYR

Srewaradachpisal

, et al. The effect of customized insole pads on plantar pressure distribution in a diabetic foot with neuropathy: material and design study using finite element analysis approach. Appl Sci 2023; 13: 399.

Geiger

Kebbach

Vogel

, et al. Efficient computer-based method for adjusting the stiffness of subject-specific 3D-printed insoles during walking. Appl Sci 2023; 13: 3854.

Chatzistergos

Naemi

Healy

, et al. Subject specific optimisation of the stiffness of footwear material for maximum plantar pressure reduction. Ann Biomed Eng 2017; 45: 1929–1940.

Martin-Scherrens

De Schepper

Bouckaert

, et al. De quels éléments et signaux d’alarme le podologue doit-il/elle tenir compte lors de l’examen de son patient dans la décision d’effectuer lui/elle-même la prestation technique ou de réorienter d’abord le patient vers un médecin?Evikey and the Belgian Ministry of Health, 2024.

Collings

Freeman

Latour

, et al. Footwear and insole design features for offloading the diabetic at risk foot - a systematic review and meta-analyses. Endocrinol Diabetes Metab 2021; 4: e00132.

Haris

Liau

Jan

, et al. A review of the plantar pressure distribution effects from insole materials and at different walking speeds. Appl Sci 2021; 11: 11851.

Nilsen

Molund

Lium

, et al. Material selection for diabetic custom insoles: a systematic review of insole materials and their properties. JPO J Prosthet Orthot 2022; 34: e131–e143.

Bus

Busch-Westbroek

Pulles

, et al. Pressure-relieving effect of different insole top covers in people with diabetes at high risk of foot ulceration. Sensors 2024; 24: 5549.

10.

Shimazaki

Nozu

Inoue

. Shock-absorption properties of functionally graded EVA laminates for footwear design. Polym Test 2016; 54: 98–103.

11.

Cardoso

Guimarães

Lopes

, et al. Development of a rubber sole with an integral cushioning system for casual sport shoes. Proc Inst Mech Eng Part J Mater Des Appl 2019; 233: 2253–2266.

12.

Mara

Harland

Mitchell

. Virtual modelling of a prosthetic foot to improve footwear testing. Proc Inst Mech Eng Part J Mater Des Appl 2006; 220: 207–213.

13.

Mackerle

. Finite element modeling and simulations in orthopedics: a bibliography 1998-2005. Comput Methods Biomech Biomed Eng 2006; 9: 149–199.

14.

Chen

Tang

. Effects of total contact insoles on the plantar stress redistribution: a finite element analysis. Clin Biomech 2003; 18: S17–S24.

15.

Franciosa

Gerbino

Lanzotti

, et al. Improving comfort of shoe sole through experiments based on CAD-FEM modeling. Med Eng Phys 2013; 35: 36–46.

16.

Cheung

Zhang

, M, Parametric design of pressure-relieving foot orthosis using statistics-based finite element method. Med Eng Phys 2008; 30: 269–277.

17.

Luboz

Perrier

Vuillerme

, et al. Foot biomechanical modelling to study orthoses influence. Comput Methods Biomech Biomed Eng 2012; 15 Suppl 1: 360–362.

18.

Yang

Cui

Wan

, et al. Design feature combinations effects of running shoe on plantar pressure during heel landing: a finite element analysis with Taguchi optimization approach. Front Bioeng Biotechnol 2022; 10: 959842.

19.

Chen

Haoa

Zhaob

. Dynamic numerical analysis of the ‘Foot - Training Shoe’ model. In: Procedia manufacturing, 6th international conference on applied human factors and ergonomics (AHFE 2015) and the affiliated conferences AHFE, 2015, pp. 5519–5526.

20.

Dassault Systems. Hyperelastic behavior in elastomeric foams, https://help.3ds.com/ (2024, accessed 1 October 2024).

21.

Cheung

Zhang

. Finite element modeling of the human foot and footwear. In: ABAQUS users’ conference. 2006.

22.

Shakouri

Mossayebi

Saraeian

. Fabrication of medical footwear for suitable distribution of stress and strain and reduction of plantar pressure by numerical and experimental approaches. Proc Inst Mech Eng H 2019; 233: 1051–1063.

23.

Song

Liu

. The effect of personalized orthopedic insoles on plantar pressure during running in subtle cavus foot. Front Bioeng Biotechnol 2024; 12: 959841.

24.

Iacob

Popescu

Stochioiu

, et al. Compressive behavior of thermoplastic polyurethane with an active agent foaming for 3D-printed customized comfort insoles. Polym Test 2024; 137: 108517.

25.

Ghassemi

Mossayebi

Jamshidi

, et al. Manufacturing and finite element assessment of a novel pressure reducing insole for diabetic neuropathic patients. Australas Phys Eng Sci Med 2015; 38: 63–70.

26.

Cracknell

Battley

Fernandez

, et al. The mechanical response of polymeric gyroid structures in an optimised orthotic insole. Biomech Model Mechanobiol 2025; 24: 311–329.

27.

Kuklin

. Optical flow in OpenCV (C++/Python), https://learnopencv.com/optical-flow-in-opencv/#what-is-optical-flow (2024).

28.

Root

Leveau

Orien

, et al. Normal and abnormal function of the foot: clinical biomechanics, vol 2. Phys Ther 1979; 59: 352.

29.

Petre

Erdemir

Cavanagh

. Determination of elastomeric foam parameters for simulations of complex loading. Comput Methods Biomech Biomed Eng 2006; 9: 231–242.

30.

Jebur

Harrison

Guo

, et al. Characterisation and modelling of a transversely isotropic melt-extruded low-density polyethylene closed cell foam under uniaxial compression. Proc Inst Mech Eng Part C 2012; 226: 2168–2177.

31.

Fontanella

Forestiero

Carniel

, et al. Analysis of heel pad tissues mechanics at the heel strike in bare and shod conditions. Med Eng Phys 2013; 35: 441–447.

32.

Storåkers

. On material representation and constitutive branching in finite compressible elasticity. J Mech Phys Solids 1986; 34: 125–145.

33.

Kitronix. Kytronix pressure sensor. https://www.kitronyx.com/solution_InsoleSensorKit (2024, accessed 1 October 2024).

34.

Lakho

Abro

Chen

, et al. Smart insole based on flexi force and flex sensor for monitoring different body postures. Sensors 2022; 22: 5469.

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Finite element framework for investigating the mechanical response of podiatric insole: A pilot study

Abstract

Keywords

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