Reduction of plantar heel pressures:​ insole design using finite element analysis

Goske, Steven<sup>1</sup>; Erdemir, Ahmet<sup>2</sup>; Petre, Marc<sup>2,3</sup>; Budhabhatti, Sachin<sup>2,4</sup>; Cavanagh, Peter R.<sup>2,5</sup>

Affiliations

¹Department of Biomedical Engineering, Saint Louis University, St. Louis, MO 63103, USA

²Department of Biomedical Engineering, Cleveland Clinic Foundation, Cleveland, OH 44195, USA

³Department of Biomedical Engineering, Case Western Reserve University, Cleveland, OH 44106, USA

⁴Department of Chemical & Biomedical Engineering, Cleveland State University, Cleveland, OH 44115, USA

⁵Department of Orthopaedic Surgery and Orthopaedic Research Center, Cleveland Clinic Foundation, Cleveland, OH 44195, USA

Abstract and keywords

Plantar heel pain is a common condition that is often exacerbated by the repetitive stresses of walking. Treatment usually includes an in-shoe intervention designed to reduce plantar pressure under the heel by using insoles and a variety of off-the-shelf products. The design process for these products is often intuitive in nature and does not always rely on scientifically derived guidelines. Finite element analysis provides an efficient computational framework to investigate the performance of a large number of designs for optimal plantar pressure reduction. In this study, we used two-dimensional plane strain finite element modeling to investigate 27 insole designs. Combinations of three insole conformity levels (flat, half conforming, full conforming), three insole thickness values (6.3, 9.5 and 12.7 mm) and three insole materials (Poron Cushioning, Microcel Puff Lite and Microcel Puff) were simulated during the early support phase of gait. Plantar pressures predicted by the model were validated by experimental trials conducted in the same subject whose heel was modeled by loading the bare foot on a rigid surface and on foam mats. Conformity of the insole was the most important design variable, whereas peak pressures were relatively insensitive to insole material selection. The model predicted a 24% relief in pressure compared to barefoot conditions when using flat insoles; the reduction increased up to 44% for full conforming insoles.

Keywords: Peak pressure; Heel pad; Footwear

Links

DOI: 10.1016/j.jbiomech.2005.08.006

PubMed: 16197952

WoS: 000241242900003

History

Accepted: 2005-08-15

Cited Works (6)

Year	Entry
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Cited By (15)

Year	Entry
2008	Hsu Y-C, Gung Y-W, Shih S-L, Feng C-K, Wei S-H, Yu C-h, Chen C-S. Using an optimization approach to design an insole for lowering plantar fascia stress: a finite element study. Ann Biomed Eng. 2008;36(8):1345-1352.
2016	Morales-Orcajo E, Bayod J, Barbosa de Las Casas E. Computational foot modeling: scope and applications. Arch Comput Methods Eng. September 2016;23(3):389-416.
2008	Yu J, Cheung JT-M, Fan Y, Zhang Y, Leung AK-L, Zhang M. Development of a finite element model of female foot for high-heeled shoe design. Clin Biomech (Bristol, Avon). 2008;23(suppl 1):S31-S38.
2010	Gu YD, Ren XJ, Li JS, Lake MJ, Zhang QY, Zeng YJ. Computer simulation of stress distribution in the metatarsals at different inversion landing angles using the finite element method. Int Orthop. June 2010;34(5):669-676.
2011	Tadepalli SC, Erdemir A, Cavanagh PR. Comparison of hexahedral and tetrahedral elements in finite element analysis of the foot and footwear. J Biomech. August 11, 2011;44(12):2337-2343.
2013	Burkhart TA, Andrews DM, Dunning CE. Finite element modeling mesh quality, energy balance and validation methods: a review with recommendations associated with the modeling of bone tissue. J Biomech. May 31, 2013;46(9):1477-1488.
2012	Chokhandre S, Halloran JP, van den Bogert AJ, Erdemir A. A three-dimensional inverse finite element analysis of the heel pad. J Biomech Eng. March 2012;134(3):031002.
2008	Actis RL, Ventura LB, Lott DJ, Smith KE, Commean PK, Hastings MK, Mueller MJ. Multi-plug insole design to reduce peak plantar pressure on the diabetic foot during walking. Med Biol Eng Comput. 2008;46(4):363-371.
2010	Natali AN, Forestiero A, Carniel EL, Pavan PG, Zovo CD. Investigation of foot plantar pressure: experimental and numerical analysis. Med Biol Eng Comput. 2010;48(12):1167-1174.
2012	Fontanella CG, Matteoli S, Carniel EL, Wilhjelm JE, Virga A, Corvi A, Natali AN. Investigation on the load-displacement curves of a human healthy heel pad: in vivo compression data compared to numerical results. Med Eng Phys. November 2012;34(9):1253-1259.
2007	Petre MT. Investigating the Internal Stress/strain State of the Foot Using Magnetic Resonance Imaging and Finite Element Analysis [PhD thesis]. Cleveland, OH: Case Western Reserve University; August 2007.
2009	Sirimamilla PA. Elaborate Experimentation for Mechanical Characterization of Human Foot Using Inverse Finite Element Analysis [Master's thesis]. Cleveland, OH: Case Western Reserve University; January 2009.
2005	Cheung TMJ. Development of Knowledge-Based Criteria for Designing Foot Orthoses [PhD thesis]. Hong Kong Polytechnic University; October 2005.
2008	Lewis GS. Computational Modeling of the Mechanics of Flatfoot Deformity and Its Surgical Corrections [PhD thesis]. State College, PA: Pennsylvania State University; December 2008.
2007	Lott DJ. Effects of Stress Application on the Soft Tissues of the Neuropathic Foot [PhD thesis]. St. Louis, MO: Washington University in St. Louis; May 2007.