Novel methodology to obtain salient biomechanical characteristics of insole materials

Lawrence A. Lavery; Steven A. Vela; Hisham R. Ashry; Dan R. Lanctot; Kyriacos A. Athanasiou

doi:10.7547/87507315-87-6-266

Novel methodology to obtain salient biomechanical characteristics of insole materials

Lawrence A. Lavery
, Steven A. Vela
, Hisham R. Ashry
, Dan R. Lanctot
, Kyriacos A. Athanasiou

Division of Podiatry

Producción científica: Article › revisión exhaustiva

14 Citas (Scopus)

Resumen

Viscoelastic inserts are commonly used as artificial shock absorbers to prevent neuropathic foot ulcerations by decreasing pressure on the sole of the foot. Unfortunately, there is little scientific information available to guide physicians in the selection of appropriate insole materials. Therefore, a novel methodology was developed to form a rational platform for biomechanical characterizations of insole material durability, which consisted of in vivo gait analysis and in vitro bioengineering measurements. Results show significant differences in the compressive stiffness of the tested insoles and the rate of change over time in both compressive stiffness and peak pressures measured. Good correlations were found between pressure-time integral and Young's modulus (r² = 0.93), and total energy applied and Young's modulus (r² = 0.87).

Idioma original	English (US)
Páginas (desde-hasta)	266-271
Número de páginas	6
Publicación	Journal of the American Podiatric Medical Association
Volumen	87
N.º	6
DOI	https://doi.org/10.7547/87507315-87-6-266
Estado	Published - 1997

ASJC Scopus subject areas

General Medicine

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title = "Novel methodology to obtain salient biomechanical characteristics of insole materials",

abstract = "Viscoelastic inserts are commonly used as artificial shock absorbers to prevent neuropathic foot ulcerations by decreasing pressure on the sole of the foot. Unfortunately, there is little scientific information available to guide physicians in the selection of appropriate insole materials. Therefore, a novel methodology was developed to form a rational platform for biomechanical characterizations of insole material durability, which consisted of in vivo gait analysis and in vitro bioengineering measurements. Results show significant differences in the compressive stiffness of the tested insoles and the rate of change over time in both compressive stiffness and peak pressures measured. Good correlations were found between pressure-time integral and Young's modulus (r2 = 0.93), and total energy applied and Young's modulus (r2 = 0.87).",

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T1 - Novel methodology to obtain salient biomechanical characteristics of insole materials

AU - Lavery, Lawrence A.

AU - Vela, Steven A.

AU - Ashry, Hisham R.

AU - Lanctot, Dan R.

AU - Athanasiou, Kyriacos A.

PY - 1997

Y1 - 1997

N2 - Viscoelastic inserts are commonly used as artificial shock absorbers to prevent neuropathic foot ulcerations by decreasing pressure on the sole of the foot. Unfortunately, there is little scientific information available to guide physicians in the selection of appropriate insole materials. Therefore, a novel methodology was developed to form a rational platform for biomechanical characterizations of insole material durability, which consisted of in vivo gait analysis and in vitro bioengineering measurements. Results show significant differences in the compressive stiffness of the tested insoles and the rate of change over time in both compressive stiffness and peak pressures measured. Good correlations were found between pressure-time integral and Young's modulus (r2 = 0.93), and total energy applied and Young's modulus (r2 = 0.87).

AB - Viscoelastic inserts are commonly used as artificial shock absorbers to prevent neuropathic foot ulcerations by decreasing pressure on the sole of the foot. Unfortunately, there is little scientific information available to guide physicians in the selection of appropriate insole materials. Therefore, a novel methodology was developed to form a rational platform for biomechanical characterizations of insole material durability, which consisted of in vivo gait analysis and in vitro bioengineering measurements. Results show significant differences in the compressive stiffness of the tested insoles and the rate of change over time in both compressive stiffness and peak pressures measured. Good correlations were found between pressure-time integral and Young's modulus (r2 = 0.93), and total energy applied and Young's modulus (r2 = 0.87).

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DO - 10.7547/87507315-87-6-266

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AN - SCOPUS:0031157665

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Novel methodology to obtain salient biomechanical characteristics of insole materials

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