J. Grasa scite author profile

This work presents a portable non-invasive external fixator to assess and monitor fracture healing in real time. To evaluate the potential of this fixator, a transverse osteotomy was performed in the tibia of six adult sheep (mean age 3+/-0.5 years and weight 63+/-5 kg). The fractures were stabilized by a specially designed unilateral external fixator, which was instrumented by means of a set of strain gauges. Strains in the external surface of the fixator were monitored during all the healing process. A wireless, remote monitoring of the implant was developed through a specially designed external telemetric device. The strain gauges were arranged in two different half-bridge Wheatstone configurations, allowing easy post-processing of the signal. Thus, bending loads were measured in two planes of the external fixator acting as a load cell. The load through the fixator was evaluated for the gait cycle during all the healing process. Full weight bearing of the injured leg was observed from the beginning. The load transmission mechanism in the fixator was quite similar in all operated tibias and radiographic images showed a successful healing in all animals. Although the fixator has only been tested in an animal model, after further testing this system may have clinical potential.

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Determination of passive viscoelastic response of the abdominal muscle and related constitutive modeling: Stress-relaxation behavior

Calvo

Sierra

Grasa

et al. 2014

Journal of the Mechanical Behavior of Biomedical Materials

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Active behavior of abdominal wall muscles: Experimental results and numerical model formulation

Grasa

Sierra

Lauzeral

et al. 2016

Journal of the Mechanical Behavior of Biomedical Materials

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In the present study a computational finite element technique is proposed to simulate the mechanical response of muscles in the abdominal wall. This technique considers the active behavior of the tissue taking into account both collagen and muscle fiber directions. In an attempt to obtain the computational response as close as possible to real muscles, the parameters needed to adjust the mathematical formulation were determined from in vitro experimental tests. Experiments were conducted on male New Zealand White rabbits (2047±34g) and the active properties of three different muscles: Rectus Abdominis, External Oblique and multi-layered samples formed by three muscles (External Oblique, Internal Oblique, and Transversus Abdominis) were characterized. The parameters obtained for each muscle were incorporated into a finite strain formulation to simulate active behavior of muscles incorporating the anisotropy of the tissue. The results show the potential of the model to predict the anisotropic behavior of the tissue associated to fibers and how this influences on the strain, stress and generated force during an isometric contraction.

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A 3D active-passive numerical skeletal muscle model incorporating initial tissue strains. Validation with experimental results on rat tibialis anterior muscle

Grasa

Ramírez

Osta

et al. 2010

Biomech Model Mechanobiol

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This paper presents a three-dimensional finite element model of skeletal muscle and its validation incorporating inital tissue strains. A constitutive relation was determined by using a convex free strain energy function (SEF) where active and passive response contributions were obtained fitting experimental data from the rat tibialis anterior (TA) muscle. The passive and active finite strains response was modelled within the framework of continuum mechanics by a quasi-incompressible transversely isotropic material formulation. Magnetic resonance images (MRI) were obtained to reconstruct the external geometry of the TA. This geometry includes initial strains also taken into account in the numerical model. The numerical results show excellent agreement with the experimental results when comparing reaction force-extension curves both in passive and active tests. The proposed constitutive model for the muscle is implemented in a subroutine in the commercial finite element software package ABAQUS.

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Probabilistic analysis of the influence of the bonding degree of the stem–cement interface in the performance of cemented hip prostheses

Pérez

Grasa

García-Aznar

et al. 2006

Journal of Biomechanics

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J. Grasa

Passive nonlinear elastic behaviour of skeletal muscle: Experimental results and model formulation

An experimental study of the mouse skin behaviour: Damage and inelastic aspects

A 3D electro-mechanical continuum model for simulating skeletal muscle contraction

Monitoring In Vivo Load Transmission Through an External Fixator

Determination of passive viscoelastic response of the abdominal muscle and related constitutive modeling: Stress-relaxation behavior

Active behavior of abdominal wall muscles: Experimental results and numerical model formulation

A 3D active-passive numerical skeletal muscle model incorporating initial tissue strains. Validation with experimental results on rat tibialis anterior muscle

Probabilistic analysis of the influence of the bonding degree of the stem–cement interface in the performance of cemented hip prostheses

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