Abstract
Polymeric meshes in the form of knitted nets are commonly used in the surgical repair of pelvic organ prolapses. Although a number of these prosthetic meshes are commercially available, there is little published data on their mechanical performance, in particular on the change in stiffness under the repeated loading experienced in vivo. In this in vitro study, cyclic tensile loading was applied to rectangular strips of four different commercially available meshes. The applied force and resultant displacement was monitored throughout the tests in order to evaluate the change in stiffness. In addition, each mesh was randomly marked using indelible ink in order to permit the use of threedimensional digital image correlation to evaluate local displacements during the tests. However, the scale and form of the deformation experienced by some of the meshes made correlation difficult so that confirmation of the values of stiffness were only obtained for two meshes. The results demonstrate that all the meshes experience an increase in stiffness during cyclic loading, that in most cases cyclic creep occurs and in some cases large-scale, irreversible reorganisation of the mesh structure occurs after as few as 200 cycles at loads of the order of 10N.
Highlights
Implanted artificial mesh is commonly used in the treatment of pelvic organ prolapse [1]
Digital Image Correlation (DIC) analysis was unsuccessful for two of the four materials examined because the deformations were so large and the meshes had a very open weave and so behaved as a structure rather than a continuum material
The Young’s modulus obtained from DIC agrees well with that obtained from the tensile test
Summary
Implanted artificial mesh is commonly used in the treatment of pelvic organ prolapse [1]. Pelvic Organ Prolapse is a condition affecting women during menopause and those who have given birth vaginally [2]. The condition is caused by a weakened pelvic floor which leads to the pelvic organs moving and falling on to the vagina, resulting in considerable discomfort to the patient [2]. One possible treatment is to use artificial mesh to reinforce the pelvic floor and help hold the organs in place. Little is known about the mechanical properties of such artificial meshes. Previous work investigated the performance of artificial meshes subject to static tension loading [3]. The aim of this paper is to understand the behaviour and properties of the artificial mesh under cyclic loading
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