Alex Elı́as-Zúñiga scite author profile

Surgical meshes, in particular those used to repair hernias, have been in use since 1891. Since then, research in the area has expanded, given the vast number of post-surgery complications such as infection, fibrosis, adhesions, mesh rejection, and hernia recurrence. Researchers have focused on the analysis and implementation of a wide range of materials: meshes with different fiber size and porosity, a variety of manufacturing methods, and certainly a variety of surgical and implantation procedures. Currently, surface modification methods and development of nanofiber based systems are actively being explored as areas of opportunity to retain material strength and increase biocompatibility of available meshes. This review summarizes the history of surgical meshes and presents an overview of commercial surgical meshes, their properties, manufacturing methods, and observed biological response, as well as the requirements for an ideal surgical mesh and potential manufacturing methods.

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Exact solution of the cubic-quintic Duffing oscillator

Elı́as-Zúñiga

2013

Applied Mathematical Modelling

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Forming force and temperature effects on single point incremental forming of polyvinylchloride

Bagudanch

García-Romeu

Centeno

et al. 2015

Journal of Materials Processing Technology

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Enhancement of a magnetorheological PDMS elastomer with carbonyl iron particles

et al. 2017

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Characterization and stability analysis of a multivariable milling tool by the enhanced multistage homotopy perturbation method

Compeán

Olvera

Campa

et al. 2012

International Journal of Machine Tools and Manufacture

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Analytical solution of the damped Helmholtz–Duffing equation

Elı́as-Zúñiga

2012

Applied Mathematics Letters

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Micro injection molding processing of UHMWPE using ultrasonic vibration energy

Sánchez-Sánchez

Hernández-Avila

Elizalde³

et al. 2017

Materials & Design

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Processing of ultra-high molecular weight polyethylene/graphite composites by ultrasonic injection moulding: Taguchi optimization

Sánchez-Sánchez

Elı́as-Zúñiga

Hernández-Avila

2018

Ultrasonics Sonochemistry

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Ultrasonic injection moulding was confirmed as an efficient processing technique for manufacturing ultra-high molecular weight polyethylene (UHMWPE)/graphite composites. Graphite contents of 1 wt%, 5 wt%, and 7 wt% were mechanically pre-mixed with UHMWPE powder, and each mixture was pressed at 135 °C. A precise quantity of the pre-composites mixtures cut into irregularly shaped small pieces were subjected to ultrasonic injection moulding to fabricate small tensile specimens. The Taguchi method was applied to achieve the optimal level of ultrasonic moulding parameters and to maximize the tensile strength of the composites; the results showed that mould temperature was the most significant parameter, followed by the graphite content and the plunger profile. The observed improvement in tensile strength in the specimen with 1 wt% graphite was of 8.8% and all composites showed an increase in the tensile modulus. Even though the presence of graphite produced a decrease in the crystallinity of all the samples, their thermal stability was considerably higher than that of pure UHMWPE. X-ray diffraction and scanning electron microscopy confirmed the exfoliation and dispersion of the graphite as a function of the ultrasonic processing. Fourier transform infrared spectra showed that the addition of graphite did not influence the molecular structure of the polymer matrix. Further, the ultrasonic energy led oxidative degradation and chain scission in the polymer.

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