Braiding Thermoplastic and Glass Fibers in Composite Dental Post Improves Their Mechanical Compatibility, In Vitro Experiment

Braiding Thermoplastic and Glass Fibers in Composite Dental Post Improves Their Mechanical Compatibility, In Vitro Experiment

Mechanical compatibility with the human dentin is a considerable issue when fabricating dental fiber posts. To this purpose, this study introduces a new method of fabricating compatible dental posts using braiding techniques of thermoplastic fibers (matrix) with glass fibers (reinforcement). Fifty f...

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Bibliographic Details
Main Authors: Esraa M. Abdelkader, K. Nassar, Juan Melchor, Guillermo Rus
Format: Article
Language:English
Published: MDPI AG 2021-04-01
Series:Materials
Subjects:
dental materials
root canal posts
fiber-reinforced composites (FRCs)
young’s modulus
shear modulus
fiber volume fraction (FVF)
Online Access:https://www.mdpi.com/1996-1944/14/9/2294
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spelling doaj-b2eb0810ac304227b2c5d57581d1f6292021-04-29T23:00:11ZengMDPI AGMaterials1996-19442021-04-01142294229410.3390/ma14092294Braiding Thermoplastic and Glass Fibers in Composite Dental Post Improves Their Mechanical Compatibility, In Vitro ExperimentEsraa M. Abdelkader0K. Nassar1Juan Melchor2Guillermo Rus3Department of Structural Mechanics, University of Granada, 18071 Granada, SpainDepartment of Textile, Faculty of Applied Arts, Helwan University, Cairo 11795, EgyptBiomechanics Group (TEC-12), Instituto de Investigación Biosanitaria, ibs.GRANADA, 18012 Granada, SpainDepartment of Structural Mechanics, University of Granada, 18071 Granada, SpainMechanical compatibility with the human dentin is a considerable issue when fabricating dental fiber posts. To this purpose, this study introduces a new method of fabricating compatible dental posts using braiding techniques of thermoplastic fibers (matrix) with glass fibers (reinforcement). Fifty fiber-reinforced composite (FRC) posts of thermoplastic yarns polypropylene (PP) braided with continuous filaments glass fibers (GFs) for reinforcement, varying in fiber volume fraction (FVF), and core types are fabricated and tested. Posts are performed using a braiding machine, and braids are placed in an aluminum mold. The filled mold is playced inside an oven at the melting temperature of the polypropylene to produce the final post’s shape. An ultrasonic test is conducted to measure the shear modulus and Young’s modulus of FRC post specimens by measuring the velocities of both the P-wave and S-wave. In order to ensure the accuracy of the measurements, each sample is measured three times, and then the means and standard deviations of each sample are calculated before analyzing the test results using the means of two steps, namely, clustering and comparing the P and R² values of each cluster, which revealed that FVF, fiber mass, and core type of the specimen had a significant effect on the resulted Young’s and shear modulus. The results indicate that the proposed method can fabricate competitive dental posts with regard to different fabricating variables. The samples show Young’s modulus ranges of from 10.08 GPa to 31.83 GPa. The following tested hypothesis is supported: the braiding technique of thermoplastic fibers with glass fibers will improve the mechanical compatibility of the resulting posts (ex vivo).https://www.mdpi.com/1996-1944/14/9/2294dental materialsroot canal postsfiber-reinforced composites (FRCs)young’s modulusshear modulusfiber volume fraction (FVF)
collection DOAJ
language English
format Article
sources DOAJ
author Esraa M. Abdelkader
K. Nassar
Juan Melchor
Guillermo Rus
spellingShingle Esraa M. Abdelkader
K. Nassar
Juan Melchor
Guillermo Rus
Braiding Thermoplastic and Glass Fibers in Composite Dental Post Improves Their Mechanical Compatibility, In Vitro Experiment
Materials
dental materials
root canal posts
fiber-reinforced composites (FRCs)
young’s modulus
shear modulus
fiber volume fraction (FVF)
author_facet Esraa M. Abdelkader
K. Nassar
Juan Melchor
Guillermo Rus
author_sort Esraa M. Abdelkader
title Braiding Thermoplastic and Glass Fibers in Composite Dental Post Improves Their Mechanical Compatibility, In Vitro Experiment
title_short Braiding Thermoplastic and Glass Fibers in Composite Dental Post Improves Their Mechanical Compatibility, In Vitro Experiment
title_full Braiding Thermoplastic and Glass Fibers in Composite Dental Post Improves Their Mechanical Compatibility, In Vitro Experiment
title_fullStr Braiding Thermoplastic and Glass Fibers in Composite Dental Post Improves Their Mechanical Compatibility, In Vitro Experiment
title_full_unstemmed Braiding Thermoplastic and Glass Fibers in Composite Dental Post Improves Their Mechanical Compatibility, In Vitro Experiment
title_sort braiding thermoplastic and glass fibers in composite dental post improves their mechanical compatibility, in vitro experiment
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2021-04-01
description Mechanical compatibility with the human dentin is a considerable issue when fabricating dental fiber posts. To this purpose, this study introduces a new method of fabricating compatible dental posts using braiding techniques of thermoplastic fibers (matrix) with glass fibers (reinforcement). Fifty fiber-reinforced composite (FRC) posts of thermoplastic yarns polypropylene (PP) braided with continuous filaments glass fibers (GFs) for reinforcement, varying in fiber volume fraction (FVF), and core types are fabricated and tested. Posts are performed using a braiding machine, and braids are placed in an aluminum mold. The filled mold is playced inside an oven at the melting temperature of the polypropylene to produce the final post’s shape. An ultrasonic test is conducted to measure the shear modulus and Young’s modulus of FRC post specimens by measuring the velocities of both the P-wave and S-wave. In order to ensure the accuracy of the measurements, each sample is measured three times, and then the means and standard deviations of each sample are calculated before analyzing the test results using the means of two steps, namely, clustering and comparing the P and R² values of each cluster, which revealed that FVF, fiber mass, and core type of the specimen had a significant effect on the resulted Young’s and shear modulus. The results indicate that the proposed method can fabricate competitive dental posts with regard to different fabricating variables. The samples show Young’s modulus ranges of from 10.08 GPa to 31.83 GPa. The following tested hypothesis is supported: the braiding technique of thermoplastic fibers with glass fibers will improve the mechanical compatibility of the resulting posts (ex vivo).
topic dental materials
root canal posts
fiber-reinforced composites (FRCs)
young’s modulus
shear modulus
fiber volume fraction (FVF)
url https://www.mdpi.com/1996-1944/14/9/2294
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