Braided Composite Configurations for Dental Applications
Salman, A., Nassar, K., Abdelkader, E. (2021). Braided Composite Configurations for Dental Applications. EKB Journal Management System, 11(4), 399-411. doi: 10.21608/idj.2021.181161
Ahmed Ali Mahmoud Salman; Khalid Mansour Nassar; Esraa M. Abdelkader. "Braided Composite Configurations for Dental Applications". EKB Journal Management System, 11, 4, 2021, 399-411. doi: 10.21608/idj.2021.181161
Salman, A., Nassar, K., Abdelkader, E. (2021). 'Braided Composite Configurations for Dental Applications', EKB Journal Management System, 11(4), pp. 399-411. doi: 10.21608/idj.2021.181161
Salman, A., Nassar, K., Abdelkader, E. Braided Composite Configurations for Dental Applications. EKB Journal Management System, 2021; 11(4): 399-411. doi: 10.21608/idj.2021.181161

Braided Composite Configurations for Dental Applications

International Design Journal
Article 32, Volume 11, Issue 4 - Serial Number 41, July and August 2021, Page 399-411  XML PDF (1.14 MB)
Document Type: Original Article
DOI: 10.21608/idj.2021.181161
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Authors
Ahmed Ali Mahmoud Salman1; Khalid Mansour Nassar2, 3; Esraa M. Abdelkader4, 5
1Prof. of Spinning, Weaving and Knitting, Faculty of Applied Arts, Helwan University, Ahmedsalman2508@gmail.com
2Department of Weaving and Spinning, Faculty of Applied Arts, Helwan University, Egypt
3Department of Textile Engineering, Faculty of Applied Arts, Badr University, Egypt (Corresponding author)
4Department of Textile, Faculty of Applied Arts, Helwan University, Cairo 11795, Egypt
5Department of Textile, Faculty of Applied Arts, Badr University in Cairo, Cairo 11829, Egypt, eng.esraa_mahmoud@outlook.com
Abstract
Braiding technology has been introduced to the composites industry in a spectrum of applications. Braiding configuration is defined by monitoring its variables according to the intended final usage which is the dental fiber posts in this study. Fiber post is a small rod used to support the teeth that have short clinical crown in the definitive restoration. Fiber posts are accepted widely because of their enhanced aesthetic and mechanical properties which enrich the dental field.
Braided composite’s manufacturing process used to be achieved by passing the braided perform through the resin emulations, but in this paper a novel procedure is followed to fabricate the posts through two consecutive processes; first is the braiding process while the second is the melting process. Three different thermoplastic types; Polypropylene (PP), Polyester (PET), and Polyamide (PA) have been braided with the glass-fibers (GF), then the thermoplastic part of the braided perform has been melted to achieve the composite posts.
The posts were assessed visually and mechanically, PP posts show the best performance visually and mechanically while PET posts show the least values in the mechanical testing and the most brittle forms in the visual assessment. Moreover, the PA posts show better mechanical values than the PET, but and the least homogenous forms in the visual assessment. The PET and PA posts brittleness could be attributed to the fabrication method used in this current approach which could have caused an accumulation of humidity because of less applied pressure on the mold during the melting process
Keywords
Braiding technology; emulation; configuration; resin bath; composite; thermoplastic; dental posts; flexural modulus
References
Carey, J. P., Melenka, G. W., Hunt, A. J. & Ayranci, C. Introduction to braided composite material behavior. in Handbook of Advances in Braided Composite Materials 207–237 (Elsevier, 2017). doi:10.1016/B978-0-08-100369-5.00005-2.

2.  Bilisik, K. Three-dimensional braiding for composites: A review. Text. Res. J. 83, 1414–1436 (2013).

3.  Kyosev, Y. Machine Configurator For Braided Composite Profiles With Arbitrary Cross Section. 8 (2014).

4.  Ganesh, V., Ramakrishna, S. & Leck, H. Fiber Reinforced Composite Based Functionally Gradient Materials. Adv. Compos. Lett. 7, 096369359800700 (1998).

5.  Abduljabbar, T. et al. Fracture resistance of three post and core systems in endodontically treated teeth restored with all-ceramic crowns. King Saud Univ. J. Dent. Sci. 3, 33–38 (2012).

6.  Cagidiaco, M. C., Radovic, I., Simonetti, M., Tay, F. & Ferrari, M. Clinical performance of fiber post restorations in endodontically treated teeth: 2-year results. Int. J. Prosthodont. 20, 293–298 (2007).

7.  Bateman, G., Ricketts, D. N. J. & Saunders, W. P. Fibre-based post systems: a review. Br. Dent. J. 195, 43–48 (2003).

8.  Goracci, C. & Ferrari, M. Current perspectives on post systems: a literature review: Post systems. Aust. Dent. J. 56, 77–83 (2011).

9.  Hedlund, S.-O., Johansson, N. G. & Sjögren, G. A retrospective study of pre-fabricated carbon fibre root canal posts. J. Oral Rehabil. 30, 1036–1040 (2003).

10. DiBenedetto, A. T. Tailoring of interfaces in glass fiber reinforced polymer composites: a review. Mater. Sci. Eng. A 302, 74–82 (2001).

11. Abdelkader, E. M., Nassar, K., Melchor, J. & Rus, G. Braiding Thermoplastic and Glass Fibers in Composite Dental Post Improves Their Mechanical Compatibility, In Vitro Experiment. Materials 14, 2294 (2021).

12. Chen, H. & Baird, D. Prediction of Young’s Modulus for Injection Molded Long Fiber Reinforced Thermoplastics. J. Compos. Sci. 2, 47 (2018).

13. Manhart, J. Fiberglass reinforced composite endodontic posts. 5 (2009).

14. Islam, Md. N. et al. Fabrication and Characterization of E-Glass Fiber Reinforced Unsaturated Polyester Resin Based Composite Materials. Nano Hybrids Compos. 24, 1–7 (2019).

15. Avilagalhano, G., Felipevalandro, L., Marquesdemelo, R., Scotti, R. & Antoniobottino, M. Evaluation of the Flexural Strength of Carbon Fiber-, Quartz Fiber-, and Glass Fiber-Based Posts. J. Endod. 31, 209–211 (2005).

16. Lo Giudice, G. et al. Evaluation of Mechanical Properties of a Hollow Endodontic Post by Three Point Test and SEM Analysis: A Pilot Study. Materials 12, 1983 (2019).

17. Calabrese, L., Fabiano, F., Bonaccorsi, L. M., Fabiano, V. & Borsellino, C. Evaluation of the Clinical Impact of ISO 4049 in Comparison with Miniflexural Test on Mechanical Performances of Resin Based Composite. Int. J. Biomater. 2015, 1–7 (2015).

18. Pereira, G. K. R. et al. Fiber-matrix integrity, micromorphology and flexural strength of glass fiber posts: Evaluation of the impact of rotary instruments. J. Mech. Behav. Biomed. Mater. 48, 192–199 (2015).

19. Song, S., Waas, A. M., Shahwan, K. W., Faruque, O. & Xiao, X. (Sharon). Compression response, strength and post-peak response of an axial fiber reinforced tow. Int. J. Mech. Sci. 51, 491–499 (2009).

20. Karacaer, Ö., Polat, T. N., Tezvergıl, A., Lassıla, L. V. J. & Vallıttu, P. K. The effect of length and concentration of glass fibers on the mechanical properties of an injection- and a compression-molded denture base polymer. J. Prosthet. Dent. 90, 385–393 (2003).

21. Shenoy, A. Thermoplastic Melt Rheology and Processing. (CRC Press, 1996). doi:10.1201/9781482295535.

22. Van de Velde, K. & Kiekens, P. Thermoplastic polymers: overview of several properties and their consequences in flax fibre reinforced composites. Polym. Test. 20, 885–893 (2001).

23. Xiong, H., Hamila, N. & Boisse, P. Consolidation Modeling during Thermoforming of Thermoplastic Composite Prepregs. Materials 12, 2853 (2019).

24. Petrie, C. S. & Walker, M. P. Effect of Airborne-Particle Abrasion and Aqueous Storage on Flexural Properties of Fiber-Reinforced Dowels: Flexural Properties of Fiber-Reinforced Dowels. J. Prosthodont. 21, 296–303 (2012).

25. Stewardson, D. A., Shortall, A. C., Marquis, P. M. & Lumley, P. J. The flexural properties of endodontic post materials. Dent. Mater. 26, 730–736 (2010).

26. Bao, L., Okazawa, T., Xu, A. & Shi, J. A simple repair method for GFRP delamination using ultraviolet-curable resin. Adv. Compos. Mater. 27, 249–259 (2018).

27. Rajamurugan, T. V., Shanmugam, K. & Palanikumar, K. Analysis of delamination in drilling glass fiber reinforced polyester composites. Mater. Des. 45, 80–87 (2013).

28. Bikiaris, D., Matzinos, P., Larena, A., Flaris, V. & Panayiotou, C. Use of silane agents and poly(propylene-g-maleic anhydride) copolymer as adhesion promoters in glass fiber/polypropylene composites. J. Appl. Polym. Sci. 81, 701–709 (2001).

29. Karsli, N. G., Yilmaz, T. & Gul, O. Effects of coupling agent addition on the adhesive wear, frictional and thermal properties of glass fiber-reinforced polyamide 6,6 composites. Polym. Bull. 75, 4429–4444 (2018).

30. Wu, H. F., Dwight, D. W. & Huff, N. T. Effects of silane coupling agents on the interphase and performance of glass-fiber-reinforced polymer composites. Compos. Sci. Technol. 57, 975–983 (1997).

31.       Mebarkia, S. & Vipulanandan, C. Coupling agent and glass fibers in polyester mortar. Polym. Eng. Sci. 34, 1287–1296 (1994).

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