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Materiale Plastice
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https://doi.org/10.37358/Mat.Plast.1964

OSIM Nr. R102356
ISSN Print 0025-5289
ISSN Online 2668-8220
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Materiale Plastice (Mater. Plast.), Year 2017, Volume 54, Issue 1, 29-31

https://doi.org/10.37358/MP.17.1.4778

Alin Gabor, Tiberiu Hosszu, Cristian Zaharia, Alexandru Kozma, Andreea Codruta Cojocariu, Meda Lavinia Negrutiu, Camelia Szuhanek, Cosmin Sinescu

3D Printing of a Mandibular Bone Deffect


Abstract:
The aim of this study was to achieve a polymeric scaffold, ex-vivo, using 3D printing technology and then subjecting it to various tests to check its optimal property. Initially there was selected a lower jaw with a bone defect that would have prevented any treatment based prosthetic implant. The mandible was first scanned using an optical scanner (MAESTRO DENTAL SCANNER MDS400). The scanning parameters using optical scanning system are: 10 micron accuracy, resolution 0.07 mm, 2 rooms with High-Resolution LED structured light, two axes. The scan time of the mandible was 4-5 min. Later the same mandible was scanned using CBCT’s CRANEX 3DX. The images obtained using CBCT’s were correlated with those obtained by optical scanning. Further on, there was achieved the digital design of the future scaffold with the conventional technique of wax addition directly on the mandibular bone defect. After that, this was again scanned using scanning system MAESTRO DENTAL SCANNER MDS400, and using CBCT’s CRANEX 3DX. The images obtained were correlated with all the scanned images of original mandible bone defects. There were made two polymeric scaffolds using 3D printing system an (D20 Digital Wax System 3D Printer). After printing, scaffold sites were introduced for 30 minutes in an oven curing. Later the pieces obtained were processed to remove small excesses of work. There were obtained 3 blocks of polymers that have a good adaptation to the bone profile. Often, in oral implantology and maxillofacial surgery appear bone defects. They prevent an optimal treatment of bio-functional and aesthetic restoration. Using 3D printing technology one can achieve scaffold sites of different biocompatible materials that have optimal properties to replace bone defect and restore the defective area. These scaffold sites have an intimate adaptation to the defect. 3D printing techniques used to restore bone defects can quickly and efficiently give the possibility to have a successful implantology prosthetics treatment.


Keywords:
polymeric scaffold; 3D printing technology ; prosthetic implant; bone defects

Issue: 2017 Volume 54, Issue 1
Pages: 29-31
Publication date: 2017/3/30
https://doi.org/10.37358/MP.17.1.4778
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Creative Commons License
This article is published under the Creative Commons Attribution 4.0 International License
Citation Styles
Cite this article as:
GABOR, A., HOSSZU, T., ZAHARIA, C., KOZMA, A., COJOCARIU, A.C., NEGRUTIU, M.L., SZUHANEK, C., SINESCU, C., 3D Printing of a Mandibular Bone Deffect, Mater. Plast., 54(1), 2017, 29-31.

Vancouver
Gabor A, Hosszu T, Zaharia C, Kozma A, Cojocariu AC, Negrutiu ML, Szuhanek C, Sinescu C. 3D Printing of a Mandibular Bone Deffect. Mater. Plast.[internet]. 2017 Jan;54(1):29-31. Available from: https://doi.org/10.37358/MP.17.1.4778


APA 6th edition
Gabor, A., Hosszu, T., Zaharia, C., Kozma, A., Cojocariu, A.C., Negrutiu, M.L., Szuhanek, C. & Sinescu, C. (2017). 3D Printing of a Mandibular Bone Deffect. Materiale Plastice, 54(1), 29-31. https://doi.org/10.37358/MP.17.1.4778


Harvard
Gabor, A., Hosszu, T., Zaharia, C., Kozma, A., Cojocariu, A.C., Negrutiu, M.L., Szuhanek, C., Sinescu, C. (2017). '3D Printing of a Mandibular Bone Deffect', Materiale Plastice, 54(1), pp. 29-31. https://doi.org/10.37358/MP.17.1.4778


IEEE
A. Gabor, T. Hosszu, C. Zaharia, A. Kozma, A.C. Cojocariu, M.L. Negrutiu, C. Szuhanek, C. Sinescu, "3D Printing of a Mandibular Bone Deffect". Materiale Plastice, vol. 54, no. 1, pp. 29-31, 2017. [online]. https://doi.org/10.37358/MP.17.1.4778


Text
Alin Gabor, Tiberiu Hosszu, Cristian Zaharia, Alexandru Kozma, Andreea Codruta Cojocariu, Meda Lavinia Negrutiu, Camelia Szuhanek, Cosmin Sinescu,
3D Printing of a Mandibular Bone Deffect,
Materiale Plastice,
Volume 54, Issue 1,
2017,
Pages 29-31,
ISSN 2668-8220,
https://doi.org/10.37358/MP.17.1.4778.
(https://revmaterialeplastice.ro/Articlegs.asp?ID=4778)
Keywords: polymeric scaffold; 3D printing technology ; prosthetic implant; bone defects


RIS
TY - JOUR
T1 - 3D Printing of a Mandibular Bone Deffect
A1 - Gabor, Alin
A2 - Hosszu, Tiberiu
A3 - Zaharia, Cristian
A4 - Kozma, Alexandru
A5 - Cojocariu, Andreea Codruta
A6 - Negrutiu, Meda Lavinia
A7 - Szuhanek, Camelia
A8 - Sinescu, Cosmin
JF - Materiale Plastice
JO - Mater. Plast.
PB - Materiale Plastice SRL
SN - 2668-8220
Y1 - 2017
VL - 54
IS - 1
SP - 29
EP - 31
UR - https://doi.org/10.37358/MP.17.1.4778
KW - polymeric scaffold
KW - 3D printing technology
KW - prosthetic implant
KW - bone defects
ER -


BibTex
@article{MatPlast2017P29,
author = {Gabor Alin and Hosszu Tiberiu and Zaharia Cristian and Kozma Alexandru and Cojocariu Andreea Codruta and Negrutiu Meda Lavinia and Szuhanek Camelia and Sinescu Cosmin},
title = {3D Printing of a Mandibular Bone Deffect},
journal = {Materiale Plastice},
volume = {54},
number = {1},
pages = {29-31},
year = {2017},
issn = {2668-8220},
doi = {https://doi.org/10.37358/MP.17.1.4778},
url = {https://revmaterialeplastice.ro/Articlegs.asp?ID=4778}
}
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