Adhesive Property of 3D-Printed PEEK Abutments: Effects of Surface Treatment and Temporary Crown Material on Shear Bond Strength

Three-dimensionally printed polyetheretherketone (PEEK) materials are promising for fabricating customized dental abutments. This study aimed to investigate the adhesive property of a 3D-printed PEEK material. The effects of surface treatment and temporary crown materials on shear bond strength were...
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Autor*in:	Dingjie Wang [verfasserIn] Xingting Han [verfasserIn] Feng Luo [verfasserIn] Florian M. Thieringer [verfasserIn] Yichen Xu [verfasserIn] Guomin Ou [verfasserIn] Sebastian Spintzyk [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2022

Schlagwörter:	fused filament fabrication polyether ether ketone additive manufacturing shear bond strength temporary abutment dental implantology

Übergeordnetes Werk:	In: Journal of Functional Biomaterials - MDPI AG, 2011, 13(2022), 4, p 288
Übergeordnetes Werk:	volume:13 ; year:2022 ; number:4, p 288

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.3390/jfb13040288

Katalog-ID:	DOAJ083133739

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520			\|a Three-dimensionally printed polyetheretherketone (PEEK) materials are promising for fabricating customized dental abutments. This study aimed to investigate the adhesive property of a 3D-printed PEEK material. The effects of surface treatment and temporary crown materials on shear bond strength were evaluated. A total of 108 PEEK discs were 3D printed by fused-filament fabrication. Surface treatments, including sandblasting, abrasive paper grinding, and CO<sub<2</sub< laser ablation, were applied to the PEEK discs, with the untreated specimens set as the control. Afterward, the surface topographies of each group were investigated by scanning electron microscopy (SEM, <i<n</i< = 1) and roughness measurements (<i<n</i< = 7). After preparing the bonding specimens with three temporary crown materials (Artificial teeth resin (ATR), 3M™ Filtek™ Supreme Flowable Restorative (FR), and Cool Temp NATURAL (CTN)), the shear bond strength was measured (<i<n</i< = 6), and the failure modes were analyzed by microscopy and SEM. The results showed that ATR exhibited a significantly higher shear bond strength compared to FR and CTN (<i<p</i< < 0.01), and the PEEK surfaces treated by sandblasting and abrasive paper grinding showed a statistically higher shear bond strength compared to the control (<i<p</i< < 0.05). For clinical application, the ATR material and subtractive surface treatments are recommended for 3D-printed PEEK abutments.
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source	In Journal of Functional Biomaterials 13(2022), 4, p 288 volume:13 year:2022 number:4, p 288
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callnumber-first	T - Technology
author	Dingjie Wang
spellingShingle	Dingjie Wang misc TP248.13-248.65 misc R5-920 misc fused filament fabrication misc polyether ether ketone misc additive manufacturing misc shear bond strength misc temporary abutment misc dental implantology misc Biotechnology misc Medicine (General) Adhesive Property of 3D-Printed PEEK Abutments: Effects of Surface Treatment and Temporary Crown Material on Shear Bond Strength
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topic_title	TP248.13-248.65 R5-920 Adhesive Property of 3D-Printed PEEK Abutments: Effects of Surface Treatment and Temporary Crown Material on Shear Bond Strength fused filament fabrication polyether ether ketone additive manufacturing shear bond strength temporary abutment dental implantology
topic	misc TP248.13-248.65 misc R5-920 misc fused filament fabrication misc polyether ether ketone misc additive manufacturing misc shear bond strength misc temporary abutment misc dental implantology misc Biotechnology misc Medicine (General)
topic_unstemmed	misc TP248.13-248.65 misc R5-920 misc fused filament fabrication misc polyether ether ketone misc additive manufacturing misc shear bond strength misc temporary abutment misc dental implantology misc Biotechnology misc Medicine (General)
topic_browse	misc TP248.13-248.65 misc R5-920 misc fused filament fabrication misc polyether ether ketone misc additive manufacturing misc shear bond strength misc temporary abutment misc dental implantology misc Biotechnology misc Medicine (General)
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title	Adhesive Property of 3D-Printed PEEK Abutments: Effects of Surface Treatment and Temporary Crown Material on Shear Bond Strength
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title_full	Adhesive Property of 3D-Printed PEEK Abutments: Effects of Surface Treatment and Temporary Crown Material on Shear Bond Strength
author_sort	Dingjie Wang
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author_browse	Dingjie Wang Xingting Han Feng Luo Florian M. Thieringer Yichen Xu Guomin Ou Sebastian Spintzyk
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author-letter	Dingjie Wang
doi_str_mv	10.3390/jfb13040288
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title_sort	adhesive property of 3d-printed peek abutments: effects of surface treatment and temporary crown material on shear bond strength
callnumber	TP248.13-248.65
title_auth	Adhesive Property of 3D-Printed PEEK Abutments: Effects of Surface Treatment and Temporary Crown Material on Shear Bond Strength
abstract	Three-dimensionally printed polyetheretherketone (PEEK) materials are promising for fabricating customized dental abutments. This study aimed to investigate the adhesive property of a 3D-printed PEEK material. The effects of surface treatment and temporary crown materials on shear bond strength were evaluated. A total of 108 PEEK discs were 3D printed by fused-filament fabrication. Surface treatments, including sandblasting, abrasive paper grinding, and CO<sub<2</sub< laser ablation, were applied to the PEEK discs, with the untreated specimens set as the control. Afterward, the surface topographies of each group were investigated by scanning electron microscopy (SEM, <i<n</i< = 1) and roughness measurements (<i<n</i< = 7). After preparing the bonding specimens with three temporary crown materials (Artificial teeth resin (ATR), 3M™ Filtek™ Supreme Flowable Restorative (FR), and Cool Temp NATURAL (CTN)), the shear bond strength was measured (<i<n</i< = 6), and the failure modes were analyzed by microscopy and SEM. The results showed that ATR exhibited a significantly higher shear bond strength compared to FR and CTN (<i<p</i< < 0.01), and the PEEK surfaces treated by sandblasting and abrasive paper grinding showed a statistically higher shear bond strength compared to the control (<i<p</i< < 0.05). For clinical application, the ATR material and subtractive surface treatments are recommended for 3D-printed PEEK abutments.
abstractGer	Three-dimensionally printed polyetheretherketone (PEEK) materials are promising for fabricating customized dental abutments. This study aimed to investigate the adhesive property of a 3D-printed PEEK material. The effects of surface treatment and temporary crown materials on shear bond strength were evaluated. A total of 108 PEEK discs were 3D printed by fused-filament fabrication. Surface treatments, including sandblasting, abrasive paper grinding, and CO<sub<2</sub< laser ablation, were applied to the PEEK discs, with the untreated specimens set as the control. Afterward, the surface topographies of each group were investigated by scanning electron microscopy (SEM, <i<n</i< = 1) and roughness measurements (<i<n</i< = 7). After preparing the bonding specimens with three temporary crown materials (Artificial teeth resin (ATR), 3M™ Filtek™ Supreme Flowable Restorative (FR), and Cool Temp NATURAL (CTN)), the shear bond strength was measured (<i<n</i< = 6), and the failure modes were analyzed by microscopy and SEM. The results showed that ATR exhibited a significantly higher shear bond strength compared to FR and CTN (<i<p</i< < 0.01), and the PEEK surfaces treated by sandblasting and abrasive paper grinding showed a statistically higher shear bond strength compared to the control (<i<p</i< < 0.05). For clinical application, the ATR material and subtractive surface treatments are recommended for 3D-printed PEEK abutments.
abstract_unstemmed	Three-dimensionally printed polyetheretherketone (PEEK) materials are promising for fabricating customized dental abutments. This study aimed to investigate the adhesive property of a 3D-printed PEEK material. The effects of surface treatment and temporary crown materials on shear bond strength were evaluated. A total of 108 PEEK discs were 3D printed by fused-filament fabrication. Surface treatments, including sandblasting, abrasive paper grinding, and CO<sub<2</sub< laser ablation, were applied to the PEEK discs, with the untreated specimens set as the control. Afterward, the surface topographies of each group were investigated by scanning electron microscopy (SEM, <i<n</i< = 1) and roughness measurements (<i<n</i< = 7). After preparing the bonding specimens with three temporary crown materials (Artificial teeth resin (ATR), 3M™ Filtek™ Supreme Flowable Restorative (FR), and Cool Temp NATURAL (CTN)), the shear bond strength was measured (<i<n</i< = 6), and the failure modes were analyzed by microscopy and SEM. The results showed that ATR exhibited a significantly higher shear bond strength compared to FR and CTN (<i<p</i< < 0.01), and the PEEK surfaces treated by sandblasting and abrasive paper grinding showed a statistically higher shear bond strength compared to the control (<i<p</i< < 0.05). For clinical application, the ATR material and subtractive surface treatments are recommended for 3D-printed PEEK abutments.
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container_issue	4, p 288
title_short	Adhesive Property of 3D-Printed PEEK Abutments: Effects of Surface Treatment and Temporary Crown Material on Shear Bond Strength
url	https://doi.org/10.3390/jfb13040288 https://doaj.org/article/c949b6c9f7724f429876c593a3f73238 https://www.mdpi.com/2079-4983/13/4/288 https://doaj.org/toc/2079-4983
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author2	Xingting Han Feng Luo Florian M. Thieringer Yichen Xu Guomin Ou Sebastian Spintzyk
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up_date	2024-07-03T15:43:20.092Z
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The results showed that ATR exhibited a significantly higher shear bond strength compared to FR and CTN (<i<p</i< < 0.01), and the PEEK surfaces treated by sandblasting and abrasive paper grinding showed a statistically higher shear bond strength compared to the control (<i<p</i< < 0.05). 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Adhesive Property of 3D-Printed PEEK Abutments: Effects of Surface Treatment and Temporary Crown Material on Shear Bond Strength

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