In vitro study of microleakage of endodontically treated teeth restored with different adhesive systems and fiber-reinforced posts

Joon-Ho Park; Yu-Sung Choi

doi:10.4047/jkap.2014.52.2.74

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Park and Choi: In vitro study of microleakage of endodontically treated teeth restored with different adhesive systems and fiber-reinforced posts

ORIGINAL ARTICLE

J Korean Acad Prosthodont 2014;52(2):74-81.

Published online: 18 January 2014

DOI: https://doi.org/10.4047/jkap.2014.52.2.74

In vitro study of microleakage of endodontically treated teeth restored with different adhesive systems and fiber-reinforced posts

Joon-Ho Park, Yu-Sung Choi^∗

Department of Prosthodontics, College of Dentistry, Dankook University, Cheoan, Republic of Korea

∗Corresponding Author: Yu-Sung Choi Department of Prosthodontics, College of Dentistry, Dankook University Dandaero 119, Dongnamgu, Cheonan, 330-714, Republic of Korea +82 41 550 1979: e-mail, yu0324@hanmail.net

Received 25 February 20148 April 2014 Accepted 14 April 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Purpose

While studies have examined microleakage in endodontically treated teeth restored with posts, microleakage among post and adhesive systems remains a concern. This study compared the sealing properties of 3 adhesively luted post systems.

Materials and methods

Thirty-six endodontically treated permanent maxillary central incisors were divided into 3 groups: Zirconia-glass fiber, Quartz-glass fiber, Polyethylene fiber posts. Post space was prepared and each post was adhesively luted with 3 systems. The specimens were separately immersed in freshly prepared 2% methylene blue solution for 1 week. The cleaned specimens were then embedded in autopolymerizing acrylic resin. The root portion of tooth were horizontally sectioned into three pieces (apical, middle, and coronal portions). An occlusal view of each section was digitally photographed with a stereomicroscope. The methylene blue-infiltrated surface for each specimen was measured. Dye penetration was estimated as the ratio of the methylene blue-infiltrated surface to the total dentin surface.

Results

No significant differences were found among post types. The variables of middle section and 3-stage adhesive produced significant differences in microleakage between the following post pairs: zirconia-glass fiber versus quartz-glass fiber, zirconia-glass fiber versus polyethylene fiber, and quartz-glass fiber versus polyethylene fiber (P<.05). There were significant differences between the apical and coronal sections of each post type, and between apical versus middle sections of quarze-glass fiber and polyethylene fiber posts (P<.05).

Conclusion

No significant differences were found among post types. The 3-stage adhesive produced significant differences in microleakage between the following post pairs. (J Korean Acad Prosthodont 2014;52:74-81)

Keywords: Fiber-reinforced post, Adhesive systems, Microleakage, Resin cement

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Table 1.

Description and manufacturer information for materials evaluated

Product	Material Type	Manufacturer
D.T. Light-post	Preshaped quartz-glass fiber	Bisco, Schaumburg, IL, USA
Snowpost	Preshaped zirconia-glass fiber	Carbotech, Ganges, France
Ribbond	Custom-shaped polyethylene fiber	Ribbond Inc, Seattle, WA, USA
All Bond 2	3-stage total-etch adhesive	Bisco, Schaumburg, IL, USA
One Step Plus	2-stage total-etch adhesive	Bisco, Schaumburg, IL, USA
AQ Bond	1-stage self-etch adhesive	Sun Medical Co., Kyoto, Japan
Duolink	Dual-polymerizing resin luting agent	Bisco, Schaumburg, IL, USA
Light-Core	Light-polymerizing core foundation composite resin	Bisco, Schaumburg, IL, USA

Table 2.

Results of Mann-Whitney U tests comparing adhesives by region (n=12)

Adhesive	Section	Mean Rank	Sum of Ranks	Mann-Whitney U	P
All bond 2	Apical	11.94	206	71	.10
	Middle	19.06	320
	Apical	8.44	150	14	<.001
	Coronal	22.56	376
	Middle	10.09	176	40.5	.001
	Coronal	20.91	350
One Step Plus	Apical	13.56	232	96	.123
	Middle	17.44	294
	Apical	9.38	165	29	<.001
	Coronal	21.63	361
	Middle	10.94	190	54	.004
	Coronal	20.06	336
AQ bond	Apical	12.00	207	71	.007
	Middle	19.00	319
	Apical	8.38	149	14	<.001
	Coronal	22.63	377
	Middle	11.38	197	61	.011
	Coronal	19.63	329

P<.05 denotes significant difference.

Table 3.

Results of Mann-Whitney U tests comparing posts by region (n=12)

Post	Section	Mean Rank	Sum of Ranks	Mann-Whitney U	P
Quartz-glass fiber	Apical	7.88	106	27.5	.006
	Middle	15.13	193
	Apical	6.25	86	8	<.001
	Coronal	16.75	212
	Middle	8.75	116	38	.056
	Coronal	14.25	182
Zirconia-glass fiber	Apical	10.08	132	54	.221
	Middle	12.92	166
	Apical	6.17	85	7	<.001
	Coronal	16.83	213
	Middle	7.00	95	17	.001
	Coronal	16.00	203
Polyethylene fiber	Apical	8.50	113	35	.005
	Middle	14.50	185
	Apical	7.00	95	17	<.001
	Coronal	16.00	203
	Middle	9.25	122	44	.108
	Coronal	13.75	176

P<.05 denotes significant difference.

Table 4.

Mann-Whitney test results comparing posts according to middle region and adhesive (All Bond 2) (n=12)

Section	Adhesive	Post	Mean Rank	Sum of Ranks	Mann-Whitney U	P
		Quartz-glass fiber	5.50	25	0	.13
		Zirconia-glass fiber	1.50	9
Middle	All bond 2	Quartz-glass fiber	5.50	25	0	.20
Middle	All bond 2	Polyethylene fiber	1.50	9
		Zirconia-glass fiber	2.00	11	2	.46
		Polyethylene fiber	5.00	23

P<.05 denotes significant difference.

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