The Effect of Polishing and Thermocycling on the Surface Roughness of Two Nanohybrid Composites
Harish Selvaraj1, Subash Sharma.S2*
1 Post Graduate Student, Department of Conservative Dentistry and Endodontics, Saveetha Dental College and Hospital, Saveetha Institute of Medical
and Technical Sciences, Saveetha University, Chennai 600077, Tamil Nadu, India.
2 Reader, Department of Conservative Dentistry and Endodontics, Saveetha Dental College and Hospital, Saveetha Institute of Medical and Technical Sciences, Saveetha University, Chennai 600077, Tamil Nadu, India.
*Corresponding Author
Subash Sharma,
Reader, Department of Conservative Dentistry and Endodontics, Saveetha Dental College and Hospital, Saveetha Institute of Medical and Technical Sciences, Saveetha University,
Chennai 600077, Tamil Nadu, India.
Tel: +91-9884533118
E-mail: drsubashsharma@gmail.com
Received: May 19, 2021; Accepted: August 11, 2021; Published: August 18, 2021
Citation:Harish Selvaraj, Subash Sharma.S. The Effect of Polishing and Thermocycling on the Surface Roughness of Two Nanohybrid Composites. Int J Dentistry Oral Sci. 2021;8(8):3941-3944. doi: dx.doi.org/10.19070/2377-8075-21000806
Copyright: Subash Sharma©2021. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited.
Abstract
Objective: This study aimed to investigate the effect of polishing and thermocycling on the surface roughness of two nanohybrid
composites.
Materials and Methods: Two nanofilled composites were used. The surface roughness (Ra) was initially measured in a profilometer
using a cut-off of 0.25 mm, after 1000 thermal cycles. Data were subjected to Paired Samples t-test and Independent
Samples t-test (a = 0.05).
Results: Overall, 1000 thermal cycles slightly increased the surface roughness values for both the materials used. It was found
that there existed a statistically significant difference between the individual groups before and after thermocycling (p<0.05)
and there was no statistically significant difference between the groups after thermocycling (p>0.05).
Conclusion: Thermocycling increased surface roughness of both the composites. When the post thermocycling surface
roughness values of Filtek Z350XT and Polofil NHT were compared, no significant differences were observed.
2.Introduction
3.Conclusion
4.References
Keywords
Roughness; Composite Resin; Degradation.
Introduction
Composite resin has been available as an aesthetic material for
restorative procedures since the early 1960s [1]. A resin matrix
and filler particles are chemically connected by silane coupling
agents in a composite material. For direct dental restorations,
a variety of composite materials are available, including microhybrid,
microfilled, and nanofilled composites [2]. These varied
filler forms of resin composite materials affect both their handling
characteristics and physical properties. The final surface
polish has an important effect on the final aesthetics of these
tooth-colored restoratives. Mechanical degradation can vary depending
on the monomer system, filler composition, and matrixfiller
coupling agent of composite resins. Damage to composites
has been identified as a result of matrix degradation, which
may reduce the likelihood of polymer restorations surviving in
vivo. The surface smoothness of composite resins is directly affected
by the composition of the resin matrix, coupling agent,
and filler particle characteristics [3]. The most important factors
are the form of inorganic particles, their size, and the extent of
filler filling. Plaque accumulation, staining susceptibility, and wear
have all been shown to be influenced by the surface roughness of
restorative materials [4, 5]. Dental plaque accumulation may increase
the risk of both caries and periodontal inflammation if the
restoration has a surface roughness of 0.2 mm (Ra) or more [6].
During the restorative process, successful finishing and polishing
procedures can increase surface smoothness and compensate
for surface roughness caused by wear mechanisms on restorations
[7]. Proper finishing and polishing of dental restoratives enhance
the esthetics and longevity of restorations [8].
Hydrolytic degradation can affect the mechanical properties of
composite resin [9]. Long-term water storage and thermal cycling
are considered important conditions to assess the stability of resin bonds in in vitro studies [10]. Furthermore, the roughness of
certain resin-based products may be altered by the toothbrushing
and thermocycling processes, which can affect the composite restoration’s
durability [11]. In this way, the analysis of surface roughness
of resin-based materials, as well as the impact of degradation
on this property, is critical for aesthetic restorations to last. As a
result, the surface roughness of two nanofilled composite resins
subjected to thermocycling procedures after polishing was investigated
in this study. Previously our team had a rich experience in
working on various research projects across multiple disciplines
[12-26]. Now the growing trend in this area motivated us to pursue
this project. The research hypothesis is that the thermocycling
process could affect the roughness of two different materials due
to differences in structure between composites, such as filler form
and resinous matrix.
Materials And Methods
The materials used in this study are two nanohybrid composites,
Polofil® NHT (VOCO) which has nano scaled particles with glass
ceramic fillers with particle size of 0.01-0.1 µm and filler fraction
of 83/68 Wt. %, Vol. %. and Filtek™ Z350 XT Universal Restorative
(3M) in which the resin contains bis-GMA, UDMA, TEGDMA,
and bis-EMA resins, PEGDMA and Non-agglomerated/
non-aggregated 20 nm silica filler, non-agglomerated/non-aggregated
4 to 11 nm zirconia filler, and aggregated zirconia/silica
cluster filler are among the fillers (comprised of 20 nm silica and
4 to 11 nm zirconia particles). A metal mold (2 mm in thickness
and 6.2 mm in diameter) was used to produce ten samples of each
resin-based composite, for a total of 20 composite disk samples.
On the top and bottom of the molds, a mylar strip was placed,
and the cavity was fully filled with composite resin. A thin glass
plate was placed over the composite, and using a variable intensity
light curing unit (Bluephase NM), the samples were light-cured
for 60 seconds. All samples were then finished and polished using
Shofu Super Snap Rainbow Technique Kit Ca using a low-speed
handpiece (11,000 rpm).
The surface roughness value (Ra) was measured in a profilometer
SJ-310, (Mitutoyo Corp., Tokyo, Japan). The Ra value was chosen
because it reflects the arithmetical mean of surface roughness
and is the most commonly used parameter for this reason. Each
measurement was taken after rotating the sample 120 degrees and
taking three measurements with a 0.25 mm cut-off. The samples
were then held at 37 degrees Celsius in distilled water until the
thermal cycling process began. Thermal cycling (alternate immersion
of samples in distilled water with a temperature of 5 and 55
degree celsius, 5 min each and a transfer interval of 5 s) was carried
out in a thermal cycler Chewing Simulator CS-4 thermal cycling
machine (SD Mechatronik). Roughness measurements were
collected after 3000 thermal cycles. The paired samples t-test was
used to compare the surface roughness values before and after
the thermocycling procedure between individual groups and independent
samples t-test to compare the surface roughness values
after the thermocycling procedure between Filtek Z350 XT and
Polofil NHT.
Results & Discussion
While the two composites were compared individually before and
after thermocycling procedure there existed a statistically significant
difference (P<0.05).
While the surface roughness values were compared after thermocycling
procedure between Filtek Z350 XT and Polofil NHT, it
was found that there was no statistically significant difference between
the groups after thermocycling (P>0.05)
Table 1 shows the surface roughness of the two nanohybrid composites
before and after 1000 thermal cycles. After 1000 thermal cycles there was a slight increase in surface roughness of both the
materials. VOCO Polofil showed lesser values of surface roughness
compared to Filtek Z350 XT but there was no statistically
significant difference after thermocycling (P>0.05).
Thermocycling had a critical impact on surface roughness of
composite resins, regardless of the filler composition, according
to the results of this in vitro study. Both the resin-based materials
showed an increase in roughness values after polishing and 1000
thermal cycles. Previous studies also showed that thermal cycling
significantly affected the surface texture of composites with dislodgement
of filler particles [27, 28]. Restorations should be finished
properly not only for aesthetic reasons, but also for oral
health reasons. Finishing's main objective is to develop a restoration
with good contour, occlusion, natural embrasure forms, and
a smooth surface. Bacterial adhesion to the surface of composite
resins and other dental restorative materials is a key factor in secondary
caries growth [29, 30]. Hardness of material is defined
as its resistance to permanent surface indentation or penetration,
and this property is related to material strength, ductility, elastic
stiffness, plasticity, strain, toughness, viscoelasticity, and viscosity
[30, 31]. The surface quality of composite resins can also be affected
by the composition, degree of conversion, finishing, and
polishing procedures. As a result, the microstructure of composite
resins, as well as the finishing and polishing processes used to
modify their surface, have an effect on their surface finish [32].
There was no noticeable difference in plaque accumulation between
surfaces polished using different methods that resulted in
standard surface Ra values in the range of 0.7–1.4 m, according
to the literature. Using a surface profilometer, the Ra value was
mostly determined in each sample after the finishing and polishing
procedures were completed according to the manufacturer's
instructions [33, 34].
The number of cycles, different temperatures, dwell time, and intervals
between baths used in the studies is associated in thermocycling
makes clinical durability of dental composites compared,
difficult.
Temperature changes have been applied to thermocycled samples,
causing thermal stresses and microcracks in the matrix or failure
at the filler/matrix interface [35]. Furthermore, exposure to water
can result in hydrolytic degradation of the filler's silane coating
or matrix swelling. After thermal cycling, differences in filler exposure
are most probably related to matrix degradation, which
exposes underlying filler particles and increases roughness. Composites
with hydrophilic matrix components, such as TEGDMA,
may be more prone to matrix degradation as they allow water to
penetrate more easily due to its hydrophobicity [36]. This might
be related to the higher surface roughness after thermocycling
of Filtek Z350XT composite material which contains hydrophilic
component TEGDMA. The surface roughness of a composite
is determined by the size, hardness, and amount of filler used,
which improves the mechanical properties of resin-based composites
[37, 38]. According to a study, the depth of composite
wear decreased uniformly as the filler level was increased. Since
microfill composites have less particle fillers in their structure,
they are more likely to be affected by increased thermal cycles [39].
The material composition, including the type of organic matrix,
can influence the preservation of roughness over time [40]. Two
nanohybrid composites have been used in the study with 83%
filler for VOCO Polofil and 78.5% filler loading for Z350XT. This
difference in the filler loading and higher filler loading in VOCO
Polofil compared to Z350XT might be the reason for lesser surface
roughness values of Polofil composite material. The 83% of
fillers in composition of this Polofil including agglomerated and
non-agglomerated nanofillers could account for this result.
The arithmetic average value of the deviation from profile from
centerline is represented by the surface roughness parameter
(Ra) [11, 40]. Both the nanohybrid composites used in the study
showed roughness under the limit proposed by the literature (0.2
mm). The increase in roughness after thermocycling procedures
could result in a variety of problems, including surface staining,
dental plaque accumulation, and occluding tooth wear. Furthermore,
organic matrices in composites may have absorbed some
water, causing hygroscopic expansion in the resinous matrix and
filler process, resulting in matrix–filler interface weakening [4, 11].
Also the use of polishing systems could be limited to the real accessibility
and uniformity of the surfaces to be finished. Further
research is needed to assess the most effective finishing procedure
in clinical practice to achieve the best possible clinical outcomes.
Our institution is passionate about high quality evidence based
research and has excelled in various fields ( [16], [41-50]).
Table 1: Surface roughness (Ra, µmm) means (SD) of the resin-based composites before and after thermal cycling.
Table 2: represents paired samples T-test which compared the surface roughness values before and after thermocycling procedure between individual groups. It was found that there existed a statistically significant difference between the individual groups before and after thermocycling (p<0.05).
Table 3 : represents an independent T-test which compared the surface roughness values after the thermocycling procedure between Filtek Z350 XT and Polofil NHT. It was found that there was no statistically significant difference between the groups after thermocycling (p>0.05).
Conclusion
Within the limits of this in-vitro study it can be concluded that
polishing and thermocycling increased the roughness values for
both the nanohybrid composites and the composition of the material,
including the form of organic matrix, particle fillers influences
in maintaining roughness over time.
References
-
[1]. Narayanan AS. Connective tissues of the periodontium: a summary of current
work. Coll Rei Res. 1983 Jan 1;3(1):33-64.
[2]. Narayanan AS, Page RC, Meyers DF. Characterization of collagens of diseased human gingiva. Biochem. 1980 Oct 1;19(22):5037-43.
[3]. Narayanan AS, Page RC, Kuzan F. Collagens synthesized in vitro by diploid fibroblasts obtained from chronically inflamed human connective tissue. Lab Invest. 1978 Jul;39(1):61-5.Pubmed PMID: 682592.
[4]. Page RC. Biochemical aspects of the connective tissue alterations in inflammatory gingival and periodontal disease. Int. dent. J.. 1973;23:455-69.
[5]. Page RC, Schroeder HE. Pathogenesis of inflammatory periodontal disease. A summary of current work. Lab. Invest. 1976 Mar 1;33(3):235-49.
[6]. Page RC, Narayanan AS, Schroeder HE. Connective tissue composition and collagen synthesis in diseased and normal gingiva of adult dogs with spontaneous periodontitis. Arch Oral Biol. 1980;25(11-12):727-36.Pubmed PMID: 6943992.
[7]. Grant DA, Stern IB, Listgarten MA. Periodontics in the Tradition of Gottlieb and Orban, 6th ed. St. Louis: The C.V. Mosby Co.; 1988;41- 44
[8]. Page RC, Simpson DM, Ammons WF, Schectman LR. Host tissue response in chronic periodontal disease: III. Clinical, histopathologic and ultrastructural features of advanced disease in a colony-maintained marmoset. J. Periodontal Res. 1972 Aug;7(4):283-96.
[9]. Carneiro J, Leblond CP. Suitability of collagenase treatment for the radioautographic identification of newly synthesized collagen labelled with 3Hglycine or 3H-proline. J Histochem Cytochem 1966;14:334- 344.
[10]. Sodek J. Collagen turnover in periodontal ligament. In: Norton LA, Burstone CJ, eds. The Biology of Tooth Movement. Boca Raton, FL: CRC Press, Inc.; 1989:167-181.
[11]. Page RC, Ammons WF. Collagen turnover in the gingiva and other mature connective tissues of the marmoset Saguinus oedipus. Arch Oral Biol. 1974 Aug;19(8):651-8.Pubmed PMID: 4217619.
[12]. Sodek J. A new approach to assessing collagen turnover by using a microassay. A highly efficient and rapid turnover of collagen in rat periodontal tissues. Biochem J. 1976 Nov 15;160(2):243-6.Pubmed PMID: 1008854.
[13]. Sodek J. A comparison of collagen and non-collagenous protein metabolism in rat molar and incisor periodontal ligaments. Arch Oral Biol. 1978;23(11):977-82.Pubmed PMID: 285652.
[14]. Udenfriend S. Formation of hydroxyproline in collagen. Science. 1966 Jun 3;152(3727):1335-40.
[15]. Whitehead RG. Hydroxyproline creatinine ratio as an index of nutritional status and rate of growth. Lancet. 1965 Sep 18;2(7412):567-70.Pubmed PMID: 4158193.
[16]. Svanberg GK. Hydroxyproline determination in serum and gingival crevicular fluid. J Periodontal Res. 1987 Mar;22(2):133-8.Pubmed PMID: 2953884.
[17]. Hara K, Takahashi T. Hydroxyproline content in gingival exudate before and after periodontal surgery. J Periodontal Res. 1975 Nov;10(5):270-4.Pubmed PMID: 129549.
[18]. Paunio K. On the hydroxyproline-Containing components in the gingival exudate. J. Periodontal Res. 1971 Apr;6(2):115-7.
[19]. Svanberg GK. Hydroxyproline titers in gingival crevicular fluid. J Periodontal Res. 1987 May;22(3):212-4.Pubmed PMID: 2955100.
[20]. Wynkoop JR, Woodyard S, Miller RA. A comparison of individual crevicular fluid hydroxyproline levels to periodontal assessments. J Dent Res. 1982;61:315.
[21]. Miller RA, Wynkoop JR, Johannsen K. Analysis of hydroxyproline in gingival exúdate by high performance liquid chromatography. Dent Res. 1982;61:275.
[22]. Silness J, Loe H. Periodontal Disease in Pregnancy. Ii. Correlation between Oral Hygiene and Periodontal Condtion. Acta Odontol Scand 1964;22:121- 135
[23]. Greene JG, Vermillion JR. The simplified oral hygiene index. J Am Dent Assoc. 1964 Jan 1;68(1):7-13.
[24]. Russell AL. The periodontal index. J. Periodontol. 1967 Nov 1;38(6):Suppl- 585.
[25]. Cimasoni. G. Crevicular fluid updated. Monogr. Oral Sci.1983;12 . [26]. Pashley D. A mechanistic analysis of gingival fluid production. J. Periodontal Res. 1976 Apr;11(2):121-34.
[27]. Subrahmanyam MV, Sangeetha M. Gingival crevicular fluid a marker of the periodontal disease activity. Indian J Clin Biochem. 2003 Jan 1;18(1):5-7.
[28]. Koss MA, Castro CE, Salúm KM, Kishimoto E, Takagi S, López ME. Gingival crevicular fluid biomarkers in patients with gingivitis and chronic periodontitis. J. Hard Tissue Biol. 2010;19(2):111-6.
[29]. Johnston CS, Cartee GD, Haskell BE. Effect of ascorbic acid nutriture on protein-bound hydroxyproline in guinea pig plasma. J. Nutr. 1985 Aug 1;115(8):1089-93.
[30]. Akalin FA, Sengün D, Eratalay K, Renda N, Caglayan G. Hydroxyproline and total protein levels in gingiva and gingival crevicular fluid in patients with juvenile, rapidly progressive, and adult periodontitis. J Periodontol. 1993 May;64(5):323-9.Pubmed PMID: 8515361.
[31]. Koss MA, Castro C, Salúm KM, López ME. Changes in saliva protein composition in patients with periodontal disease. Acta Odontol Latinoam. 2009 Sep;22(2):105-12.
