Evaluation of Hardness and Fracture Toughness of Feldspathic Porcelain by Various Surface Finishing Techniques
Correspondence Address :
Hariharan Ramakrishnan,
Professor, Department of Prosthodontics, Ragas Dental College and Hospital, East Coast Road, Uthandi, Chennai-600119, Tamil Nadu, India.
E-mail: abcv2005@yahoo.com
Introduction: Dental porcelain is fired at a high temperature inside the furnace and subsequently glazed for intraoral use as a restoration. There is no clarity on the correlation between physical properties of porcelain and its surface finishing techniques.
Aim: To evaluate surface hardness and fracture toughness of feldspathic porcelain with different porcelain surface finishing methods.
Materials and Methods: This in-vitro descriptive study was conducted between November 2018 to August 2019 at Department of Prosthodontics, Ragas Dental College and Hospital, Tamil Nadu, India, with 40 samples of Nickel Chrome (NiCr) alloy specimens, with addition of porcelain. The sample were divided into four groups S1: Unpolished, S2: Polished, S3: Autoglazed, S4: Add-on glaze according to the finishing procedures used with each group containing 10 samples. All samples were tested for surface hardness and Fracture toughness and were subjected to One-way Analysis of Variance (ANOVA), Bonferroni posthoc tests and Statistical Package of the Social Sciences (SPSS) California, USA.
Results: Mean value of fracture toughness (in MPa1/2) for 0.2Â kg load was 0.729672 for S1, 1.187567 for S2, 0.89482 for S3, 1.324399 for S4. Mean value of surface hardness (in kg/mm2) for 1 kg load was 360.048 for S1, 519.166 for S2, 508.817 for S3, 527.916 for S4. Maximum deviation of 24.752 and error of 7.8273 was found in S4, least deviation of 10.7760 and error of 3.4077 was found in S1 group.
Conclusion: The glazed porcelain had the highest micro hardness and fracture toughness followed by polished porcelain and autoglazed porcelain.
Dental casting technique, Dental polishing, Dental porcelain, Hardness test, Porcelain metal alloys
Porcelain is widely used in dental practice as material of choice for an individual jacket crown, fixed long span restorations. Effective finishing and polishing of dental restorations provide three benefits of dental care: oral health, function and esthetics (1). Main advantages of porcelain include biocompatibility, natural appearance and high resistance to wear and chemical inertness, refractive nature, hardness, susceptibility to clinical fracture and chemical inertness (2).
Disadvantages of porcelain include brittleness, lesser edge strength, high hardness resulting in more impact to the opposing teeth during mastication and abrasion of enamel of the natural opposing and adjacent teeth. The finishing and polishing of porcelain restorations are considered as an essential procedure for the final fit (2),(3),(4). Some authors have concluded that finishing and polishing of porcelain restoration is considered satisfactory with usage of conventional polishing systems such as polishing cups, disks and with porcelain polishing pastes (5),(6). However, the usual method of producing the surface gloss is by the application of glazes on the surface of porcelain (4).
Porcelain which is used as metal ceramic restorative material should have adequate strength, hardness, formable to the required shape, biocompatible, resistant to the oral environment, abrasive resistance and should be able to obtain the required colour and translucency (7),(8). For dental application hardness of ceramic, similar to that of enamel is desirable to minimise the wear of the resulting ceramic restoration and reduce the wear damage that can be produced on enamel by the ceramic restoration (8),(9).
It is also considered that the surface flaws induced at the time of surface finish leads to brittleness and reduces the flexural strength, micro hardness and thereby reducing the fracture toughness values. However it is mandatory and essential that high surface finish with an increase in esthetic value is achieved by the method of polishing and glazing (8),(10).
Considering these facts at the background, this study was conducted with the aim to evaluate two important physical properties namely micro hardness and fracture toughness and their relation to various methods of finishing and polishing such as conventional usage of polishing materials on porcelain, glazing with vitreous materials and also auto glazing. Objectives of the study included intra group comparison and inter group comparison of microhardness and fracture hardness of feldspathic porcelain following four different polishing techniques and identification of the viable and acceptable polishing method.
This in-vitro descriptive study was conducted between November 2018 to August 2019 at Department of Prosthodontics, Ragas Dental College and Hospital, Tamil Nadu, India. A sample size of 60 was included in the present study.
Inclusion and Exclusion criteria: The inclusion criteria included uniformly fired casting samples without any distortion, uniformly fired opaque porcelain samples, uniformly fired dentin ceramic samples. Inadequately fired porcelain samples, inadequately polished porcelain samples requiring repolishing were excluded. Twenty samples were discarded from study based on the exclusion criteria through visual inspection. Finally, forty samples were considered and selected and they were further divided into four groups of 10 samples each.
Study Procedure
The preparation of specimens for testing and for conducting the study of metal ceramic were made in two stages. The first stage in the preparation of the specimens was the making of the alloy substructure. The second stage was fusion of porcelain to the alloy structure, so the entire unit comprised of porcelain fused to alloy structure, as the final specimen to test the important physical properties.
The NiCr alloy samples were made from acrylic resin pattern. A stainless steel die was prepared for the fabrication of resin specimens of equal size and shape of the metal substructure. Sample preparation was done as per American Society for Testing and Materials (ASTM), specifications for materials (11). These acrylic patterns have a better dimensional stability than the wax pattern (11). The dimensions of the patterns were 40 mm length and 10 mm width at one end. Thus, a total of 60 resin patterns were fabricated.
Each of the acrylic patterns were attached to a standardised wax sprue former of 5 mm length and diameter of 2.5 mm. The sprue was attached at the narrow portion of each acrylic pattern. Thus, group of 10 resin patterns were taken up and sprue formers were attached to each one of the resin pattern at one time for casting purpose. In each group 10 patterns were arranged in circular configuration and all the samples were connected to a conical form to which a crucible former was attached. The crucible former assembled with the sprues with the resin patterns were attached to the casting ring with 100 mm height and 3.5 inch diameter. The patterns were sprayed with debubbliser to improve the wetting of the patterns.
This whole assembly of 10 such sprued plastic patterns were invested in graphite free phosphate bonded precision investment material, Heravest universal N (Heraeus kulzer, Germany). The ring was preheated and held at the final temperature for 50 minutes for complete burn out. The burnout ring was kept in the induction casting machine and adjusted for alignment with the preheated crucible held in the casting machine. The alloy pellets were kept in the crucible and the weights were balanced. The casting temperature of the alloy was adjusted at 1500C (11). Once the alloy had melted the lever was released to cast the metal in the mold.
The casting ring was allowed to cool to room temperature and divested. The sprues were severed and nodules removed. All the casting specimen were trimmed and finished with a thickness of 2Â mm. Ten samples were obtained from each casting. Likewise six castings were made in a phased manner to produce a total of 60 samples made with nickel chromium alloy (Table/Fig 1). The samples were coded for ease of identification. The specimens were held under vacuum for two minutes at 960°C. With temperature increase of 70°C per minute according to the manufacturer instructions to form oxide layer.
A custom mold was fabricated with clear methyl methacrylate. It consisted of a slot of 40×10×2 mm, which would facilitate the uniformity in the porcelain buildup. The working end of the metal samples, were grounded to 1 cm×0.5 mm and made to fit into the slot. When metal specimens were placed in the slot a uniform space of 2 mm remained in the slot between the top of the mold and metal and in the test site alone the metal was 0.5 mm (Table/Fig 2). Porcelain powders were to be mixed with the modular liquid and filled in the mold. The mold was then placed on the mechanical vibrator and the porcelain condensed. A glass slab was placed on the mold surface to make the porcelain surface smooth and of uniform thickness.
Specimens were trimmed flush at the top of the mold with a glass slab, which would give the approximate uniform thickness to all the porcelain samples. The thickness was further measured with the micrometer for the uniformity in all samples at nine points and the thickness of ceramic was totally 1.5 mm for all the 40 samples and were divided into four groups of 10 each as UP-unpolished, P-polished, AG-autoglazed, G-glazed.
The porcelain bearing surface of the alloy specimen was air abraded to simulate standard laboratory procedure. Further all the samples were steam cleaned to remove any surface impurities small amount of opaque porcelain paste was mixed with the special liquid. It was applied on the metal surface with the ceramic brush. Wash opaque was painted on the metal as a thin coating; no attempt was made to completely mask the metal. After firing the wash opaque a second layer of opaque was applied to completely mask the metal. The specimen was gently vibrated to evenly spread the paste. The second firing too was done as per manufacturers instructions. The thickness of opaque layer was found to be 0.3 mm after two firings (Table/Fig 3). The same procedure was follow for the application of opaque layer on all the 40 alloy specimens. Following this, dentin porcelain was added and all the 40 specimens and were fired according to the manufacturer’s instructions. Total thickness of sample was 2.0 mm (0.5 metal+0.3 opaque+0.8 dentine+0.4 enamel) (Table/Fig 4),(Table/Fig 5),(Table/Fig 6).
Among the 40 specimens, 10 specimens were taken for the study group coded as S1: UP unpolished, 10 specimens were taken and coded as S2: P, were polished with conventional polishing system to produce glossy appearance on the surface, by using finishing and polishing kit (Shofu, USA) and diamond polishing paste and finally they were all steam cleansed. Third group of 10 specimens, S3 were taken for study group coded as AG was given a surface finish with auto glazing according to the manufacturer recommended autoglazing firing temperature. The fourth, group of specimens of 10 members, S4 was coded as G and glazing was done by applying add on glazing material and were fired according to the manufacturer’s recommended glazing temperature.
Study Parameters
Hardness was measured by indentation method. Hardness was indicated though Vicker’s Hardness Number (VHN) Kg/mm2. In Vicker’s hardness test, two different loads of 0.2 kg and 1 kg was used. Diamond in the shape of a square pyramid is used as the indentor. The method of analysis of VHN is the load, divided by the area of indentation. The indentation was square in shape. The length of the diagonals of the indentation (sides of the diamond) are measured and averaged. Vicker’s test is used for brittle materials but not suitable for elastic materials (9),(10),(11),(12),(13),(14).
Fracture toughness or the critical stress intensity is a mechanical property that describes the ability of a material containing crack to resist further propagation and is given in the units of stress times the square root of crack length is MPa.m1/2, Klc-0.16 ha2 c3/2, where Klc-fracture toughness, h-hardness value, a-radius of impression, c-height of the crack (12),(13),(14),(15),(16).
Statistical Analysis
Statistical analysis was done using One way ANOVA and Posthoc Bonferroni tests (IBM SPSS, Los Angeles, California). A value of p<0.05 was considered significant.
Values of micro hardness in kg/m2 of porcelain, tested under 0.2 kg load, that have been finished using various techniques within the samples tested for S1, mean was 475.064. For S2 group, mean was 662.54. Within the samples tested for S3, mean was 641.224.Within the samples tested for S4, mean was 668.069 (Table/Fig 7).
The values of fracture toughness for 0.2 kg load are shown in (Table/Fig 8). The fracture toughness has been shown in Mpa1/2”. The fracture toughness in S1 with a mean value was 0.729672, fracture toughness in S2, with mean value was 1.187567. Fracture toughness in S3 with a mean value was 0.894827. Fracture toughness in S4 with the mean value was 1.324399.
Values of micro hardness of porcelain, tested under 1 kg load that have been finished using various techniques are shown in (Table/Fig 9). Within the samples tested for S1, mean was 360.048. Within the samples tested for S2, mean was 519.166. Within the samples tested for S3, mean was 508.817. Within the samples tested for S4, mean was 527.916.
The values of fracture toughness of porcelain for I kg load. The mean value for S1 was 0.553014 was shown in (Table/Fig 10). Fracture toughness in S2 mean value was 0.930577. In S3 the mean value was 0.710053. in S4 mean value was 1.046556.
There were significant differences in values of surface hardness and fracture toughness between these four groups (p<0.05) (Table/Fig 11). There were significant differences in values of surface hardness and fracture toughness between these four groups (Table/Fig 12).
Intergroup comparison of microhardness and fracture toughness between the four groups at 0.2 kg load has been presented n (Table/Fig 13). When S1 (unpolished) was compared with the rest, it was found to have a significant mean difference with all the other groups. The values of mean difference were all in negative, VHNproving that this group is significantly inferior to the rest. When S2 (polished) was compared with the rest of the groups, it was found to be significantly superior to S1. It’s difference with the rest of the groups was not significant. When S3 (autoglazed) was compared with the rest of the groups, it was found to be significantly superior to S1, and significantly inferior to S4. It’s difference with S2 was not significant. When S4 (glazed) was compared with the rest of the groups, it was found to be significantly superior to S1 and S3. It’s difference with the S2 was not significant.
Intergroup comparison of microhardness and fracture toughness between the four groups at 1 kg load has been presented in (Table/Fig 14). For fracture toughness when S1 (unpolished) was compared with the rest, it was found to have a significant difference with all the other groups. When S2 (polished) was compared with the rest of the groups, it was found to be superior to S1. It’s difference with the rest of the groups was insignificant. When S3 (autoglazed) was compared with the rest of the groups, it was found to be significantly superior to S1, and significantly inferior to S4. It’s difference with S2 was not significant. When S4 (glazed) was compared with the rest of the groups, it was found to be significantly superior to S1 and S3. It’s difference with the S2 was not significant.
The outcome of the present study indicated preferential use of glazed porcelain over other types of polishing techniques for porcelain.
Analysing the results of hardness value obtained showed that glazed material could be considered harder than that of conventional polishing. Anusaivice also mentioned that autoglazed (or) self glazed medium fusing feldspathic porcelain is much stronger than ground and rough, non glazed porcelain (11). If the material was unpolished or if the glaze, was removed by grinding, the hardness and fracture toughness was 25-35% less than that of the porcelain with the glaze layer intact. The glaze is effective in decreasing the crack propagation which in the outer surface because the surface flaws may be bridged and the surface will be under a state of comprehensive stress (11).
Results of this study indicated that porcelain with conventional highly polished surface with Shofu ceramic polishing kit and diamond polishing paste (S2), have comparably higher values of 519.166 as hardness and 0.930577 as fracture toughness value than that of the autoglazed shown in a value of 508.817 as hardness and 0.710053 as fracture toughness under 1 kg load. It is assumed that both type of glazing whether self (or) autoglazing produces smoother surface than any mechanical polishing agents (or) technique. In the case of self glazing a minimum fitted surface could arise due to the mismatch in the thermal coefficient of expansion as surface silica particles a higher temperature flows more than that of inner core of silica. In such conditions if the glaze has lower coefficient of thermal expansion than that of the body porcelain, it will be put under compressive stress on cooling. On such occasion tensile stress develop and the tendency is to develop crazing on the surface of the self glaze. Crazing is apparently shown as micro cracks or through conventional mechanical polishing flaws which would expose such cracks. This observation is of clinical importance because after the porcelain fused metal prosthesis is cemented in the mouth, it is a common practice for the operator to adjust the occlusion by grinding the surface of the porcelain with diamond burs and polishing it with a polishing kit (11),(12),(13),(14).
Deleterious effects of the rough and ground porcelain includes increased susceptibility for fracture due to propagation of microcracks, increase in wear of opposing restoration and/or tooth and discoloration due to more plaque accumulation. Increased wear of opposing teeth, loss of vertical dimension and interceptive contacts due to unglazed porcelain teeth induces traumatic occlusion in complete denture (15),(16),(17),(18). Additional firing for glazing may have a deleterious effect on the porcelain itself like devitrification. Moreover, reglazing is more time consuming as the chair side time, transportation, and laboratory time are involved. Grinding process removes glazed superficial surface. Ideally, it is advised to be re-glazed to get the smooth surface (19),(20),(21),(22),(23),(24),(25).
In a previous study, different polishing kits used reduced the average roughness by approximately 77% (20). It was concluded that corrected porcelain surfaces should ideally be reglazed, alternatively, polish the surfaces before final cementation .this study and the current study had utilized Shofu kit for polishing, but hardness and fracture toughness was not included in their study. Sethi S et al., explained that polishing of feldspathic porcelain surface will lead to a finish similar to a reglazed surface. Therefore chairside polishing can be a good alternative to reglazing for finishing adjusted porcelain surface (26). Manjuran NG and Sreelal T, concluded that polishing with feldspathic porcelain adjustment kit followed by diamond particle impregnated wax, created surfaces significantly smoother than the glazed specimens (27). Rani V et al., elaborated the fact that after adjustment of ceramic restorations in dental clinics, diamond polishing paste, when used after porcelain adjustment kit, could provide the marked finish equal to glazed or reglazed surface (28). Kalia P et al., concluded abraded specimens of feldspathic, after polishing using pearl finish polishing paste and soflex disc became smoother than glazed specimens (29). Facts and conclusions derived from these studies are different from current study. This could be attributed due to difference in brands of feldspathic porcelains and their composition used, operator style of polishing. Comparison of previous studies had been done in (Table/Fig 15) (20),(26),(27),(28),(29).
Limitation(s)
This study included interpretation of only two mechanical properties of porcelain following finishing methods. More properties including ultimate tensile strength and ductility should be included in future studies. Only one type of porcelain and alloy was used in this study. Artificial saliva was not used in this study to simulate clinical situation.
Within the limitations of the study, it can be concluded that glazed porcelain exhibited significant and highest micro-hardness and fracture toughness when compared with other finishing and polishing techniques. Polished porcelain exhibited significant and lesser values for microhardness and fracture toughness, than glazed porcelain and was second best. Glazed porcelain should be used whenever possible for porcelain fused to metal, for fixed single and multiple anterior and posterior long span restorations for greater durability and clinical longevity.
DOI: 10.7860/JCDR/2022/53002.16469
Date of Submission: Oct 26, 2021
Date of Peer Review: Jan 07, 2022
Date of Acceptance: Mar 29, 2022
Date of Publishing: Jun 01, 2022
AUTHOR DECLARATION:
• Financial or Other Competing Interests: None
• Was Ethics Committee Approval obtained for this study? NA
• Was informed consent obtained from the subjects involved in the study? NA
• For any images presented appropriate consent has been obtained from the subjects. NA
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