Journal of Clinical and Diagnostic Research, ISSN - 0973 - 709X

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Dr Mohan Z Mani

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On Sep 2018




Prof. Somashekhar Nimbalkar

"Over the last few years, we have published our research regularly in Journal of Clinical and Diagnostic Research. Having published in more than 20 high impact journals over the last five years including several high impact ones and reviewing articles for even more journals across my fields of interest, we value our published work in JCDR for their high standards in publishing scientific articles. The ease of submission, the rapid reviews in under a month, the high quality of their reviewers and keen attention to the final process of proofs and publication, ensure that there are no mistakes in the final article. We have been asked clarifications on several occasions and have been happy to provide them and it exemplifies the commitment to quality of the team at JCDR."



Prof. Somashekhar Nimbalkar
Head, Department of Pediatrics, Pramukhswami Medical College, Karamsad
Chairman, Research Group, Charutar Arogya Mandal, Karamsad
National Joint Coordinator - Advanced IAP NNF NRP Program
Ex-Member, Governing Body, National Neonatology Forum, New Delhi
Ex-President - National Neonatology Forum Gujarat State Chapter
Department of Pediatrics, Pramukhswami Medical College, Karamsad, Anand, Gujarat.
On Sep 2018




Dr. Kalyani R

"Journal of Clinical and Diagnostic Research is at present a well-known Indian originated scientific journal which started with a humble beginning. I have been associated with this journal since many years. I appreciate the Editor, Dr. Hemant Jain, for his constant effort in bringing up this journal to the present status right from the scratch. The journal is multidisciplinary. It encourages in publishing the scientific articles from postgraduates and also the beginners who start their career. At the same time the journal also caters for the high quality articles from specialty and super-specialty researchers. Hence it provides a platform for the scientist and researchers to publish. The other aspect of it is, the readers get the information regarding the most recent developments in science which can be used for teaching, research, treating patients and to some extent take preventive measures against certain diseases. The journal is contributing immensely to the society at national and international level."



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Sri Devaraj Urs Medical College
Sri Devaraj Urs Academy of Higher Education and Research , Kolar, Karnataka
On Sep 2018




Dr. Saumya Navit

"As a peer-reviewed journal, the Journal of Clinical and Diagnostic Research provides an opportunity to researchers, scientists and budding professionals to explore the developments in the field of medicine and dentistry and their varied specialities, thus extending our view on biological diversities of living species in relation to medicine.
‘Knowledge is treasure of a wise man.’ The free access of this journal provides an immense scope of learning for the both the old and the young in field of medicine and dentistry as well. The multidisciplinary nature of the journal makes it a better platform to absorb all that is being researched and developed. The publication process is systematic and professional. Online submission, publication and peer reviewing makes it a user-friendly journal.
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Dr Saumya Navit
Professor and Head
Department of Pediatric Dentistry
Saraswati Dental College
Lucknow
On Sep 2018




Dr. Arunava Biswas

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Their prompt and timely response to review's query and the manner in which they have set the reviewing process helps in extracting the best possible scientific writings for publication.
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Dr. Arunava Biswas
MD, DM (Clinical Pharmacology)
Assistant Professor
Department of Pharmacology
Calcutta National Medical College & Hospital , Kolkata




Dr. C.S. Ramesh Babu
" Journal of Clinical and Diagnostic Research (JCDR) is a multi-specialty medical and dental journal publishing high quality research articles in almost all branches of medicine. The quality of printing of figures and tables is excellent and comparable to any International journal. An added advantage is nominal publication charges and monthly issue of the journal and more chances of an article being accepted for publication. Moreover being a multi-specialty journal an article concerning a particular specialty has a wider reach of readers of other related specialties also. As an author and reviewer for several years I find this Journal most suitable and highly recommend this Journal."
Best regards,
C.S. Ramesh Babu,
Associate Professor of Anatomy,
Muzaffarnagar Medical College,
Muzaffarnagar.
On Aug 2018




Dr. Arundhathi. S
"Journal of Clinical and Diagnostic Research (JCDR) is a reputed peer reviewed journal and is constantly involved in publishing high quality research articles related to medicine. Its been a great pleasure to be associated with this esteemed journal as a reviewer and as an author for a couple of years. The editorial board consists of many dedicated and reputed experts as its members and they are doing an appreciable work in guiding budding researchers. JCDR is doing a commendable job in scientific research by promoting excellent quality research & review articles and case reports & series. The reviewers provide appropriate suggestions that improve the quality of articles. I strongly recommend my fraternity to encourage JCDR by contributing their valuable research work in this widely accepted, user friendly journal. I hope my collaboration with JCDR will continue for a long time".



Dr. Arundhathi. S
MBBS, MD (Pathology),
Sanjay Gandhi institute of trauma and orthopedics,
Bengaluru.
On Aug 2018




Dr. Mamta Gupta,
"It gives me great pleasure to be associated with JCDR, since last 2-3 years. Since then I have authored, co-authored and reviewed about 25 articles in JCDR. I thank JCDR for giving me an opportunity to improve my own skills as an author and a reviewer.
It 's a multispecialty journal, publishing high quality articles. It gives a platform to the authors to publish their research work which can be available for everyone across the globe to read. The best thing about JCDR is that the full articles of all medical specialties are available as pdf/html for reading free of cost or without institutional subscription, which is not there for other journals. For those who have problem in writing manuscript or do statistical work, JCDR comes for their rescue.
The journal has a monthly publication and the articles are published quite fast. In time compared to other journals. The on-line first publication is also a great advantage and facility to review one's own articles before going to print. The response to any query and permission if required, is quite fast; this is quite commendable. I have a very good experience about seeking quick permission for quoting a photograph (Fig.) from a JCDR article for my chapter authored in an E book. I never thought it would be so easy. No hassles.
Reviewing articles is no less a pain staking process and requires in depth perception, knowledge about the topic for review. It requires time and concentration, yet I enjoy doing it. The JCDR website especially for the reviewers is quite user friendly. My suggestions for improving the journal is, more strict review process, so that only high quality articles are published. I find a a good number of articles in Obst. Gynae, hence, a new journal for this specialty titled JCDR-OG can be started. May be a bimonthly or quarterly publication to begin with. Only selected articles should find a place in it.
An yearly reward for the best article authored can also incentivize the authors. Though the process of finding the best article will be not be very easy. I do not know how reviewing process can be improved. If an article is being reviewed by two reviewers, then opinion of one can be communicated to the other or the final opinion of the editor can be communicated to the reviewer if requested for. This will help one’s reviewing skills.
My best wishes to Dr. Hemant Jain and all the editorial staff of JCDR for their untiring efforts to bring out this journal. I strongly recommend medical fraternity to publish their valuable research work in this esteemed journal, JCDR".



Dr. Mamta Gupta
Consultant
(Ex HOD Obs &Gynae, Hindu Rao Hospital and associated NDMC Medical College, Delhi)
Aug 2018




Dr. Rajendra Kumar Ghritlaharey

"I wish to thank Dr. Hemant Jain, Editor-in-Chief Journal of Clinical and Diagnostic Research (JCDR), for asking me to write up few words.
Writing is the representation of language in a textual medium i e; into the words and sentences on paper. Quality medical manuscript writing in particular, demands not only a high-quality research, but also requires accurate and concise communication of findings and conclusions, with adherence to particular journal guidelines. In medical field whether working in teaching, private, or in corporate institution, everyone wants to excel in his / her own field and get recognised by making manuscripts publication.


Authors are the souls of any journal, and deserve much respect. To publish a journal manuscripts are needed from authors. Authors have a great responsibility for producing facts of their work in terms of number and results truthfully and an individual honesty is expected from authors in this regards. Both ways its true "No authors-No manuscripts-No journals" and "No journals–No manuscripts–No authors". Reviewing a manuscript is also a very responsible and important task of any peer-reviewed journal and to be taken seriously. It needs knowledge on the subject, sincerity, honesty and determination. Although the process of reviewing a manuscript is a time consuming task butit is expected to give one's best remarks within the time frame of the journal.
Salient features of the JCDR: It is a biomedical, multidisciplinary (including all medical and dental specialities), e-journal, with wide scope and extensive author support. At the same time, a free text of manuscript is available in HTML and PDF format. There is fast growing authorship and readership with JCDR as this can be judged by the number of articles published in it i e; in Feb 2007 of its first issue, it contained 5 articles only, and now in its recent volume published in April 2011, it contained 67 manuscripts. This e-journal is fulfilling the commitments and objectives sincerely, (as stated by Editor-in-chief in his preface to first edition) i e; to encourage physicians through the internet, especially from the developing countries who witness a spectrum of disease and acquire a wealth of knowledge to publish their experiences to benefit the medical community in patients care. I also feel that many of us have work of substance, newer ideas, adequate clinical materials but poor in medical writing and hesitation to submit the work and need help. JCDR provides authors help in this regards.
Timely publication of journal: Publication of manuscripts and bringing out the issue in time is one of the positive aspects of JCDR and is possible with strong support team in terms of peer reviewers, proof reading, language check, computer operators, etc. This is one of the great reasons for authors to submit their work with JCDR. Another best part of JCDR is "Online first Publications" facilities available for the authors. This facility not only provides the prompt publications of the manuscripts but at the same time also early availability of the manuscripts for the readers.
Indexation and online availability: Indexation transforms the journal in some sense from its local ownership to the worldwide professional community and to the public.JCDR is indexed with Embase & EMbiology, Google Scholar, Index Copernicus, Chemical Abstracts Service, Journal seek Database, Indian Science Abstracts, to name few of them. Manuscriptspublished in JCDR are available on major search engines ie; google, yahoo, msn.
In the era of fast growing newer technologies, and in computer and internet friendly environment the manuscripts preparation, submission, review, revision, etc and all can be done and checked with a click from all corer of the world, at any time. Of course there is always a scope for improvement in every field and none is perfect. To progress, one needs to identify the areas of one's weakness and to strengthen them.
It is well said that "happy beginning is half done" and it fits perfectly with JCDR. It has grown considerably and I feel it has already grown up from its infancy to adolescence, achieving the status of standard online e-journal form Indian continent since its inception in Feb 2007. This had been made possible due to the efforts and the hard work put in it. The way the JCDR is improving with every new volume, with good quality original manuscripts, makes it a quality journal for readers. I must thank and congratulate Dr Hemant Jain, Editor-in-Chief JCDR and his team for their sincere efforts, dedication, and determination for making JCDR a fast growing journal.
Every one of us: authors, reviewers, editors, and publisher are responsible for enhancing the stature of the journal. I wish for a great success for JCDR."



Thanking you
With sincere regards
Dr. Rajendra Kumar Ghritlaharey, M.S., M. Ch., FAIS
Associate Professor,
Department of Paediatric Surgery, Gandhi Medical College & Associated
Kamla Nehru & Hamidia Hospitals Bhopal, Madhya Pradesh 462 001 (India)
E-mail: drrajendrak1@rediffmail.com
On May 11,2011




Dr. Shankar P.R.

"On looking back through my Gmail archives after being requested by the journal to write a short editorial about my experiences of publishing with the Journal of Clinical and Diagnostic Research (JCDR), I came across an e-mail from Dr. Hemant Jain, Editor, in March 2007, which introduced the new electronic journal. The main features of the journal which were outlined in the e-mail were extensive author support, cash rewards, the peer review process, and other salient features of the journal.
Over a span of over four years, we (I and my colleagues) have published around 25 articles in the journal. In this editorial, I plan to briefly discuss my experiences of publishing with JCDR and the strengths of the journal and to finally address the areas for improvement.
My experiences of publishing with JCDR: Overall, my experiences of publishing withJCDR have been positive. The best point about the journal is that it responds to queries from the author. This may seem to be simple and not too much to ask for, but unfortunately, many journals in the subcontinent and from many developing countries do not respond or they respond with a long delay to the queries from the authors 1. The reasons could be many, including lack of optimal secretarial and other support. Another problem with many journals is the slowness of the review process. Editorial processing and peer review can take anywhere between a year to two years with some journals. Also, some journals do not keep the contributors informed about the progress of the review process. Due to the long review process, the articles can lose their relevance and topicality. A major benefit with JCDR is the timeliness and promptness of its response. In Dr Jain's e-mail which was sent to me in 2007, before the introduction of the Pre-publishing system, he had stated that he had received my submission and that he would get back to me within seven days and he did!
Most of the manuscripts are published within 3 to 4 months of their submission if they are found to be suitable after the review process. JCDR is published bimonthly and the accepted articles were usually published in the next issue. Recently, due to the increased volume of the submissions, the review process has become slower and it ?? Section can take from 4 to 6 months for the articles to be reviewed. The journal has an extensive author support system and it has recently introduced a paid expedited review process. The journal also mentions the average time for processing the manuscript under different submission systems - regular submission and expedited review.
Strengths of the journal: The journal has an online first facility in which the accepted manuscripts may be published on the website before being included in a regular issue of the journal. This cuts down the time between their acceptance and the publication. The journal is indexed in many databases, though not in PubMed. The editorial board should now take steps to index the journal in PubMed. The journal has a system of notifying readers through e-mail when a new issue is released. Also, the articles are available in both the HTML and the PDF formats. I especially like the new and colorful page format of the journal. Also, the access statistics of the articles are available. The prepublication and the manuscript tracking system are also helpful for the authors.
Areas for improvement: In certain cases, I felt that the peer review process of the manuscripts was not up to international standards and that it should be strengthened. Also, the number of manuscripts in an issue is high and it may be difficult for readers to go through all of them. The journal can consider tightening of the peer review process and increasing the quality standards for the acceptance of the manuscripts. I faced occasional problems with the online manuscript submission (Pre-publishing) system, which have to be addressed.
Overall, the publishing process with JCDR has been smooth, quick and relatively hassle free and I can recommend other authors to consider the journal as an outlet for their work."



Dr. P. Ravi Shankar
KIST Medical College, P.O. Box 14142, Kathmandu, Nepal.
E-mail: ravi.dr.shankar@gmail.com
On April 2011
Anuradha

Dear team JCDR, I would like to thank you for the very professional and polite service provided by everyone at JCDR. While i have been in the field of writing and editing for sometime, this has been my first attempt in publishing a scientific paper.Thank you for hand-holding me through the process.


Dr. Anuradha
E-mail: anuradha2nittur@gmail.com
On Jan 2020

Important Notice

Original article / research
Year : 2024 | Month : November | Volume : 18 | Issue : 11 | Page : ZC51 - ZC57 Full Version

Evaluation of the Marginal Fit and Fracture Resistance of Polyetheretherketone (PEEK) and Zirconia Copings: An In-vitro Study


Published: November 1, 2024 | DOI: https://doi.org/10.7860/JCDR/2024/73093.20281
Nehal Mahajan, Urvashi Sukhija, Navneet Kukreja, Sandeep Kalra, Sanjeev Mittal, Manumeet Bhathal, Swati Chhabra, Surinder Sachdeva

1. Postgraduate Student, Department of Prosthodontics, MM College of Dental Sciences and Research, Maharishi Markandeshwar (Deemed to be University), Mullana, Ambala, Haryana, India. 2. Professor, Department of Prosthodontics, MM College of Dental Sciences and Research, Maharishi Markandeshwar (Deemed to be University), Mullana, Ambala, Haryana, India. 3. Professor, Department of Conservative Dentistry and Endodontics, MM College of Dental Sciences and Research, Maharishi Markandeshwar (Deemed to be University), Mullana, Ambala, Haryana, India. 4. Associate Professor, Department of Prosthodontics, MM College of Dental Sciences and Research, Maharishi Markandeshwar (Deemed to be University), Mullana, Ambala, Haryana, India. 5. Professor, Department of Prosthodontics, MM College of Dental Sciences and Research, Maharishi Markandeshwar (Deemed to be University), Mullana, Ambala, Haryana, India. 6. Associate Professor, Department of Prosthodontics, MM College of Dental Sciences and Re

Correspondence Address :
Dr. Swati Chhabra,
Assistant Professor, Department of Conservative Dentistry and Endodontics, MM College of Dental Sciences and Research, Maharishi Markandeshwar (Deemed to be University), Mullana, Ambala-133207, Haryana, India.
E-mail: drswatichhabraendo@gmail.com

Abstract

Introduction: In dentistry, there has been an increasing demand for aesthetics and biocompatible restorations with low plaque affinity. The success of any restoration is based on three main factors: marginal fit, fracture resistance, and aesthetics. Polyetheretherketone (PEEK) is a polymeric material that has emerged as a novel thermoplastic material with wide applications.

Aim: To evaluate the marginal fit and fracture resistance of PEEK and zirconia copings fabricated using Computer-aided Design (CAD)/Computer-aided Manufacturing (CAM) technology.

Materials and Methods: The present in-vitro study was conducted in the Department of Prosthodontics, MM College of Dental Sciences and Research, Mullana, Ambala, Haryana, India, from November 2022 to March 2024. The present study compared the marginal fit and fracture resistance of PEEK and zirconia copings fabricated using CAD/CAM technology. All-ceramic tooth preparations were performed on extracted maxillary first premolars, and the prepared teeth were scanned. Using three dimensional (3D) printing technology, 20 resin dies were obtained. These dies were divided into two groups: 10 for PEEK and 10 for zirconia. Ten copings for zirconia and PEEK were fabricated using CAD/CAM technology, and two reference points were marked on the copings. The copings were luted with resin cement on the dies, and marginal fit and fracture resistance were recorded. The observations were statistically analysed using a two-way Analysis of Variance (ANOVA) test and a two-sample t-test.

Results: The lowest mean marginal discrepancy values (18.469±6.55 μm for the palatal aspect and 17.116±6.34 μm for the buccal aspect) were observed for the zirconia copings. These values were significantly better compared to the PEEK copings (23.941±7.73 μm on the palatal aspect and 22.338±7.89 μm on the buccal aspect). In terms of fracture resistance, PEEK copings demonstrated a higher load-bearing capacity (523.11±117.27 N) and significantly better results compared to zirconia copings (395.4±150.93 N).

Conclusion: The results revealed that, when comparing both PEEK and zirconia copings, zirconia copings demonstrated a better marginal fit compared to PEEK copings. However, for fracture resistance analysis, PEEK copings exhibited better load-bearing capacity than zirconia copings.

Keywords

Aesthetics, Fixed dental prosthesis, Resin die, Stereomicroscope, Universal testing machine

In dentistry, there has been a growing demand for aesthetic, natural-appearing restorations with better compatibility and low plaque affinity to promote periodontal health. In prosthodontics, the materials used for fixed dental prostheses have evolved over the years, and their production stages are being rapidly automated with each passing day (1).

In recent years, the demand for natural-looking restorations with enhanced biocompatibility has led to the rise of metal-free alternatives. Despite initial reservations, advancements in material science have propelled the viability of metal-free restorations, particularly for anterior teeth. However, challenges such as low fracture resistance and improper marginal adaptation have hindered their application in posterior restorations (2),(3).

Material science has transformed with the advent of CAD/CAM technology in dentistry in the 1980s. These developments have greatly enhanced the manufacturing of indirect restorations with unparalleled strength and performance. One such material is Yttria-stabilised Tetragonal Zirconia Polycrystals (Y-TZP). Zirconia, a crystalline dioxide of zirconium, was dubbed ‘ceramic steel’ by Gravie in 1972, showcasing mechanical properties akin to metal along with excellent aesthetics. Due to its exceptional strength, lengthy fabrication time and tool wear, fully sintered zirconia presents significant challenges to technicians during manufacturing. To overcome this, zirconia is processed in its presintered phase, and the final sintering is done after the fabrication. The clinical applications of zirconia in dentistry include anterior and posterior Fixed Partial Dentures (FPDs) and implant abutments (4). Zirconia serves as an excellent framework material for crowns and long-span bridges in posterior teeth, offering high toughness, compressive strength, fracture resistance, chemical stability and biocompatibility. However, it lacks tensile strength and etching properties, requiring layering for enhanced aesthetics, although it is prone to fracturing when paired with porcelain under occlusal stresses (3).

High-performance polymers like Polyaryletherketone (PAEK), Polyetheretherketone (PEEK) and Polyetherketoneketone (PEKK) have been introduced in dentistry as alternatives to ceramic restorations. PEEK, introduced in 1978, stands out within the PAEK family for its physiologically inert, water-insoluble properties, making it widely used. Its benefits include radiolucency, low plaque affinity and exceptional chemical resistance (5). Despite its opaque, greyish appearance, PEEK requires layering with tooth-coloured materials for better aesthetics. Its biomechanical properties, including high fracture strength, rigidity and dimensional stability, make it ideal for various dental restorations like implant prostheses, bars and fixed dental prostheses (3).

Young’s modulus for PEEK in its pure form is around 3.6 GPa, which is similar to that of cortical bone, whereas for zirconia, it is 200 GPa. When reinforced with carbon, Carbon Fibre-reinforced-PEEK (CFR-PEEK), its modulus of elasticity can increase to between 19 GPa and 150 GPa. These characteristics make PEEK an ideal material. Additionally, it has a low density of 1.28-1.32 g/cm3 compared to 6.49 g/cm3 for zirconia, making PEEK useful for fabricating lightweight prostheses (6),(7). PEEK prostheses can be manufactured using vacuum-press techniques with granules or pellets, or they can be milled using CAD/CAM technology, offering flexibility in manufacturing.

The success of the restoration hinges on three main factors: marginal fit, fracture resistance, and aesthetics. Mechanical properties and fracture load are pivotal for the prognosis of restoration under occlusal forces and for the long-term success of the restoration. The tooth-restorative margin contact forms the weakest point in fixed prosthetic treatment. A poor fit could result in the cement dissolving and fluid seeping through, which could induce secondary caries, sensitivity, pulp exposure, plaque deposition and periodontal destruction (2). PEEK is a relatively new material that is becoming popular in clinical practice and can prove to be a competent coping material like zirconia (3); however, literature on its use as a coping material is limited.

Therefore, the present study was planned to evaluate and compare the marginal fit and fracture resistance properties of PEEK and zirconia copings. For marginal fit analysis, the null hypothesis stated that there was no significant difference between the materials (PEEK and zirconia copings) and between the sides (palatal and buccal sides). For fracture resistance, the null hypothesis stated that there is no significant difference in the mean fracture resistance between PEEK copings and zirconia copings.

Material and Methods

The present in-vitro study was carried out in the Department of Prosthodontics, Maharishi Markandeshwar College of Dental Science and Research, Mullana, Ambala, Haryana, India, in collaboration with Acucal Services, Ambala Cantt, Haryana, and Em Cee Cee Sports Ag. Pvt. Ltd., Jalandhar, Punjab. The study took place over a span of two years, from November 2022 to March 2024. Study was conducted after obtaining clearance from Institutional Ethical Committee (IEC number: 2255).

Inclusion criteria: Maxillary first premolars, which were extracted for orthodontic purposes, with a crown size having a mesiodistal diameter of 7-8 mm and a buccolingual diameter of 9-10 mm were included in the study.

Exclusion criteria: Teeth with caries, any restorations, or any defects were excluded from the study.

Sample size: The sample size was calculated using the software OpenEpi, Version 3; and was calculated to be 20 (10 for the PEEK group and 10 for the zirconia group).

Study Procedure

The maxillary first premolar was mounted in dental plaster and then prepared for all-ceramic restorations. The prepared tooth was scanned using a 3D scanner (Medit T 310 3D Scanner), and the data was stored in Stereolithography (STL) files, which were later used to fabricate resin dies using a 3D printer (Elegoo Saturn 8K Resin 3D Printer) and a resin dye material (Phrozen Aqua 4K 3D Printing Resin). In total, 20 resin dies were created (Table/Fig 1). These dies were divided into two groups for the fabrication of 10 PEEK copings (Group A) and 10 zirconia copings (Group B) using CAD/CAM technology. After grouping, the samples were numbered from 1 to 10 in each group (Table/Fig 2).

The resin dies were scanned using a 3D extraoral scanner. CAD software (exocad) (Table/Fig 3) was used to design the copings, and photographs were taken to ensure a uniform thickness of 0.5 mm and a virtual cement layer of 50 μm, which was applied 1 mm above the shoulder finish line. The zirconia copings were designed with a uniform thickness of 0.5 mm and a cement space of 50 μm starting 1 mm above the finish line. A 5-axis milling machine (Arum 5X-300 D milling machine) (Table/Fig 4) was used to fabricate both PEEK and zirconia copings.

The PEEK and zirconia copings were collected, and reference points were marked on the margins of two aspects: buccal (b) and palatal (p) using a bur attached to a micromotor to ensure uniform depth and size of the marked points (Table/Fig 5). At each marked reference point, three readings were recorded: for the palatal side, p1, p2 and p3; and for the buccal side, b1, b2 and b3. The fit of the PEEK and zirconia copings was analysed on each resin die, and they were luted onto the prepared surface of the resin die using a self-adhesive translucent resin cement with finger pressure for atleast 10 minutes. The excess cement was removed from the margins.

The PEEK and zirconia copings were evaluated under a stereomicroscope at 60x magnification at the marked reference points to check the marginal fit (Table/Fig 6). The restoration-tooth margin was observed to assess the marginal gap, which was measured as the separation between the prepared tooth’s external marginal line and the extended point on the coping margin (Table/Fig 7).

All 20 samples were subjected to thermal cycling to simulate the oral environmental conditions. Each sample underwent 1000 thermal cycles at 5°C and 55°C in a water bath, with a dwell time of 15 seconds and a transfer time between the baths of 15 seconds, similar to the studies by Sarfaraz H et al., (8). After thermal cycling, all the samples were assessed for fracture resistance using a Universal Testing Machine (UTM) (Presto Computerised Tensile Testing Machine and UTM) (Table/Fig 8). Therefore, the maximum vertical dislodging force was recorded at a crosshead speed of 1 mm/min. The test samples were placed in the lower compartment of the machine, with the central fossa directly aligned with the centre of the upper compartment to ensure a uniform distribution of stresses. The failure load or fracture resistance value was determined by recording the value that corresponded to the specimen’s first break. The force was recorded in Newtons, and it was noted that the load decreased by 30% from the maximum load (Table/Fig 9).

Statistical Analysis

A two-way ANOVA was used to assess whether there are significant differences in marginal fit based on material and side between PEEK and zirconia copings. To compare the fracture resistance of PEEK and zirconia copings, an independent t-test was applied to assess whether there is a statistically significant difference in the mean fracture resistance between the two materials. The p-value <0.05 was considered statistically significant.

Results

The mean±Standard Deviation (SD) for marginal fit was calculated aspect-wise for both the PEEK and zirconia groups based on the three readings obtained for all samples at the palatal and buccal aspects. These mean readings were then used for comparative analysis (Table/Fig 10). For both the palatal and buccal aspects, the test results showed higher mean values for the PEEK copings (palatal side: 23.941±7.73 μm and buccal side: 22.338±7.89 μm) compared to the zirconia copings (palatal side: 18.469±6.55 μm and buccal side: 17.116±6.34 μm). This implies less discrepancy at the margins for the zirconia group, indicating that the zirconia copings have better marginal adaptation than the PEEK copings.

The results of the two-way ANOVA indicate a significant difference in marginal fit between the two materials used in the study (PEEK and zirconia). The p-value associated with the ‘material’ factor is highly significant (p-value=7.53e-05), suggesting that the choice of material has a substantial impact on the marginal fit value. However, the factor ‘side’ (palatal or buccal) does not show a significant effect on marginal fit, as indicated by a non significant p-value (p-value=0.259). This implies that, on average, across both materials, the location of the fit measurement (palatal or buccal) does not significantly influence marginal fit. Thus, the difference in marginal fit is primarily attributed to the choice of material, with no significant influence from the side of measurement.

For the analysis of fracture resistance, higher mean values are shown by the PEEK group compared to the zirconia group. This indicates that the PEEK copings exhibit greater fracture resistance than the zirconia copings (Table/Fig 11). A two-sample t-test was conducted to compare the means of fracture resistance between the PEEK and zirconia copings. The analysis yielded a p-value of 0.04884, which is less than the common significance level of 0.05.

Discussion

In the era of digitalisation in prosthodontics, it has become possible to manufacture newer materials with good strength and performance. Using CAD/CAM technology, it has become easier to produce precise restorations that demonstrate both longevity and durability (9).

According to Rodriguez V et al., marginal adaptation, fracture resistance and aesthetics are the three key elements that influence the success of restorations, even with advancements in CAD/CAM technology (10). McLean JW and Von Fraunhofer JA (1971) stated that for crown prostheses, the clinically acceptable marginal gap is approximately 120 μm, ensuring the longevity of the prostheses (11). However, El-Dessouky RA et al., reported that marginal discrepancies ranging between 17 μm and 161 μm have been found for all-ceramic restorations fabricated using different techniques (12). Therefore, the strength of the finished restoration and the marginal fit are significantly impacted by the various materials and manufacturing processes used in crown systems.

The present study was conducted to evaluate and compare the marginal fit and fracture resistance of PEEK and zirconia copings fabricated using CAD/CAM technology. Additionally, standardised resin master dies were used. This material was preferred because of its high tensile modulus, low brittleness, great hardness and stiffness, and good clarity, which provided visibility to evaluate the marginal gap using digital microscopes.

Previous authors have studied the marginal gap at various reference points. Groten M et al., (2000) suggested using 50 reference points for measuring the marginal fit, while Gassino G et al., (2004) suggested using 18 reference points (13),(14). However, different studies have reported the number of measurements to range between 4, 8 and 12, which is closer to the number of reference points marked in the present study.

In the present study, the mean marginal gap for PEEK copings was significantly higher than that for zirconia copings. For the PEEK copings, a marginal discrepancy of 23.941±7.73 μm was reported on the palatal side and 22.338±7.89 μm on the buccal side. These values were consistent with the observations by Attia MA and Shokry TE, and Abdullah AO et al., for PEEK CAD/CAM copings (3),(15). The mean marginal gap observed for zirconia copings in this study was 18.469±6.55 μm for the palatal side and 17.116±6.34 μm for the buccal side, which were similar to the results observed by Emam M and Metwally MF (2023), who also reported a similar range of marginal discrepancy for partially sintered zirconia (16).

The results of the marginal fit were congruent with the study conducted by Emad M et al., which highlighted a higher marginal discrepancy in PEEK crowns compared to zirconia crowns. The present study was also conducted using a stereomicroscope (17). Additionally, favourable results were reported by Makky MR et al., who stated a significantly lower marginal gap for the zirconia group than for the PEEK CAD and PEEK pressed groups (18). Baran MC et al., evaluated the adaptation of three-unit Fixed Dental Prosthesis (FDPs) processed using zirconia, PEEK, PEKK and fibre-reinforced polymer composite, using silicon replica technique under a stereomicroscope at 40x (19). Their results concluded that the best adaptation was shown by the zirconia FDP.

In the present study, PEEK copings demonstrated a higher marginal discrepancy compared to zirconia copings. This could be due to the semicrystalline nature of PEEK, which has a structure made of filler particles embedded in the resin matrix, resulting in a higher marginal gap during manufacturing. In contrast, zirconia is polycrystalline. The present study did not align with the findings of Bae SY et al., who compared the marginal and internal fit of PEKK and zirconia copings, stating that PEKK copings showed a better fit than zirconia copings (20). Similarly, Park JY et al., used the replica technique to compare the marginal fit of PEEK, zirconia and lithium disilicate crowns, concluding that the marginal discrepancy for all crowns was clinically acceptable (21). Amalorpavam V et al., also concluded that zirconia copings exhibited less marginal and internal adaptation compared to PEEK copings, with the difference being statistically significant, as observed under a scanning electron microscope (22).

After the analysis of the marginal fit, all the samples underwent artificial ageing. According to Güngör MB and Nemli SK, all samples must undergo dynamic loading and thermal cycling to simulate the changes observed in the oral environment (23). In the present study, all the copings were subjected to thermal cycling for 1000 cycles at temperatures of 5°C and 55°C in a water bath, with a dwell time of 15 seconds and a transfer time of 15 seconds. The copings were then assessed for fracture resistance in a universal testing machine, where the maximum dislodging force was recorded at a cross-head speed of 1 mm/minute.

Beuer F et al., stated that for fixed prostheses, fracture strength is determined by several parameters, including cementation, loading circumstances, and the elastic modulus of the supporting die (24). Scherrer SS and De Rijk WG stated that when the Young’s modulus of the supporting die is greater, it may result in larger fracture strength (25). Different authors have tested fracture resistance using stainless-steel dies, epoxy resin, or acrylic dies with varying mechanical properties. However, the dies used in this study were digitally obtained and fabricated using 3D printing technology, with a tensile modulus of 1037 MPa. Cementation and loading factors were consistent for all samples used in the study.

The maximum bite force for the maxillary premolar area ranges between 222 and 445 N, with a mean force of 322.5 N. In this study, an average load-bearing capacity of 300 N was used to represent adequate fracture resistance against normal occlusal forces. The results indicated that the fracture resistance of PEEK copings was significantly higher than that of zirconia copings (p-value=0.048, p-value<0.005). The mean values reported were 523.11±117.27 N for PEEK copings, with the highest fracture load recorded at 725.1 N. In contrast, the mean fracture load recorded for zirconia copings was 395.4±150.93 N, with the highest load observed at 570 N.

The results of the current study were congruent with those of Hossam M et al., who compared the load-bearing capacity of PEEK {Bio-high Performance Polymer (BioHPP)} and zirconia three-unit framework prostheses using a universal testing machine (26). The PEEK group showed higher fracture resistance than the zirconia group. In that study, epoxy dies were used, and no artificial ageing was performed.

Rodriguez V et al., studied the fracture resistance of FPD frameworks processed using metal, zirconia and PEEK CAD/CAM milled materials. Their results indicated the highest fracture resistance for metal prostheses, followed by PEEK and zirconia prostheses (10). Emam M and Metwally MF reported no significant difference in the fracture resistance of molar crowns manufactured using PEEK (CAD), pressed PEEK and zirconia groups (16). A similar study by El Sokkary A et al., also observed no significant difference in the fracture resistance of zirconia and PEEK veneered groups (27).

In contrast, a study by Tartuk BK et al., examined the load-bearing capacity of CAD/CAM crowns made from zirconia, PEEK and hybrid ceramic crowns (28). A statistically insignificant difference was observed between the PEEK (2214±236 N) and the ceramic group (2325±264 N); however, the zirconia group exhibited the highest values (3292±192 N). Additionally, a zirconia die was used in that study. Stawarczyk B et al., examined the load-bearing capacity of PEEK three-unit FDPs manufactured using CAD/CAM and pressed granules, stating that PEEK CAD/CAM showed a higher fracture resistance than the pressed group (29). A comparative evaluation of similar studies has been presented in (Table/Fig 12),(Table/Fig 13) (1),(10),(16),(18),(20),(22),(29).

In the present study, PEEK copings exhibited significantly higher fracture resistance than zirconia copings. Therefore, it can be presumed that PEEK material exhibits better mechanical properties than zirconia. This may be due to the semicrystalline nature of PEEK, which possesses significant ductility, allowing it to withstand plastic deformation under load application. Consequently, the null hypothesis was rejected, indicating that there is sufficient evidence to conclude a significant difference in the means of fracture resistance between PEEK and zirconia copings.

Limitation(s)

This is an in-vitro study; therefore, patient-based studies are needed to evaluate mechanical properties and patient satisfaction. Resin dies were used in the present study. A natural tooth could have been used as a supporting die to better match the modulus of elasticity of a natural tooth or bone. Cementation was performed using finger pressure, and no mechanical loading was performed during the cementation process. The marginal fit was evaluated using a stereomicroscope, but the replica method, which is also commonly used to evaluate marginal adaptation, was not employed.

Conclusion

Within the limitations of the present study, it can be concluded that the marginal fit of both PEEK and zirconia copings was within the clinically acceptable range, with marginal gaps observed between 23 μm and 110.1 μm. Zirconia copings demonstrated a significantly superior marginal fit compared to PEEK copings. The fracture strength is determined by several parameters, including cementation, loading conditions, and the elastic modulus of the supporting die. PEEK copings demonstrated a higher fracture resistance than zirconia copings due to the polycrystalline nature of PEEK. The results obtained in the current study are promising under laboratory conditions; however, it is necessary to investigate the properties of PEEK and zirconia copings in clinical or oral conditions. PEEK is emerging as a promising material due to its exceptional properties, and its use in both removable and fixed prostheses can be highly recommended. More studies should be encouraged to compare the load-bearing capacity, as well as, the fit of PEEK and zirconia.

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DOI and Others

DOI: 10.7860/JCDR/2024/73093.20281

Date of Submission: May 29, 2024
Date of Peer Review: Jul 01, 2024
Date of Acceptance: Aug 29, 2024
Date of Publishing: Nov 01, 2024

AUTHOR DECLARATION:
• Financial or Other Competing Interests: None
• Was Ethics Committee Approval obtained for this study? Yes
• Was informed consent obtained from the subjects involved in the study? No
• For any images presented appropriate consent has been obtained from the subjects. NA

PLAGIARISM CHECKING METHODS:
• Plagiarism X-checker: May 30, 2024
• Manual Googling: Jul 02, 2024
• iThenticate Software: Aug 28, 2024 (16%)

ETYMOLOGY: Author Origin

EMENDATIONS: 7

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