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1. Multi-objective optimization of custom implant abutment design for enhanced bone remodeling in single-crown implants using 3D finite element analysis

Author

Pongsakorn Poovarodom, Chaiy Rungsiyakull, Jarupol Suriyawanakul, Qing Li, Keiichi Sasaki, Nobuhiro Yoda, and Pimduen Rungsiyakull

Subjects
Optimization, Bone remodeling, Dental implant, Customized abutment, Finite element analysis, Medicine, Science
Abstract

Abstract The optimal configuration of a customized implant abutment is crucial for bone remodeling and is influenced by various design parameters. This study introduces an optimization process for designing two-piece zirconia dental implant abutments. The aim is to enhance bone remodeling, increase bone density in the peri-implant region, and reduce the risk of late implant failure. A 12-month bone remodeling algorithm subroutine in finite element analysis to optimize three parameters: implant placement depth, abutment taper degree, and gingival height of the titanium base abutment. The response surface analysis shows that implant placement depth and gingival height significantly impact bone density and uniformity. The taper degree has a smaller effect on bone remodeling. The optimization identified optimal values of 1.5 mm for depth, 35° for taper, and 0.5 mm for gingival height. The optimum model significantly increased cortical bone density from 1.2 to 1.937 g/cm3 in 2 months, while the original model reached 1.91 g/cm3 in 11 months. The standard deviation of density showed more uniform bone apposition, with the optimum model showing values 2 to 6 times lower than the original over 12 months. The cancellous bone showed a similar trend. In conclusion, the depth and taper have a significant effect on bone remodeling. This optimized model significantly improves bone density uniformity.

Published
2024
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2. Accuracy of implant placement with computer-aided static, dynamic, and robot-assisted surgery: a systematic review and meta-analysis of clinical trials

Author

Angkoon Khaohoen, Warit Powcharoen, Tanapon Sornsuwan, Pisaisit Chaijareenont, Chaiy Rungsiyakull, and Pimduen Rungsiyakull

Subjects
Robotic guide surgery, Image-guided surgery, Computer-assisted implantation, Surgical navigation, Dental implants, Systematic review, Dentistry, RK1-715
Abstract

Abstract This systematic review explores the accuracy of computerized guided implant placement including computer-aided static, dynamic, and robot-assisted surgery. An electronic search up to February 28, 2023, was conducted using the PubMed, Embase, and Scopus databases using the search terms “surgery”, “computer-assisted”, “dynamic computer-assisted”, “robotic surgical procedures”, and “dental implants”. The outcome variables were discrepancies including the implant’s 3D-coronal, -apical and -angular deviations. Articles were selectively retrieved according to the inclusion and exclusion criteria, and the data were quantitatively meta-analysed to verify the study outcomes. Sixty-seven articles were finally identified and included for analysis. The accuracy comparison revealed an overall mean deviation at the entry point of 1.11 mm (95% CI: 1.02–1.19), and 1.40 mm (95% CI: 1.31–1.49) at the apex, and the angulation was 3.51˚ (95% CI: 3.27–3.75). Amongst computerized guided implant placements, the robotic system tended to show the lowest deviation (0.81 mm in coronal deviation, 0.77 mm in apical deviation, and 1.71˚ in angular deviation). No significant differences were found between the arch type and flap operation in cases of dynamic navigation. The fully-guided protocol demonstrated a significantly higher level of accuracy compared to the pilot-guided protocol, but did not show any significant difference when compared to the partially guided protocol. The use of computerized technology clinically affirms that operators can accurately place implants in three directions. Several studies agree that a fully guided protocol is the gold standard in clinical practice.

Published
2024
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3. The Integration of Gold Nanoparticles into Dental Biomaterials as a Novel Approach for Clinical Advancement: A Narrative Review

Author

Saharat Jongrungsomran, Dakrong Pissuwan, Apichai Yavirach, Chaiy Rungsiyakull, and Pimduen Rungsiyakull

Subjects
gold nanoparticles, dental biomaterial, antimicrobial activity, osteogenic activity, cell adhesion, cell proliferation, Biotechnology, TP248.13-248.65, Medicine (General), R5-920
Abstract

Gold nanoparticles (AuNPs) have gained significant attention in the biomedical field owing to their versatile properties. AuNPs can be customized by modifying their size, shape and surface characteristics. In recent years, extensive research has explored the integration of AuNPs into various dental materials, including titanium, polymethylmethacrylate (PMMA) and resin composites. This review aims to summarize the advancements in the application of modified AuNPs in dental materials and to assess their effects on related cellular processes in the dental field. Relevant articles published in English on AuNPs in association with dental materials were identified through a systematic search of the PubMed/MEDLINE, Embase, Scopus and ScienceDirect databases from January 2014 to April 2024. Future prospects for the utilization of AuNPs in the field of dentistry are surveyed.

Published
2024
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4. Titanium Surface Modification Techniques to Enhance Osteoblasts and Bone Formation for Dental Implants: A Narrative Review on Current Advances

Author

Sivakorn Tuikampee, Pisaisit Chaijareenont, Pimduen Rungsiyakull, and Apichai Yavirach

Subjects
surface treatment, sandblasting, acid etching, SLA, anodization, laser radiation, Mining engineering. Metallurgy, TN1-997
Abstract

Surface modifications for titanium, a material of choice for dental implants, can greatly alter the surface micro/nanotopography and composition of implants, leading to notable enhancements in their hydrophilicity, mechanical properties, osseointegration performance, and antibacterial performance, as well as their impacts on osteoblast activity and bone formation processes. This article aims to update titanium surface modification techniques for dental implants from the past to the present, along with their effects on osteoblasts and bone formation, by thoroughly summarizing findings from published studies. Peer-reviewed articles published in English consisting of in vitro, in vivo, and clinical studies on titanium dental implant surface treatments were searched in Google Scholar, PubMed/MEDLINE, ScienceDirect, and the Scopus databases from January 1983 to December 2023 and included in this review. The previous studies show that implant surface roughness, condition, and hydrophilicity are crucial for osteoblast adhesion and growth. While various techniques enhance osseointegration comparably, one of the most common approaches to accomplishing these properties is sandblasting large-grit acid etching surface treatment and coating with hydroxyapatite or chitosan. In conclusion, this review points out the efficacy of different subtraction and addition techniques in enhancing the surface properties of titanium dental implants, promoting favorable outcomes in terms of osteoblast activity and bone formation in various degrees. However, most existing studies predominantly compare treated and non-treated titanium, revealing a need for more comprehensive studies comparing the effects of various modification techniques. Moreover, further investigation of factors playing a role in the dynamic osseointegration process in addition to osteoblasts and their functions, as well as improved surface modification techniques for the treatment of compromised patients, is greatly required.

Published
2024
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5. Wear Behavior of Different Generations of Zirconia: Present Literature

Author

Kuljirarnat Jitwirachot, Pimduen Rungsiyakull, Julie A. Holloway, and Wissanee Jia-mahasap

Subjects
Dentistry, RK1-715
Abstract

Objective. The wear behavior of the novel zirconia generation is less well understood and may be affected by compositional modifications compared to the conventional zirconia. Materials and Methods. Combinations of keywords such as “zirconia,” “high translucent,” and “wear” were searched in PubMed and Google Scholar databases up to May 2021. The total of 23 relevant articles was selected according to inclusion criteria. Results. Reports show comparable wear resistance of translucent zirconia to the conventional zirconia despite an increased cubic phase content and lower mean flexural strength. A meticulously polished surface creates the lowest surface roughness, producing favorable zirconia wear resistance and antagonist wear compared to a glazed surface. In comparison to other ceramic materials, zirconia produces the least wear on an enamel antagonist and almost undetectable wear when opposed by zirconia. Wear when paired against resin materials yields a favorable outcome, whereas wear behavior against a metal antagonist varies with the surface hardness of the metal. Conclusions. All zirconia generations are considered wear-friendly to all types of antagonists. Nonetheless, comparative studies on antagonist wear opposing zirconia of different compositions are still limited and further investigation is required.

Published
2022
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6. Stress Distribution Pattern in Mini Dental Implant-Assisted RPD with Different Clasp Designs: 3D Finite Element Analysis

Author

Chaiy Rungsiyakull, Pimduen Rungsiyakull, Kullapop Suttiat, and Nut Duangrattanaprathip

Subjects
Dentistry, RK1-715
Abstract

Introduction. The removable partial denture (RPD) components, especially the retentive arm, play a major role in the loading characteristic on supporting structures. Objective. To evaluate and compare the effect of different clasp designs on the stress distribution pattern, maximum von Mises stress, and average hydrostatic pressure on abutment teeth, as well as edentulous ridges, mini dental implants (MDIs), and peri-implant bone between the conventional removable partial denture (CRPD) and mini dental implant-assisted distal extension removable partial denture (IARPD) using a three-dimensional finite element analysis (3D FEA). Materials and Methods. 3D FEA models of mandibular arches, with and without bilateral MDI at the second molar areas, and Kennedy class I RPD frameworks, with RPA, RPI, Akers, and no clasp component, were generated. A total of 200 N vertical load was bilaterally applied on both sides of distal extension areas, and the stress was analyzed by 3D FEA. Results. The stress concentration of IARPD with RPI clasp design was located more lingually on abutment teeth, MDI, and peri-implant bone, while the other designs were observed distally on the supporting structures. The maximum von Mises stress on the abutment root surface was decreased when the RPDs were assisted with MDIs. The CRPD and IARPD with the Akers clasp design showed the highest von Mises stress followed by the designs with RPA and RPI clasp, respectively. The average hydrostatic pressure in each group was in approximation. Conclusion. The placement of MDIs on distal extension ridges helps to reduce the stress concentration on denture supporting structures. The maximum von Mises stress is affected by the different designs of clasp components. The CRPD and the IARPD with RPI clasp provide the least stress on supporting structures.

Published
2022
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7. Effect of Number and Location on Stress Distribution of Mini Dental Implant-Assisted Mandibular Kennedy Class I Removable Partial Denture: Three-Dimensional Finite Element Analysis

Author

Wissanee Jia-mahasap, Chaiy Rungsiyakull, Wipahatpong Bumrungsiri, Natthaphorn Sirisereephap, and Pimduen Rungsiyakull

Subjects
Dentistry, RK1-715
Abstract

Purpose. To investigate effects of number and location on patterns of von Mises stress distribution and volume average stress on abutment tooth, edentulous ridge, mini dental implant, and surrounding bone of mini dental implant-assisted mandibular Kennedy class I removable partial denture. Materials and Methods. Eight three-dimensional finite element models of mandibular Kennedy class I with different numbers and locations of mini dental implants were constructed. Mini dental implants were generated in the area of second premolar, first molar, and second molar, respectively. A static load of 400 N was applied on all models. The von Mises stress and volumetric average stress were calculated by three-dimensional finite element analysis. Result. The minimum volumetric average stress of abutment tooth was found in the model, where there was one mini dental implant at the second molar position and 2 mini dental implants at first molar and second molar positions. The model with three mini dental implants had reduced volumetric average stress of abutment tooth, which was not different from the model with two mini dental implants. However, the minimum volumetric average stress of mini dental implant and surrounding bone were found when three mini dental implants were applied, followed by two and one mini dental implants, respectively. Conclusion. Placing at least one mini dental implant at a second molar position can help reduce stress transferred to the abutment tooth. Stresses around each implant and surrounding bone reduced with increased numbers of mini dental implants.

Published
2022
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8. Biomaterials and Clinical Applications of Customized Healing Abutment—A Narrative Review

Author

Parima Chokaree, Pongsakorn Poovarodom, Pisaisit Chaijareenont, Apichai Yavirach, and Pimduen Rungsiyakull

Subjects
customized healing abutment, implant abutment, dental abutment, PEEK, PMMA, titanium, Biotechnology, TP248.13-248.65, Medicine (General), R5-920
Abstract

Customized healing abutments have been introduced in clinical practice along with implant surgery to preserve or create natural-appearing hard and soft tissue around the implant. This provides the benefits of reducing the overall treatment time by eliminating the second stage and reducing the elapsed time of the fabrication of the final prostheses. This article aims to review the types and properties of materials used for the fabrication of customized healing abutments and their clinical applications. Articles published in English on customized healing abutments were searched in Google Scholar, PubMed/MEDLINE, ScienceDirect, and the Scopus databases up to August 2022. The relevant articles were selected and included in this literature review. Customized healing abutments can be fabricated from materials available for dental implants, including PEEK, PMMA, zirconia, resin composite, and titanium. All the materials can be used following both immediate and delayed implant placement. Each material provides different mechanical and biological properties that influence the peri-implant tissues. In conclusion, the studies have demonstrated promising outcomes for all the materials. However, further investigation comparing the effects of each material on peri-implant soft and hard tissues is required.

Published
2022
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9. Effect of the Location of Dental Mini-Implants on Strain Distribution under Mandibular Kennedy Class I Implant-Retained Removable Partial Dentures

Author

Pimduen Rungsiyakull, Kallaya Kujarearntaworn, Pathawee Khongkhunthian, Michael Swain, and Chaiy Rungsiyakull

Subjects
Dentistry, RK1-715
Abstract

Purpose. To investigate the effect of minidental implant location on strain distributions transmitted to tooth abutments and dental minidental implants under mandibular distal extension removable partial denture. Materials and Methods. A mandibular Kennedy Class I distal extension model missing teeth 35–37 and 45–47 was constructed. Six dental mini-implants were placed at positions A, B, and C, where position A was 6.5 mm distal to the abutment teeth with 5 mm between each position. Fourteen uniaxial strain gauges were bonded on the model at the region of dental mini-implant and abutment (first premolar). Four groups were designated according to the location of the mini-implants. A load of 150 N and 200 N was applied using an Instron testing machine. Loadings consisted of bilateral and unilateral loading. Comparisons of the mean microstrains among all strain gauges in all situations were analyzed. Results. Variation in mini-implant locations induced local strains in different areas. Strains at the tooth abutment were significantly decreased in the group in which implants were placed mesially. Strains around the mini-implants showed different patterns when loaded with different loading conditions. The group in which implants were placed distally showed the lowest strains compared to other groups. Conclusion. Mesially placed mini-implants showed the lowest strain around abutment teeth, while a distally-placed mini-implants presented the lowest strain around mini-implants themselves. Under favorable biting force, mini-implant is an option to assist mandibular distal extension removable partial denture. Mesially placed mini-implants are recommended when the abutment has periodontally compromised conditions and a distally placed mini-implant when periodontal conditions are stable.

Published
2021
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10. Validity and Reliability of Intraoral Camera with Fluorescent Aids for Oral Potentially Malignant Disorders Screening in Teledentistry

Author

Sirikanlaya Vetchaporn, Wetchayan Rangsri, Jitjiroj Ittichaicharoen, and Pimduen Rungsiyakull

Subjects
Dentistry, RK1-715
Abstract

There is limited documentation of using fluorescence images in oral potentially malignant disorders (OPMDs) and oral cancer screening through the field of teledentistry. This study aims to develop and evaluate the validity and reliability of the intraoral camera with the combination method of autofluorescence and LED white light used for OPMDs and oral cancer screening in teledentistry. The intraoral camera with fluorescent aids, which uses a combined method of both autofluorescence and LED white light, was developed before the device was evaluated for validity and reliability as a OPMDs screening tool for teledentistry. All lesions of thirty-four OPMD patients underwent biopsy for definitive diagnosis and were examined by an oral medicine specialist. Both images under autofluorescent and LED white light mode captured from the device were sent online and interpreted for the initial diagnosis and dysplastic features in addition to being compared to the direct clinical examination and histopathological findings. The combination method was also compared with autofluorescence method alone. The device provided good image quality, which was enough for initial diagnosis. Using the combination method, sensitivity, specificity, PPV, and NPV of the device via teledentistry were 87.5%, 84.6%, 63.6%, and 95.7%, respectively, which were higher than autofluorescence method alone in every parameter. The concordance of dysplastic lesion was 85.29% and 79.41% for category of lesion. The validity and reliability results of the combination method for the screening of dysplasia in OPMDs were higher than autofluorescent method alone. The intraoral camera with fluorescent aids for the OPMDs screening can be utilized for screening via teledentistry.

Published
2021
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11. PEEK Biomaterial in Long-Term Provisional Implant Restorations: A Review

Author

Suphachai Suphangul, Dinesh Rokaya, Chatruethai Kanchanasobhana, Pimduen Rungsiyakull, and Pisaisit Chaijareenont

Subjects
polyetheretherketone, PEEK, carbon fiber, provisional restoration, provisional crown, implant prostheses, Biotechnology, TP248.13-248.65, Medicine (General), R5-920
Abstract

Polyetheretherketone (PEEK) has become a useful polymeric biomaterial due to its superior properties and has been increasingly used in dentistry, especially in prosthetic dentistry and dental implantology. Promising applications of PEEK in dentistry are dental implants, temporary abutment, implant-supported provisional crowns, fixed prosthesis, removable denture framework, and finger prosthesis. PEEK as a long-term provisional implant restoration has not been studied much. Hence, this review article aims to review PEEK as a long-term provisional implant restoration for applications focusing on implant dentistry. Articles published in English on PEEK biomaterial for long-term provisional implant restoration were searched in Google Scholar, ScienceDirect, PubMed/MEDLINE, and Scopus. Then, relevant articles were selected and included in this literature review. PEEK presents suitable properties for various implant components in implant dentistry, including temporary and long-term provisional restorations. The modifications of PEEK result in wider applications in clinical dentistry. The PEEK reinforced by 30–50% carbon fibers can be a suitable material for the various implant components in dentistry.

Published
2022
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13. Effect of implant placement depth on bone remodeling on implant-supported single zirconia abutment crown: A 3D finite element study

Author

Pongsakorn Poovarodom, Chaiy Rungsiyakull, Jarupol Suriyawanakul, Qing Li, Keiichi Sasaki, Nobuhiro Yoda, and Pimduen Rungsiyakull

Subjects
Dentistry (miscellaneous), Oral Surgery
Abstract

This study aimed to evaluate the influence of subcrestal implant placement depth on bone remodeling using time-dependent finite element analysis (FEA) with a bone-remodeling algorithm over 12 months.Seven models of different subcrestal implant placement depths (0, 0.5, 1.0, 1.5, 2.0, 2.5, and 3.0 mm) were analyzed using FEA to evaluate the biomechanical responses in the bone and implant, including von Mises equivalent stress, strain energy density (SED), and overloading elements. SED was used as a mechanical stimulus to simulate cortical and cancellous bone remodeling over the first 12 months after final prosthesis delivery.The highest increase in cortical bone density was observed at Depth 1.5, whereas the lowest increase was observed at Depth 3.0. In contrast, the highest increase in bone density was observed at Depth 3.0 in the cancellous bone, whereas the lowest increase was observed at Depth 0. The highest peak von Mises stress in the cortical bone occurred at Depth 2.5 (107.24 MPa), while that in the cancellous bone was at Depth 2.5 (34.55 MPa). Notably, the maximum von Mises stress values in the cancellous bone exceeded the natural limit of the bony material, as indicated by the overloading elements observed at the depths of 2.0, 2.5, and 3.0 mm.Greater bone density apposition is observed with deeper implant placement. An implant depth of more than 1.5 mm exhibited a higher maximum von Mises stress and greater overloading elements.

Published
2022

14. Effect of the Location of Dental Mini-Implants on Strain Distribution under Mandibular Kennedy Class I Implant-Retained Removable Partial Dentures

Author

Pathawee Khongkhunthian, Michael V. Swain, Pimduen Rungsiyakull, Kallaya Kujarearntaworn, and Chaiy Rungsiyakull

Subjects
Orthodontics, Article Subject, business.industry, medicine.medical_treatment, Abutment, RK1-715, 030209 endocrinology & metabolism, 030206 dentistry, Bite force quotient, stomatognathic diseases, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, stomatognathic system, Mini implants, Dentistry, Premolar, Medicine, Implant, Dentures, business, General Dentistry, Strain gauge, Research Article, Removable partial denture
Abstract

Purpose. To investigate the effect of minidental implant location on strain distributions transmitted to tooth abutments and dental minidental implants under mandibular distal extension removable partial denture. Materials and Methods. A mandibular Kennedy Class I distal extension model missing teeth 35–37 and 45–47 was constructed. Six dental mini-implants were placed at positions A, B, and C, where position A was 6.5 mm distal to the abutment teeth with 5 mm between each position. Fourteen uniaxial strain gauges were bonded on the model at the region of dental mini-implant and abutment (first premolar). Four groups were designated according to the location of the mini-implants. A load of 150 N and 200 N was applied using an Instron testing machine. Loadings consisted of bilateral and unilateral loading. Comparisons of the mean microstrains among all strain gauges in all situations were analyzed. Results. Variation in mini-implant locations induced local strains in different areas. Strains at the tooth abutment were significantly decreased in the group in which implants were placed mesially. Strains around the mini-implants showed different patterns when loaded with different loading conditions. The group in which implants were placed distally showed the lowest strains compared to other groups. Conclusion. Mesially placed mini-implants showed the lowest strain around abutment teeth, while a distally-placed mini-implants presented the lowest strain around mini-implants themselves. Under favorable biting force, mini-implant is an option to assist mandibular distal extension removable partial denture. Mesially placed mini-implants are recommended when the abutment has periodontally compromised conditions and a distally placed mini-implant when periodontal conditions are stable.

Published
2021

15. Effects of composite resin core level and periodontal pocket depth on crack propagation in endodontically treated teeth: An extended finite element method study

Author

Narissara Boonrawd, Pimduen Rungsiyakull, Chaiy Rungsiyakull, and Phumisak Louwakul

Subjects
Dental Stress Analysis, Tooth, Nonvital, Finite Element Analysis, Humans, Periodontal Pocket, Oral Surgery, Composite Resins
Abstract

Preserving teeth with radicular cracks with or without a periodontal pocket is an alternative to extraction. However, an effective protocol for the restoration of radicular cracks is lacking.The purpose of this study was to examine the composite resin core level and periodontal pocket depth effects on stress distribution, maximum von Mises stress, and crack propagation in endodontically treated teeth by using the extended finite element (FE) method.Four 3-dimensional models of a cracked endodontically treated mandibular first molar were constructed: PP2C2 (periodontal pocket depth, 2 mm; composite resin core level, 2 mm below the canal orifice level); PP2C4 (periodontal pocket depth, 2 mm; composite resin core level, 2 mm below the crack level); PP4C2 (periodontal pocket depth, 4 mm; composite resin core level, 2 mm below the canal orifice level); and PP4C4 (periodontal pocket depth, 4 mm; composite resin core level, 2 mm below the crack level). The crack initiation was at the same level in all models. A static 700-N load was applied to the models in a vertical direction.The highest stress in dentin was observed in PP2C2, whereas PP2C4 exhibited the lowest stress and least crack propagation. Stress was high in the dentin and supporting bone. No reduction in crack propagation was observed in the PP4 models, regardless of the composite resin core level.The periodontal pocket depth (2 mm and 4 mm) and composite resin core level (2 mm below the crack level and 2 mm below the canal orifice level) affected stress concentration in dentin, resulting in different patterns of crack propagation in the FE models.

Published
2021

16. Wear of various restorative materials against 5Y-ZP zirconia

Author

Wissanee Jia-mahasap, Kuljirarnat Jitwirachot, Julie A. Holloway, Wetchayan Rangsri, and Pimduen Rungsiyakull

Subjects
Dental Materials, Ceramics, Silver, Surface Properties, Materials Testing, Alloys, Humans, Zirconium, Esthetics, Dental, Oral Surgery, Dental Porcelain, Palladium
Abstract

The ceramic 5-mol% yttria-stabilized zirconia (5Y-ZP) has been developed for dental use in the esthetic zone with greater translucency than 3-mol% yttria-stabilized zirconia (3Y-ZP). However, studies on the wear behavior of 5Y-ZP zirconia against clinically relevant antagonist materials are lacking.The purpose of this in vitro study was to investigate the wear behavior of 5Y-ZP zirconia against the antagonists 5Y-ZP zirconia, lithium disilicate, palladium alloy, and human enamel.Flat specimens (n=8) were fabricated from 5Y-ZP zirconia, lithium disilicate, palladium alloy, and human central incisor enamel. A custom wear-simulating device with a sliding pin-on-plate configuration was used for a total of 120 000 wear cycles at 1.6-Hz frequency under a 49-N vertical load while submerged in distilled water at room temperature. The wear volume and maximum wear depth of flat specimens were evaluated with a 3D profilometer. Scanning electron microscopy was used to analyze the characteristics of the worn surfaces.After wear simulation, the 5Y-ZP zirconia and palladium-silver alloy specimens exhibited the least amount of material loss, both in terms of maximum wear depth and wear volume (0.079 ±0.042 μm, 0.001 ±0.001 mmThe 5Y-ZP zirconia and palladium-silver alloy exhibited the lowest wear, followed by human enamel and lithium disilicate. Slight grain dislodgement was displayed on worn 5Y-ZP surfaces, while more apparent grain dislodgement and wear grooves were found on lithium disilicate. Plastic deformation of worn palladium-silver alloy accumulated at the end of wear track. Cracks were detected in the human enamel specimens.

Published
2022

17. Comparative study of stress characteristics in surrounding bone during insertion of dental implants of three different thread designs: A three-dimensional dynamic finite element study

Author

Chaiy Rungsiyakull, Pathawee Khongkhunthian, Pimduen Rungsiyakull, and Chaiwat Udomsawat

Subjects
Dental Stress Analysis, Materials science, medicine.medical_treatment, Finite Element Analysis, 0211 other engineering and technologies, 02 engineering and technology, Bone healing, 03 medical and health sciences, Imaging, Three-Dimensional, 0302 clinical medicine, stress distribution, Cortical Bone, medicine, Humans, von Mises yield criterion, Computer Simulation, Dental implant, General Dentistry, 021106 design practice & management, Stress concentration, Dental Implants, Stress–strain curve, Original Articles, 030206 dentistry, Models, Dental, Biomechanical Phenomena, dynamic finite element, Dental Implantation, medicine.anatomical_structure, Dental Prosthesis Design, Original Article, Cortical bone, Stress, Mechanical, Implant, implant design, Cancellous bone, implants insertion, Biomedical engineering
Abstract

The objective of this study is to evaluate the stress distribution characteristics around three different dental implant designs during insertion into bone, using dynamic finite element stress analysis. Dental implant placement was simulated using finite element models. Three implants with different thread and body designs (Model 1: root form implant with three different thread shapes; Model 2: tapered implant with a double‐lead thread; and Model 3: conical tapered implant with a constant buttress thread) were assigned to insert into prepared bone cavity models until completely placed. Stress and strain distributions were descriptively analyzed. The von Mises stresses within the surrounding bone were measured. At the first 4‐mm depth of implant insertion, maximum stress within cortical bone for Model 3 (175 MPa) was less than the other models (180 MPa each). Stress values and concentration area were increasing whereas insertion depth increased. At full implant insertion depth, maximum stress level in Model 1 (35 MPa) within the cancellous bone was slightly greater than in Models 2 (30 MPa) and 3 (25 MPa), respectively. Generally, for all simulations, the highest stress value and the location of the stress concentration area were mostly in cortical bone. However, the stress distribution patterns during the insertion process were different between the models depending on the different designs geometry that contacted the surrounding bone. Different implant designs affect different stress generation patterns during implant insertion. A range of stress magnitude, generated in the surrounding bone, may influence bone healing around dental implants and final implant stability.

Published
2018

20. Validity and Reliability of Intraoral Camera with Fluorescent Aids for Oral Potentially Malignant Disorders Screening in Teledentistry

Author

Pimduen Rungsiyakull, Wetchayan Rangsri, Jitjiroj Ittichaicharoen, and Sirikanlaya Vetchaporn

Subjects
medicine.medical_specialty, Article Subject, medicine.diagnostic_test, business.industry, Concordance, Physical examination, RK1-715, Oral Medicine Specialist, medicine.disease, Autofluorescence, Dysplasia, Dentistry, Intraoral camera, Biopsy, medicine, Radiology, business, Teledentistry, General Dentistry, Research Article
Abstract

There is limited documentation of using fluorescence images in oral potentially malignant disorders (OPMDs) and oral cancer screening through the field of teledentistry. This study aims to develop and evaluate the validity and reliability of the intraoral camera with the combination method of autofluorescence and LED white light used for OPMDs and oral cancer screening in teledentistry. The intraoral camera with fluorescent aids, which uses a combined method of both autofluorescence and LED white light, was developed before the device was evaluated for validity and reliability as a OPMDs screening tool for teledentistry. All lesions of thirty-four OPMD patients underwent biopsy for definitive diagnosis and were examined by an oral medicine specialist. Both images under autofluorescent and LED white light mode captured from the device were sent online and interpreted for the initial diagnosis and dysplastic features in addition to being compared to the direct clinical examination and histopathological findings. The combination method was also compared with autofluorescence method alone. The device provided good image quality, which was enough for initial diagnosis. Using the combination method, sensitivity, specificity, PPV, and NPV of the device via teledentistry were 87.5%, 84.6%, 63.6%, and 95.7%, respectively, which were higher than autofluorescence method alone in every parameter. The concordance of dysplastic lesion was 85.29% and 79.41% for category of lesion. The validity and reliability results of the combination method for the screening of dysplasia in OPMDs were higher than autofluorescent method alone. The intraoral camera with fluorescent aids for the OPMDs screening can be utilized for screening via teledentistry.

Published
2021

21. The Effect of Various Types of Coupling Agent Solution on the Surface Wettability of Polyoxymethylene.

Author

Pranmas Teeranuwat, Thanapat Sastraruji, Pimduen Rungsiyakull, and Pisaisit Chaijareenont

Subjects
POLYOXYMETHYLENE, WETTING, CONTACT angle, SURFACE roughness, SURFACE preparation
Abstract

The purpose of this study was to investigate the effect of various types of coupling agent solutions as a surface treatment of polyoxymethylene (POM) on surface roughness and wettability. Seventy-five POM specimens were fabricated from polyoxymethylene CAD-CAM blocks and divided into non-treated (control) and 4 coupling agent solutions treated groups (n=15/group): MPS, APS, AAPMS, and Clearfil Ceramic Primer (CCP). Fifteen specimens of each treated group were assessed with a goniometer via sessile drop method and profilometer to determine surface roughness and contact angle; morphological changes in untreated and treated specimens were examined by using scanning electron microscopy and element depositions were analyzed by using energy dispersive spectrometer (EDS). One-way ANOVA was used at p< 0.05 for statistical comparison. POM specimens treated with MPS and CCP resulted in significantly lower contact angle than control, APS and AAPMS groups (p<0.05). No differences in contact angle were measured between MPS (62.2±9.9°) and CCP (52.1 ±13.0°); and also, between control (90.8±4.1°), APS (91.1 ±5.0°) and AAPMS (85.6±7.3°). Surface roughness was not significantly different after treatment between groups (p<0.05). EDS analysis showed silica on MPS, APS, AAPS and CCP. Contrary to phosphorus, that was discovered on CCP only. The surface roughness of all test groups was similar. POM treated with MPS and CCP exhibited the lowest contact angle. [ABSTRACT FROM AUTHOR]

Published
2022

22. Bone’s responses to different designs of implant-supported fixed partial dentures

Author

Michael V. Swain, Junning Chen, Chaiy Rungsiyakull, Qing Li, Wei Li, and Pimduen Rungsiyakull

Subjects
Materials science, Bone density, Finite Element Analysis, Dentistry, Mandible, Prosthesis Design, Models, Biological, Bone and Bones, Osseointegration, Bone remodeling, Bone Density, Premolar, medicine, Humans, Dental Implants, business.industry, Mechanical Engineering, Biomechanics, Biomechanical Phenomena, Resorption, Resonance frequency analysis, medicine.anatomical_structure, Modeling and Simulation, Denture, Partial, Fixed, Stress, Mechanical, Implant, business, Algorithms, Biotechnology
Abstract

This paper explores the biomechanics and associated bone remodeling responses of two different abutment configurations, namely implant-implant-supported versus tooth-implant-supported fixed partial dentures. Two 3D finite element analysis models are created based upon computerized tomography data. The strain energy density induced by occlusal loading is used as a mechanical stimulus for driving the bone remodeling. To measure osseointegration and stability during healing, a resonance frequency analysis is conducted. At the second premolar peri-implant region, overloading resorption around the neck of implant is identified in both the models over the first 12 months. Stress-shielding around the edentulous region is also observed in both the models with a greater resorption rate found in the implant-implant case. The remodeling and resonance frequency analyses reveal that the tooth-implant scheme offers a higher degree of osseointegration. The remodeling procedure is expected to provide prosthodontists with a modeling tool to assess possible long-term clinical outcomes.

Published
2014

23. Effects of different numbers of mini-dental implants on alveolar ridge strain distribution under mandibular implant-retained overdentures

Author

Pathawee Khongkhunthian, Pongsakorn Warin, Pimduen Rungsiyakull, and Chaiy Rungsiyakull

Subjects
Dental Stress Analysis, Materials science, Compressive Strength, medicine.medical_treatment, 0206 medical engineering, Dentistry, 02 engineering and technology, Mandible, 03 medical and health sciences, 0302 clinical medicine, Tensile Strength, Alveolar ridge, medicine, Alveolar Process, Jaw, Edentulous, Dentistry (miscellaneous), Orthodontics, Dental Implants, business.industry, 030206 dentistry, Denture, Overlay, 020601 biomedical engineering, Denture Retention, Molar, Strain distribution, Posterior teeth, Implant, Stress, Mechanical, Oral Surgery, Dentures, business
Abstract

Purpose To investigate the strains around mini-dental implants (MDIs) and retromolar edentulous areas when using different numbers of MDIs in order to retain mandibular overdentures. Materials and methods Four different prosthetic situations were fabricated on an edentulous mandibular model including a complete denture (CD), and three overdentures, retained by four, three or two MDIs in the interforaminal region with retentive attachments. A static load of 200N was applied on the posterior teeth of the dentures under bilateral or unilateral loading conditions. The strains at the mesial and distal of the MDIs and the retromolar edentulous ridges were measured using twelve strain gauges. Comparisons of the mean microstrains among all strain gauges in all situations were analyzed. Results The strain distribution determined during bilateral loading experienced a symmetrical distribution; while during unilateral loading, the recorded strains tended to change from compressive strains on the loaded side to tensile strains. Overall, the number of MDIs was found to be passively correlated to the generated compressive strain. The highest strains were recorded in the four MDIs followed by three, two MDIs retained overdenture and CD situations, respectively. The highest strain was found around the terminal MDI. Conclusions The use of a low number of MDIs tends to produce low strain values in the retromolar denture-bearing area and around the terminal MDIs during posterior loadings. However, when using a high number of MDIs, the overdenture tends to have more stability during function.

Published
2016

24. Fracture Analysis of Post Material and Bonding Condition on A Cylindrical Glass-Resin Bilayer Structure.

Author

Pimduen Rungsiyakull, Kanittha Kasetwong, Apichai Yavirach, and Tanapon Sornsuwan

Subjects
METAL fibers, STRESS concentration, AXIAL loads, MATERIALS analysis, DEAD loads (Mechanics)
Abstract

The study aimed to develop a biomechanics model to identify the effects of post material and bonding condition on the vertical cracking of a glass-resin bilayer structure under applied axial load. The specimens consisted of cylindrical glass tubes, in which metal or fiber posts were centered and which were filled with a resin core material. Fifty specimens were divided into five groups, a control group without posts, and four experimental groups, depending on the type of post and whether bonding was used. A static load was applied using a universal testing machine and continued at 0.01 mm/min until fracture. The failure load was compared using statistical analysis (p <.05). Failure rate, fracture patterns, and failure probability were analyzed. The control group had the highest failure rate compared to groups in which posts were used. Bonded posts had no significant difference in failure rates, whereas unbonded metal posts had a higher failure rate than unbonded fiber posts. Unbonded metal posts had a significantly higher failure rate than bonded metal posts, whereas both unbonded and bonded fiber posts had no significant difference in failure rates. Post material and bonding condition affect the fracture resistance of the model. Metal and fiber posts may have similar fracture rates in cases with good bonding condition; however, fiber posts present a lower fracture rate than metal posts in cases with no bonding. Bonding condition can change peak stress concentration from the cervical area to the middle third of the glass tube. [ABSTRACT FROM AUTHOR]

Published
2019

26. Loading of a single implant in simulated bone

Author

Pimduen Rungsiyakull, Rungsiyakull, Chaiy, Appleyard, Richard, Li, Qing, Swain, Micheal, and Klineberg, Iven

Subjects
Models, Anatomic, Titanium, Crowns, Surface Properties, Acrylic Resins, Tooth, Artificial, Bone and Bones, Biomechanical Phenomena, Dental Materials, Dental Implants, Single-Tooth, Dental Prosthesis Design, Humans, Dental Prosthesis, Implant-Supported, Stress, Mechanical
Abstract

This study investigated the effect of occlusal design on the strain developed in simulated bone of implant-supported single crown models. Triaxial strain gauges were attached at the cervical area of each model. Occlusal design, load location, and magnitude were examined to determine the maximum axial principal strains (ΜÓ) of four occlusal designs: 30-degree cusp inclination with 4- and 6-mm occlusal table dimensions and a 10-degree cusp inclination with 4- and 6-mm occlusal table dimensions. Statistical differences were found for peak average maximum principal strains between each occlusal design when the applied load was directed along the central fossa and 2 mm buccal to the central fossa along the inclined plane, with strain gauges attached at the cervicobuccal (P.001) and cervicolingual (P ⋜ .001) aspects. In all loading conditions, the 30-degree cusp inclination and 6-mm occlusal table dimension consistently presented the largest strains compared with the other occlusal designs. A reduced cusp inclination and occlusal table dimension effectively reduced experimental bone strain on implant-supported single crowns. The occlusal table dimension appeared to have a relatively more important role than cusp inclination.

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