Relevant bibliographies by topics / Digital orthodontics

Academic literature on the topic 'Digital orthodontics'

Author: Grafiati
Published: 9 March 2023
Last updated: 10 March 2023

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Journal articles on the topic "Digital orthodontics"

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Wang, Qing, Ziran Jiang, Zhilun Xue, Wulin He, and Zhiwei He. "Application of Mathematical Model in Orthodontics." Mobile Information Systems 2022 (September 16, 2022): 1–12. http://dx.doi.org/10.1155/2022/5286225.

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With the development of digital information technology and big data technology, the medical industry has also undergone tremendous changes. Traditional medical treatment mainly relies on the technical experience of the attending doctor for treatment, and there is no sophisticated instrument or scientific analysis system to assist in treatment. With the improvement of people’s living standards, people’s attention to teeth has increased significantly. Traditional orthodontics is based on the subjective judgment of orthodontists and manual treatment. Due to the differences in the experience of orthodontists, the traditional orthodontic effect is often very poor. Using digital information and big data technology to carry out quantitative diagnosis and treatment analysis of teeth, 3D modeling, and simulation of prosthesis, personalized treatment of the prosthesis model, and finally applied to orthodontics, digital-based orthodontics make the orthodontic diagnosis and treatment process evidence-based, safer, and more effective. This article compares orthodontics and traditional oral orthodontics based on the mathematical model, to analyze the comfort of orthodontics, the aesthetics of orthodontics, the matching degree of aligners, and the stability of the environment in the periodontal ligament. It is concluded that the average orthodontic comfort based on the mathematical model is 85.6%, and the average aesthetic degree is 64.0%, which are more than 20% better than traditional orthodontics. It is also superior to traditional orthodontics in terms of the degree of matching of the appliance and the stability of the environment in the periodontal ligament. Therefore, the combination of mathematical models and orthodontics can lead to better orthodontic results.
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Pooja, R., S. Mahendra, A. V. Arun, P. Vinay Reddy, Aravind S. Raju, and C. M. Mahesh. "Digital marketing and social media in today’s orthodontic practice — Bridging the gap." Journal of Contemporary Orthodontics 6, no. 1 (April 15, 2022): 1–5. http://dx.doi.org/10.18231/j.jco.2022.001.

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To assess and determine the various aspects of the interrelationship between social and digital media and orthodontics from the patient's as well as orthodontist’s perspective. Determining where the patient looks for Orthodontist’s information online and where the orthodontist is posting or promoting their practice 2. Differentiating between patient interests on web page/social media and orthodontic posts 3. Comfort level of patients to visit an orthodontist based on digital media popularity/reviewsIn our 2-part survey, 2 separate google forms were created to assess the various aspects of practice promotion and sent to Orthodontists and patients separately. Demographic data and informed consent was taken.The survey comprises of two groups: A) Orthodontists (212 participants) B) Patients (200 participants)From the orthodontist’s perspective, patients visit them based on internet popularity. They promote their practice using their own website which is available on Google. Social media is used commonly to promote themselves by posting photos of patients and clinic. Facebook was most used. Orthodontists believe that 15-20% visit them based on internet popularity.From the patients perspective, they choose orthodontists based on popularity on internet with google search being the most used. They review orthodontists on social media on popular sites such as Instagram, WhatsApp, Facebook and Twitter. Word of mouth referrals was the most preferred old school method of finding orthodontists based on experience. With vast improvement in digital technology, youngsters prefer to review orthodontists based on digital media reviews as well. The largest discrepancy found between social media sites used by the patients/ parents and orthodontists was with Facebook and Instagram. This opportunity is being vastly ignored by most orthodontic practices and should be considered as a potential marketing tool for current and prospective patients.
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Balut, Nasib, Digant P. Thakkar, Enrique Gonzalez, Rodrigo Eluani, and Luis David Silva. "Digital orthodontic indirect bonding systems: A new wave." APOS Trends in Orthodontics 10 (September 18, 2020): 195–200. http://dx.doi.org/10.25259/apos_18_2020.

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Digital technologies are progressing with leaps and bounds and the field of orthodontics is not untouched by it, with innovations like intraoral scanners and 3D printers being easy to own and maintain and increased availability of biocompatible 3D printing materials orthodontist are curious to use this technology to improve orthodontic bracket positioning which would require minimal to no repositioning during the course of treatment. The authors here have tried to outline 2 different methods using CBCT and VTO as guide to decide the bracket positioning digitally and using 3D printed Indirect Bonding trays for orthodontic bonding.
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Mohammed Alassiry, Ahmed. "DIGITAL ORTHODONTICS- A CONTEMPORARY VIEW OF FUTURISTIC PRACTICE." International Journal of Advanced Research 9, no. 4 (April 30, 2021): 723–32. http://dx.doi.org/10.21474/ijar01/12758.

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The world is going digital and so is the speciality of orthodontics. The knowledge of computers is no longer rudimentary and the application of technology in orthodontics has grown exponentially. Conventional methods of running an orthodontic practice were limited and associated with multiple drawbacks. Owning and running a digital orthodontic practice is the need of the hour and necessity of the future. The aim of this review article is to encourage and promote the orthodontic community to integrate digital elements in their practice. This review article discusses in detail about the various aspects of digital orthodontics involving digital office, study models, three-dimensional imaging, rapid prototyping, virtual treatment planning, artificial intelligence and role of robots. This review article provides an insight into the capabilities and clinical application on currently available digital orthodontic technological systems.
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Acharya, Swati Saraswata, Pritam Mohanty, and Pavithra Rao. "How do I Imagine Orthodontic World in 2035." Orthodontic Journal of Nepal 7, no. 1 (June 30, 2017): 51–52. http://dx.doi.org/10.3126/ojn.v7i1.18903.

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The future orthodontic world is so bright that we definitely ‘need to wear shades’. We are infiltrating a new era of orthodontics accoutered with modern technologies. However, ever growing operating costs, greater patient expectations and indictments against orthodontists are few concerns which need to be addressed. Increased information technology skills, three-dimensional image superimposition methods, custom designed treatments, tooth movement control systems, digital models and evidencebased orthodontics will be the new outlook in the next twenty years. Orthodontic research is entering an epoch of exhilaration. Trends, issues and new evolutions can come together in startling ways. Scenarios are the recitals about the future that combine these forces of change in various ways. Genome wide coalition studies are vital to further the evidence base to practice orthodontics in the coming years.
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Anacleto, Murilo Augusto, and Bernardo Quiroga Souki. "Superimposition of 3D maxillary digital models using open-source software." Dental Press Journal of Orthodontics 24, no. 2 (April 2019): 81–91. http://dx.doi.org/10.1590/2177-6709.24.2.081-091.bbo.

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Abstract Historically, whether for research purposes or clinical monitoring, orthodontic evaluation of dental movements has been done using plaster study models and two dimensional (2D) radiographs. However, new frontiers for the diagnosis, planning and outcome assessment of orthodontic treatments have arisen, due to the revolutionary digital tools which enable a three dimensional (3D) computerized analysis of dental movements by means of digital models. However, the software for 3D analysis are often costly, resulting in limited access to orthodontists. The present study aims to describe, through a clinical case presented to the Brazilian Board of Orthodontics and Dentofacial Orthopedics, a method for the superimposition of maxillary digital models using an open-source software to evaluate dental movements.
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Agarwal, Anupam, Shalu Mahajan, and Santosh Verma. "Digital Single Lens Reflex Photography in Clinical Orthodontics: Revolution or Evolution." World Journal of Dentistry 5, no. 2 (2014): 118–23. http://dx.doi.org/10.5005/jp-journals-10015-1271.

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ABSTRACT The field of dentistry has witnessed a ‘Digital Revolution’ in the recent past which has made the maintenance of patient's pretreatment and post-treatment records a necessary protocol. The speciality of orthodontics depends heavily on patient's records for various purposes including diagnosis and treatment planning and patient motivation. The recent upsurge in digital technology has been both inviting and confusing as an orthodontist finds himself in a dilemma regarding which camera to choose for orthodontic photography. This research article tries to develop an understanding about the cameras to choose for the above mentioned purpose and that whether digital SLR technology is really a revolution or just an evolution. How to cite this article Agarwal A, Mahajan S, Verma S. Digital Single Lens Reflex Photography in Clinical Orthodontics: Revolution or Evolution. World J Dent 2014;5(2):118-123.
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Alqahtani, Jamal, Ghufran Alhemaid, Hussein Alqahtani, Ahmed Abughandar, Reem AlSaadi, Ibtihal Algarni, Wahiba AlSharif, et al. "Digital Diagnostics and Orthodontic Practice." JOURNAL OF HEALTHCARE SCIENCES 02, no. 06 (2022): 112–17. http://dx.doi.org/10.52533/johs.2022.2605.

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Orthodontic diagnosis is mostly dependent on the patient's dental and medical history, clinical examination, study models, and cephalometric radiographs, which are the most important tool for orthodontic diagnosis since they are used to identify abnormalities in the dental and craniofacial skeleton. An ever-increasing array of digital technologies is transforming dental therapy in a variety of ways. Digital dental models, the use of digital dental set-ups to simulate the eventual result of orthodontic therapy, and three-dimensional imaging of the dentofacial region are among the technological advances that provided new choices for patient documentation. Digital records allow for a three-dimensional evaluation of a patient's dentofacial morphology, which is critical for orthodontic diagnostics and treatment planning. Additionally, these digital records increase record storage, access, conservation, communication with patients, and duplication possibilities. The purpose of this research is to review the available information about the digital diagnostics and orthodontic practice. Since the introduction of threedimensional techniques, which have found different uses in orthodontics as well as oral and maxillofacial surgery, imaging technology in the dentistry sector has emerged as one of the most significant parts of identifying and managing oral problems. With the growing availability of cone-beam computed tomography, three-dimensional depiction of dentition, maxillofacial skeleton, and soft tissues in all phases of interactions is now possible. In orthodontics, digital scanning can be utilized for a variety of purposes. However, more research is needed to generate evidence-based results regarding the utilization of digital diagnostics in orthodontics.
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Doğan, Ege, and Çağlayan Öztürk. "Evaluation of Orthodontists' Perspective on Digital Orthodontics." Journal of Ege University School of Dentistry 43, no. 50 (2022): 1–9. http://dx.doi.org/10.5505/eudfd.2022.62134.

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AKDENİZ, Berat Serdar, Volkan AYKAÇ, Merve TURGUT, and Semanur ÇETİN. "Digital dental models in orthodontics: A review." Journal of Experimental and Clinical Medicine 39, no. 1 (January 1, 2022): 250–55. http://dx.doi.org/10.52142/omujecm.39.1.48.

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Digital 3 dimensional (3D) dental models are considered one of the most important advancements in modern dental history. Digital dental models are used in diagnosis, treatment planning, and appliance production phases in orthodontics. The present technology of digital dental models reached, and in some points, exceeded the plaster models' accuracy. The use of digital models with CBCT images and rapid prototyping techniques brought the possibility of new treatment techniques, some of which are considered as the future of modern orthodontics. This article aims to review the current use and success of digital 3D models in orthodontic practice.
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Dissertations / Theses on the topic "Digital orthodontics"

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Porter, Jason L. "Comparison of intraoral and extraoral scanners on the accuracy of digital model articulation." VCU Scholars Compass, 2017. http://scholarscompass.vcu.edu/etd/4881.

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Introduction: Orthodontists increasingly rely on digital models in clinical practice. The ability of modern scanners to articulate digital models must be scientifically evaluated. Methods:Twenty five digital articulated models were produced from four digital scanners in five experimental groups. The resulting inter-arch measurements were compared to the gold standard. An acceptable range of 0.5mm more or less than the gold standard was used for evaluation. Results: iTero® and iTero® Element yielded all acceptable inter-arch measurements. The 3M™ True Definition and Ortho Insight 3D® with Regisil® bite registration produced four of six acceptable inter-arch measurements. The Ortho Insight 3D® with Coprwax ™ bite registration yielded three of six acceptable inter-ach measurements. Conclusions: The iTero® and iTero® Element produced the most accurately articulated models. The 3M™ True Definition and Ortho Insight 3D® with Regisil® were the next most accurate. The Ortho Insight 3D® scanner with Coprwax ™ was the least accurate method tested.
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Durrett, Sharon Jeane. "Efficacy of composite tooth attachments in conjunction with the invisalign tm system using three-dimensional digital technology." [Gainesville, Fla.] : University of Florida, 2004. http://purl.fcla.edu/fcla/etd/UFE0004566.

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Thesis (M.S.)--University of Florida, 2004.
Typescript. Title from title page of source document. Document formatted into pages; contains 35 pages. Includes Vita. Includes bibliographical references.
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Kriel, Earl Ari Mac. "Accuracy of orthodontic digital study models." Thesis, University of the Western Cape, 2012. http://hdl.handle.net/11394/4513.

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Magister Scientiae Dentium - MSc(Dent)
Background: Plaster study models are routinely used in an Orthodontic practice. With the recent introduction of digital models, an alternative is now available, whereby three dimensional images of models can be analyzed on a computer. Aims and objectives: The aim of this study was to compare the measurements taken on digital models created from scanning the impression, digital models created from scanning the plaster model, and measurements done on the plaster models. The objectives were: Measurement differences between those taken directly on plaster models compared with measurements on digital models created from scanned impressions and digital models created from scanned plaster models. Methods: The study sample was selected from the patient records of one Orthodontist. They consisted of 26 pre-treatment records of patients that were coming for orthodontic treatment. Alginate impressions were taken of the maxillary and the mandibular arches. Each impression was scanned using a 3Shape R700™ scanner. Ortho Analyzer software from 3Shape was used to take the measurements on the digital study models. Within 24 hours plaster study models were cast from the impressions, and were scanned using a 3Shape R700™ scanner. On the plaster models the measurements were done with a MAX-CAL electronic digital calliper. The mesiodistal width as well as intermolar and intercanine width for both the maxillary and mandibular models were recorded.Results and discussion: Box plots used to compare the variability in each of the three measurement methods, suggest that measurements are less variable for Plaster. Plaster measurements for tooth widths were significantly higher (mean 7.79) compared to a mean of 7.74 for Digital Plaster and 7.69 for Digital impression. A mixed model analysis showed no significant difference among methods for arch width. Conclusions: Digital models offer a highly accurate alternative to the plaster models with a high degree of accuracy. The differences between the measurements recorded from the plaster and digital models are likely to be clinically acceptable.
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Harris, Angela Manbre Poulter. "Assessment of tooth movement in the maxilla during orthodontic treatment using digital recording of orthodontic study model surface contours." Thesis, University of the Western Cape, 2006. http://etd.uwc.ac.za/index.php?module=etd&action=viewtitle&id=gen8Srv25Nme4_2231_1254312268.

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The aim of this project was to measure changes in dimension of the first three primary rugae and to evaluate tooth movement in the maxilla during orthodontic treatment in patients treated with and without premolar extractions.

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McCaffrey, Kevin. "Cephalometric regional superimpositions -- digital vs. analog accuracy and precision: 2. the mandible." Thesis, NSUWorks, 2014. https://nsuworks.nova.edu/hpd_cdm_stuetd/19.

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Introduction: Lateral cephalometric superimpositions (LCS) are used to measure dental and skeletal changes that occur in the craniofacial complex over time. Orthodontists use LCSs to assess treatment outcomes. The purpose of this study was to conduct an assessment of the measured displacement of defined dental landmarks across digital and analog methods of mandibular regional serial superimposition as compared to an implant-registered superimposition reference. The data used in this study was derived from the Mathew's Acquisition Group implant sample; the first United States longitudinal study of growing children with maxillary and mandibular Björk type metallic implants. Methods: Sixty-six lateral cephalometric radiographs were selected from twenty-two children. Three cephalometric tracings were completed for each subject that were then superimposed pairwise (T1 vs. T2, T2 vs. T3) across four separate methods of superimposition, two analog: Implant, Structural; and two digital: Dolphin, Quick Ceph. Each superimposition was then imported into Adobe Photoshop where the images were scaled and the displacement of defined dental structures was measured. Defined dental structures included: (1) first molar mesial contact point, (2) first molar apical root bisection, (3) central incisor root apex, and (4) central incisor crown incisal edge. A random-effects, generalized linear model was used to contrast dental landmark displacement measurements. Results: There was no difference between the mean displacement of defined dental structures between different methods (p=0.145). There was no difference between the different methods by defined dental structure (p=0.150). Conclusions: Our study demonstrated that there are no statistically significant differences among three methods of mandibular regional superimposition in comparison to an implant-registered (reference) method (analog: Structural, Implant; digital: Dolphin, and Quick Ceph). The historical data set utilized in our study, limited by the small sample size, resulted in a relatively low power (0.15). A low power increases the likelihood of incorrectly failing to reject a null hypothesis that is actually false. which must be considered in our study.
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Zuppardo, Marcelo Lelis. "Efeito da corticotomia e decorticalização na movimentação ortodôntica : estudo em ratos /." Universidade Estadual Paulista (UNESP), 2018. http://hdl.handle.net/11449/154786.

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Este estudo comparou dois protocolos cirúrgicos, corticotomia e corticotomia com decorticalização, em ratos para verificar alteração na movimentação ortodôntica convencional. 60 animais foram divididos aleatoriamente: Grupo controle (GC) - movimentação ortodôntica convencional; Grupo 1 (G1) -movimentação ortodôntica e corticotomia; Grupo 2 (G2) - movimentação ortodôntica com corticotomia e decorticalização. Os animais foram eutanasiados após 7 e 14 dias. No G1 e G2 houve uma maior movimentação ortodôntica comparado aos animais do GC aos 14 dias (p = 0,009 e 0,016) com uma maior área radiográfica interradicular, menor volume ósseo/volume total, menor área final e menor porcentagem de osso. Aos 7 dias os animais do G2 apresentaram menor volume de osso/volume total comparado com GC e aos 14 dias os animais do G2 apresentaram uma menor medida linear da crista óssea comparado com o GC. Os animais do GC aos 14 dias apresentaram uma maior área final comparado aos 7 dias, enquanto o G2 apresentou maior número de células TRAP positivas tanto aos 7 quanto aos 14 dias comparado com o G1. Na análise histológica aos 7 dias houve frequente reabsorção radicular inicial geralmente associada às áreas de hialinização e aos 14 dias, presença do infiltrado inflamatório e com menor ocorrência de áreas hialinas. O padrão de reabsorção radicular iniciado no 7º dia de movimento e consolidado no 14º dia. Concluímos que a corticotomia acelera a movimentação ortodôntica em 14 dias independente da magnitude da injúria cirúrgica
This study compared two surgical protocols, corticotomy and decorticalization corticotomy, in rats to verify alteration in conventional orthodontic movement. 60 animals were randomly divided: Group 1 (G1) orthodontic movement and corticotomy, and Group 2 (G2) orthodontic movement with corticotomy and decorticalization. The animals were euthanized after 7 and 14 days. In G1 and G2, there was a greater orthodontic movement compared to CG animals at 14 days (p = 0.009 and 0.016) with a higher interradicular radiographic area, lower bone volume / total volume, lower final area and lower percentage of bone. At 7 days the G2 animals presented lower bone volume / total volume compared to CG and at 14 days G2 animals presented a smaller linear measure of bone crest compared to CG. GC animals at 14 days presented a larger final area compared to 7 days, while G2 presented a higher number of TRAP cells positive at 7 and 14 days compared to G1. In the histological analysis at 7 days, there was frequent initial root resorption generally associated with hyalinization areas and at 14 days, presence of inflammatory infiltrate and less occurrence of hyaline areas. The root resorption pattern started on day 7 of movement and was consolidated on the 14th day. We conclude that corticotomy accelerates orthodontic movement in 14 days regardless of the magnitude of the surgical injury.
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Dubula, Vuyani Goodman. "Comparison of the accuracy of digital models obtained from scans of impressions versus direct intra-oral scans." University of the Western Cape, 2016. http://hdl.handle.net/11394/5606.

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Magister Chirurgiae Dentium - MChD
Measurements and a variety of analyses of dental casts are essential for precise diagnosis of an orthodontic case. Study models have long been an essential part of orthodontic diagnosis and treatment planning. Currently virtual computerized models are available to clinicians, supplemented by dedicated software for performing needed measurements (Zilberman et al, 2003). Digital impression methods are now available and intraoral digital scanning techniques make it possible to generate study models directly from the scanning of the dentition. The aim of this study was to compare measurements taken after scanning the dental impressions to the measurements obtained from using direct intraoral scanning of the dentition. Alginate impressions of the maxillary and mandibular dentitions were taken on 20 patients and these impressions were scanned using a 3 Shape R 700 TM scanner. Direct intraoral scans of both dentitions were then performed for the same patient. Ortho analyzer TM software was used to measure the mesiodistal widths of individual teeth, and the intercanine and intermolar on digital models of the scanned impressions and digital models obtained from direct intraoral scans of the maxillary and the mandibular dentitions. The results indicated that there were no statistically significant differences between mesiodistal widths, and intercanine and intermolar distances between the two techniques (p > 0.05). Because of the high level of accuracy of the virtual measurements compared to those of the scanned impressions, it can be concluded that direct intraoral scanning of the dentition can be used with confidence in the clinical situation to measure tooth sizes and inter-arch distances for orthodontic purposes. Orthodontists commonly use models for various areas in the practice, clinical research and medico-legal documentation (Marcel, 2001)
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Burzynski, Jennifer Ann. "A Comparison of Digital Intraoral Scanners and Alginate Impressions: Time & Patient Satisfaction." The Ohio State University, 2017. http://rave.ohiolink.edu/etdc/view?acc_num=osu1489694607035837.

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Andrews, Curtis Kyo-shin. "Validity and Reliability of Peer Assessment Rating Index Scores of Digital and Plaster Models." The Ohio State University, 2008. http://rave.ohiolink.edu/etdc/view?acc_num=osu1208136018.

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Madhoo, Amika. "A comparison of three types of orthodontic study models." University of the Western Cape, 2020. http://hdl.handle.net/11394/8126.

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Magister Scientiae Dentium - MSc(Dent)
The aim of this present study was to compare the accuracy of digital and printed study models with plaster study models, that are considered the gold standard. The objectives were to compare the accuracy of measurements obtained from digital and printed study models with those of plaster study models, to establish which type of study model yielded the most accurate measurements in comparison to plaster study models and to identify possible disadvantages and errors that can be made using any of the three types of study models.
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Books on the topic "Digital orthodontics"

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Breuning, K. Hero, and Chung How Kau, eds. Digital Planning and Custom Orthodontic Treatment. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2017. http://dx.doi.org/10.1002/9781119087724.

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Kau, Chung H., and K. Hero Breuning. Digital Planning and Custom Orthodontic Treatment. Wiley & Sons, Incorporated, John, 2017.

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Kau, Chung H., and K. Hero Breuning. Digital Planning and Custom Orthodontic Treatment. Wiley & Sons, Limited, John, 2017.

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Kau, Chung H., and K. Hero Breuning. Digital Planning and Custom Orthodontic Treatment. Wiley & Sons, Incorporated, John, 2017.

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Alpha Dentistry Volume 1 - Digital Orthodontics Assembled Edition. Nguyen, Ba Khoa, 2022.

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Mastering Digital Dental Photography. Quintessence Publishing (IL), 2006.

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Digital radiography and three-dimensional imaging. Ann Arbor, Mich: Department of Orthodontics and Pediatric Dentistry, School of Dentistry; and Center for Human Growth and Development, the University of Michigan, 2006.

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Book chapters on the topic "Digital orthodontics"

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Dalbah, Lana. "Digital Orthodontics." In Digitization in Dentistry, 189–221. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-65169-5_7.

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Caminiti, Marco. "Digital Planning in Orthognathic Surgery." In 3D Diagnosis and Treatment Planning in Orthodontics, 267–82. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-57223-5_11.

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Jasen, Sara. "Applicability of CAD/CAM Technology in Orthodontics." In Digital Economy, Business Analytics, and Big Data Analytics Applications, 69–76. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-031-05258-3_7.

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Foong, Kelvin W. C. "Use of Digital Models/Dental Casts and their Role in Orthodontics/Maxillofacial Surgery." In Three-Dimensional Imaging for Orthodontics and Maxillofacial Surgery, 226–38. West Sussex, UK: John Wiley & Sons, Ltd., 2013. http://dx.doi.org/10.1002/9781118786642.ch14.

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Breuning, K. Hero, and Chung H. Kau. "Orthodontic Treatment Planning." In Digital Planning and Custom Orthodontic Treatment, 31–39. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2017. http://dx.doi.org/10.1002/9781119087724.ch5.

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Breuning, K. Hero. "Custom Retention after Orthodontic Treatment." In Digital Planning and Custom Orthodontic Treatment, 65–68. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2017. http://dx.doi.org/10.1002/9781119087724.ch9.

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Breuning, K. Hero, and Chung H. Kau. "Analysis of Digital Dental Documentation." In Digital Planning and Custom Orthodontic Treatment, 27–30. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2017. http://dx.doi.org/10.1002/9781119087724.ch4.

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Breuning, K. Hero. "Documentation of the Dentition." In Digital Planning and Custom Orthodontic Treatment, 1–7. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2017. http://dx.doi.org/10.1002/9781119087724.ch1.

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Tuncay, Orhan. "The Invisalign System." In Digital Planning and Custom Orthodontic Treatment, 69–79. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2017. http://dx.doi.org/10.1002/9781119087724.ch10.

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Breuning, K. Hero. "Documentation of the Face." In Digital Planning and Custom Orthodontic Treatment, 9–14. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2017. http://dx.doi.org/10.1002/9781119087724.ch2.

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Conference papers on the topic "Digital orthodontics"

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Savignano, Roberto, Sandro Barone, Alessandro Paoli, and Armando V. Razionale. "FEM Analysis of Bone-Ligaments-Tooth Models for Biomechanical Simulation of Individual Orthodontic Devices." In ASME 2014 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/detc2014-34912.

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In the last decades, research in the orthodontic field has focused on the development of more comfortable and aesthetic appliances such as thermoformed aligners. Aligners have been used in orthodontics since the mid 20-century. Nonetheless, there is still not enough knowledge about how they interact with teeth. This paper is focused on the development of a Finite Element Method (FEM) model to be used in the optimization process of geometrical attributes of removable aligners. The presented method integrates Cone Beam Computed Tomography (CBCT) data and optical data in order to obtain a customized model of the dental structures, which include both crown and root shapes. The digital simulation has been focused on analyzing the behavior of three upper frontal teeth. Moreover, the analyses have been carried out by using different aligners’ thicknesses with the support of composite structures polymerized on teeth surfaces while simulating a 2 degrees rotation of an upper central incisor.
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Alcaniz-Raya, Mariano L., Salvador E. Albalat, Vincente Grau Colomer, and Carlos A. Monserrat. "Digital dental surface registration with laser scanner for orthodontics set-up planning." In Medical Imaging 1997, edited by Richard L. Van Metter and Jacob Beutel. SPIE, 1997. http://dx.doi.org/10.1117/12.274022.

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Guo, Jia, Xusen Wang, Hongfang Zhao, and Junjie Wang. "Application of three-dimensional digital modeling of teeth and jaws in orthodontics teaching." In 2021 International Conference on Computer Engineering and Artificial Intelligence (ICCEAI). IEEE, 2021. http://dx.doi.org/10.1109/icceai52939.2021.00051.

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Yagi, Masakazu, Hiroko Ohno, and Kenji Takada. "Decision-making models compatible with digital associative processor for orthodontic treatment planning." In 2009 IEEE Biomedical Circuits and Systems Conference (BioCAS). IEEE, 2009. http://dx.doi.org/10.1109/biocas.2009.5372063.

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Barone, Sandro, Alessandro Paoli, Armando Viviano Razionale, and Roberto Savignano. "Design of Customised Orthodontic Devices by Digital Imaging and CAD/FEM Modelling." In 3rd International Conference on Bioimaging. SCITEPRESS - Science and Technology Publications, 2016. http://dx.doi.org/10.5220/0005821000440052.

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Barone, Sandro, Alessandro Paoli, Armando V. Razionale, and Roberto Savignano. "3D Reconstruction of Individual Tooth Shapes by Integrating Dental CAD Templates and Patient-Specific Anatomy." In ASME 2014 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/detc2014-34362.

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The accurate reconstruction of a human digital dental model represents a wide research area within the orthodontic field due to its importance for the customization of patient treatments. Usually, 3-D dental root geometries are obtained by segmenting tomographic data. However, concerns about radiation doses may be raised since tomographic scans produce a greater X-ray dose than conventional 2-D panoramic radiographs (PAN). The present work is aimed at investigating the possibility to retrieve 3-D shape of individual teeth by exposing the patient to the minimum radiation dose. The proposed methodology is based on adapting general CAD templates over patient-specific dental anatomy, which is reconstructed by integrating the optical digitization of dental plaster models with a PAN image. The radiographic capturing process is simulated through the Discrete Radon Transform (DRT) and performed onto the patient crowns geometry obtained by segmenting the digital plaster model. A synthetic PAN image is then reconstructed and used to integrate the radiographic data within the digitized plaster model, thus allowing to retrieve roots information which guide the CAD templates adapting over the patient anatomy.
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