Dental software classification and dento-facial interdisciplinary planning platform

A Conservative Approach to Ceramic Laminates in the Anterior Region: A Clinical Report

This clinical report presents a conservative approach to restoring aesthetic function in anterior maxillary teeth using digital dental technologies. A 40-year-old female patient sought treatment to enhance the aesthetics of her anterior maxillary teeth. The clinical examination revealed wear on the incisal surfaces and gingival asymmetry. Utilizing a digital workflow, intraoral and extraoral data were acquired through clinical photographs and an intraoral scanner. The patient's restorative needs were assessed using the 3Shape Smile Design system (3Shape, Copenhagen, Denmark). Minimal-thickness ceramic restorations were designed and fabricated using Computer-Aided Design-Computer-Aided Manufacturing (CAD-CAM) technologies. Lithium disilicate was selected for its strong mechanical properties and adhesive capabilities. The restorations were then placed using an adhesive cementation protocol under magnification. Digital technologies facilitated precise diagnosis, planning, and execution of the treatment. The ceramic restorations provided excellent aesthetic outcomes, aligning with the patient's expectations. The minimal thickness of the restorations ensured the preservation of natural tooth structure while maintaining structural integrity and adhesion performance. This case underscores the advantages of a digital workflow in achieving optimal restorative outcomes. The digital dental workflow demonstrated in this case report provides a reliable, efficient, and patient-centric approach to minimal thickness restorations, highlighting the potential for future advancements in restorative dentistry.

Connecting the dots towards precision orthodontics

Precision orthodontics entails the use of personalized clinical, biological, social and environmental knowledge of each patient for deep individualized clinical phenotyping and diagnosis combined with the delivery of care using advanced customized devices, technologies and biologics. From its historical origins as a mechanotherapy and materials driven profession, the most recent advances in orthodontics in the past three decades have been propelled by technological innovations including volumetric and surface 3D imaging and printing, advances in software that facilitate the derivation of diagnostic details, enhanced personalization of treatment plans and fabrication of custom appliances. Still, the use of these diagnostic and therapeutic technologies is largely phenotype driven, focusing mainly on facial/skeletal morphology and tooth positions. Future advances in orthodontics will involve comprehensive understanding of an individual's biology through omics, a field of biology that involves large-scale rapid analyses of DNA, mRNA, proteins and other biological regulators from a cell, tissue or organism. Such understanding will define individual biological attributes that will impact diagnosis, treatment decisions, risk assessment and prognostics of therapy. Equally important are the advances in artificial intelligence (AI) and machine learning, and its applications in orthodontics. AI is already being used to perform validation of approaches for diagnostic purposes such as landmark identification, cephalometric tracings, diagnosis of pathologies and facial phenotyping from radiographs and/or photographs. Other areas for future discoveries and utilization of AI will include clinical decision support, precision orthodontics, payer decisions and risk prediction. The synergies between deep 3D phenotyping and advances in materials, omics and AI will propel the technological and omics era towards achieving the goal of delivering optimized and predictable precision orthodontics.

Comparative Analysis between 3D-Printed Models Designed with Generic and Dental-Specific Software

With the great demand in the market for new dental software, the need has been seen to carry out a precision study for applications in digital dentistry, for which there is no comparative study, and there is a general ignorance regarding their applications. The purpose of this study was to investigate the accuracy differences between digital impressions obtained using generic G-CAD (general CAD) and D-CAD (CAD dental) software. Today, there is a difference between the design software used in dentistry and these in common use. Thus, it is necessary to make a comparison of precision software for specific and generic dental use. We hypothesized that there is no significant difference between the software for specific and general dental use.

METHODS

A typodont was digitized with an intraoral scanner and the models obtained were exported in STL format to four different softwares (Autodesk MeshMixer 3.5, Exocad Dental, Blender for dental, and InLAB). The STL files obtained by each software were materialized using a 3D printer. The printed models were scanned and exported in STL files, with which six pairs of groups were formed. The groups were compared using analysis software (3D Geomagic Control X) by superimposing them in the initial alignment order and using the best fit method.

RESULTS

There were no significant differences between the four analyzed software types; however, group 4, composed of the combination of D-CAD (Blender-InLAB), obtained the highest average (-0.0324 SD = 0.0456), with a higher accuracy compared to the group with the lowest average (group 5, composed of the combination of the Meshmixer and Blender models), a generic software and a specific software (0.1024 SD = 0.0819).

CONCLUSION

Although no evidence of significant difference was found regarding the accuracy of 3D models produced by G-CAD and D-CAD, combinations of groups where specific dental design software was present showed higher accuracy (precision and trueness). The comparison of the 3D graphics obtained with the superimposition of the digital meshes of the printed models performed with the help of the analysis software using the best fit method, replicating the same five reference points for the six groups formed, evidenced a greater tolerance in the groups using D-CAD.

Artificial Intelligence and Augmented Reality for Guided Implant Surgery Planning: a Proof of Concept

PURPOSE

To present a novel protocol for authentic three-dimensional (3D) planning of dental implants, using artificial intelligence (AI) and augmented reality (AR).

METHODS

The novel protocol consists of (1) 3D data acquisition, with an intraoral scanner (IOS) and cone-beam computed tomography (CBCT); (2) application of AI for CBCT segmentation to obtain standard tessellation language (STL) models and automatic alignment with IOS models; (3) loading of selected STL models within the AR system and surgical planning with holograms; (4) surgical guide design with open-source computer-assisted-design (CAD) software; and (5) surgery on the patient.

RESULTS

This novel protocol is effective and time-efficient when used for planning simple cases of static guided implant surgery in the partially edentulous patient. The clinician can plan the implants in an authentic 3D environment, without using any radiological guided surgery software. The precision of implant placement looks clinically acceptable, with minor deviations.

CONCLUSIONS

AI and AR technologies can be successfully used for planning guided implant surgery for authentic 3D planning that may replace conventional guided surgery software. However, further clinical studies are needed to validate this protocol.

STATEMENT OF CLINICAL RELEVANCE

The combined use of AI and AR may change the perspectives of modern guided implant surgery for authentic 3D planning that may replace conventional guided surgery software.

The crown lengthening double guide and the digital Perio analysis

OBJECTIVE

This article describes a surgical crown lengthening double guide, which was digitally obtained to improve diagnosis, treatment outcome, and follow-up.

CLINICAL CONSIDERATIONS

The rehabilitation of anterior dental esthetics should involve interdisciplinary and facially driven planning for achieving pleasant long-term outcomes. Surgical crown lengthening is one of the most common periodontal surgery, which can be assisted by digital tools to improve surgical planning and follow-up.

CONCLUSION

The double guide for surgical crown lengthening allows the proper management of hard and soft tissues for achieving a predefined goal based on biological requirements and facially driven planning. In addition, the digital quality control allows the follow-up compared with the pre-operative condition and planned treatment plan.

CLINICAL SIGNIFICANCE

The use of digital tools allow the clinician to develop a facially driven planning with proper communication with the team and patient, leading to a shorter, more predictable, and less invasive surgical technique, reducing postoperative inflammation and increasing patient comfort.

Interdisciplinary 3D digital treatment simulation before complex esthetic rehabilitation of orthodontic, orthognathic and prosthetic treatment: workflow establishment and primary evaluation

Background

An interdisciplinary treatment simulation and smile design before a complex esthetic rehabilitation is important for clinicians’ decision-making and patient motivation. Meanwhile, intervention and interaction are necessary for dental specialists in these complex rehabilitations. However, it is difficult to visualize an interdisciplinary treatment plan by using the conventional method, especially when orthognathic surgery is involved, thus hindering communication between dental specialists. This research aims to establish a 3D digital workflow of interdisciplinary treatment simulation to solve this problem.

Methods

An interdisciplinary 3D digital workflow of simulated treatment plan for complex esthetic rehabilitation was established. Eleven patients were enrolled and illustrated with their treatment plans using 3D treatment simulation, as well as 2D digital smile design (DSD) plus wax-up. Visual analogue scales (VAS) were used to rate the intuitiveness, understanding, and satisfaction or help between the two methods by patients and dental specialists.

Results

According to the ratings from the patients, 3D treatment simulation showed obvious advantages in the aspects of intuitiveness (9.7 ± 0.5 vs 6.4 ± 1.4) and treatment understanding (9.1 ± 0.8 vs 6.6 ± 1.5), and the satisfaction rates were also higher (9.0 ± 0.6 vs 7.1 ± 1.8). Dental specialists regarded the 3D digital plans as more intuitive (8.9 ± 0.8 vs 5.9 ± 1.0) and useful to understand the plans from the other specialists (8.9 ± 0.7 vs 6.1 ± 1.0) and helpful to their own treatment plans (8.7 ± 0.9 vs 5.9 ± 1.4).

Conclusions

The interdisciplinary 3D digital treatment simulation helps both patients and dental specialists to improve treatment understanding, and facilitates dental specialists for decision-making before complex esthetic rehabilitation.

Trial registration

This study was registered in the National Clinical Trials Registry under the identification number MR-11-20-002862. This is an observational study in which we did not assign the intervention.

Supplementary Information

The online version contains supplementary material available at 10.1186/s12903-022-02070-z.

Multidisciplinary design: Creating a common perspective in complex cases

OBJECTIVE

This clinical report describes and illustrates digital treatment planning and interdisciplinary orthodontic, surgical, and prosthetic treatment in a highly complex clinical case.

CLINICAL CONSIDERATIONS

Analogue design protocols through wax ups are highly variable, technique sensitive, and operator dependent. Digital smile design and treatment planning tools facilitate simplified processes through the use of natural tooth libraries, based on the specific esthetic and functional needs of the individual patient. The vast information compiled in the virtual patient and the treatment plan consolidated in the initial digital design facilitate true interdisciplinary treatment planning and execution, with all dental specialties involved, from orthodontic to surgical and prosthetic treatment.

CONCLUSIONS

Digital protocols and design tools provide clear clinical roadmaps for increased efficiency, precision, and predictability, vastly improving the quality of interdisciplinary patient care.

CLINICAL SIGNIFICANCE

While analogue protocols are technique sensitive and largely dependent on the operator, digital smile design, and treatment planning tools offer opportunities for truly patient-centered individualized care and interdisciplinary treatment.

Three-dimensional (3D) facially driven workflow for anterior ridge defect evaluation: a treatment concept

The esthetic rehabilitation of anterior ridge defects and the achievement of patient satisfaction has become major clinical challenges for dentists and technicians. Poor diagnosis and treatment planning are frequently associated with multiple surgical procedures which fail to meet patient expectations. The loss of hard and soft tissues in esthetic compromised zone is commonly associated with anterior ridges and affects the rehabilitation prognosis. The presence of interdental papilla and papillary configuration play a decisive role in patient satisfaction. A treatment planning considering esthetic parameters, prosthetic needs, and morphological defects must be conducted to improve treatment outcomes. Therefore, this study aims to propose a treatment concept for anterior ridge defects focusing on digital evaluation systems and guided by an ideal facially driven smile design project. In addition, the relevance of the papilla for the esthetic outcomes and the treatment alternatives for anterior ridge defects are also addressed.