Cham, Switzerland : , : Springer, , [2022]

©2022

3-031-07369-X

1 online resource (325 pages)

617.69

Dental implants

Implants dentals

Impressió 3D

Llibres electrònics

Inglese

Includes bibliographical references.

Intro -- Preface -- Contents -- Editors and Contributors -- About the Editors -- Contributors -- 1: An Introduction to Three-Dimensional (3D) Printing in Oral Health Science -- 1.1  What Is 3D Printing (3DP)? -- 1.2  How Does 3D Printing Process Work? -- 1.2.1  3D Digital Model Acquisition -- 1.2.2  3D Digital Image Processing -- 1.2.3  The 3D Printing -- 1.2.4  Post-processing -- 1.3  Brief History of 3D Printing Development -- 1.4  Contemporary Applications and Limitations of 3D Printing in Oral Health Science -- 1.5  Summary -- References -- 2: Principles and Applications of Various 3D Scanning Methods for Image Acquisition for 3D Printing Applications in Oral Health Science -- 2.1  Noninvasive, Nonionizing Surface Imaging -- 2.1.1  Intraoral Scanning -- 2.1.1.1  An Introduction to Intraoral Scanners Including Its Advantages and Disadvantages -- Advantages and Disadvantages -- 2.1.1.2  Various Intraoral (IOS) Scanning Technologies and Principles -- Tabletop vs. Intraoral Scanners (Fig. 2.1) -- 2.1.1.3  Accuracy of Intraoral Scanning Technology -- In Vitro Trueness (Fig. 2.5a) -- In Vivo Trueness (Fig. 2.5b) -- Precision -- Effect of Software Versions on Intraoral Scanner Accuracy -- 2.1.1.4  The Various Commercially Available Intraoral Scanners -- 2.1.1.5  Application of Intraoral

Scanning in Various Fields of Dentistry Including 3D Printing -- Digital Orthodontics -- 3D Printed Dentures (Fig. 2.11) -- Dental Implants (Fig. 2.12) -- 2.1.2  Desktop Scanning -- 2.1.2.1  An Introduction of Desktop Scanning Including Advantages and Disadvantages -- 2.1.2.2  Technical Characteristics of Some Commercially Available Desktop Scanners -- 2.1.2.3  Application of Desktop Scanning in Various Field of Dentistry Including 3D Printing -- 2.1.3  Facial Scanning -- 2.1.3.1  An Introduction to Facial Scanning Including Advantages and Disadvantages.

2.1.3.2  Various Facial Scanning Technologies -- 2.1.3.3  Accuracy of Facial Scanning Technology -- 2.1.3.4  Technical Characteristics of Some Commercially Available Facial Scanning Devices -- 2.1.3.5  Application of Facial Scanning in Various Fields of Dentistry -- 2.2  Ionizing Surface Imaging -- 2.2.1  Cone Beam Computed Tomography Imaging -- 2.2.1.1  Basic Principle of CBCT Imaging -- 2.2.1.2  3D Printing with CBCT Imaging -- 2.2.1.3  Advantages of CBCT Over CT -- 2.2.1.4  Limitations of CBCT -- 2.2.1.5  Application of CBCT Data for 3D Printing in Various Field of Dentistry -- References -- 3: Commonly Used 3D Printing Technologies in Oral Health Science -- 3.1  Introduction -- 3.2  Brief History -- 3.3  Basic Terminologies -- 3.3.1  2D Printing -- 3.3.2  3D Printing -- 3.3.3  Additive Manufacturing -- 3.3.4  Subtractive Manufacturing (Computer-Aided Manufacturing or Milling) -- 3.3.5  Intraoral Scanning -- 3.3.6  Desktop Scanning -- 3.3.7  STL File (Stereolithographic File or Standard Tessellation Language File) -- 3.3.8  Stereolithography (SLA) -- 3.3.9  Stereophotogrammetry -- 3.3.10  Computer-Aided Design (CAD) -- 3.3.11  Resolution -- 3.3.11.1  Horizontal Resolution -- 3.3.11.2  Vertical Resolution -- 3.3.12  Accuracy -- 3.4  Various 3D Printing Technologies for Oral Health Applications: Principles and Applications -- 3.4.1  Stereolithography (SLA) -- 3.4.2  Digital Light Processing (DLP) -- 3.4.3  Fused Deposition Modeling (FDM) -- 3.4.4  Inkjet 3D Printing/PolyJet Photopolymerization (PPP) -- 3.4.5  Selective Laser Melting (SLM) and Selective Laser Sintering (SLS) -- 3.4.6  Electron-Beam Melting (EBM) -- 3.4.7  Laminated Object Manufacturing (LOM) -- 3.5  Commonly Used 3D Printers in Different Branches of Oral Health Science -- 3.5.1  Oral and Maxillofacial Surgery -- 3.5.2  Orthodontics -- 3.5.3  Implantology and Prosthodontics.

3.5.4  Restorative Dentistry -- 3.5.5  Endodontics -- 3.5.6  Periodontics -- 3.6  Summary and Key Points -- References -- 4: An Overview of 3D Printable Materials for Dental and Craniofacial Applications -- 4.1  Introduction to 3D Printed Materials -- 4.2  Classification of 3D Printing Materials -- 4.2.1  Liquid-Based Materials -- 4.2.2  Powder-Based Materials -- 4.2.3  Solid-Based Materials -- 4.2.4  AM Technologies and Materials Matrix -- 4.3  Digital Dentistry with 3D Printed Materials: A Broad Perspective -- 4.3.1  Prominent Use Cases for Dental Applications in Additive Manufacturing -- 4.3.1.1  Oral Maxillofacial Surgery -- 4.3.1.2  Prosthodontics -- 4.3.1.3  Orthodontics -- 4.3.1.4  Endodontics -- 4.3.1.5  Periodontics -- 4.3.2  Factors for Adopting 3D Printed Materials in Digital Dentistry -- 4.4  Liquid-Based Materials -- 4.4.1  Introduction to Liquid Material-Based 3D Printing Technologies -- 4.4.1.1  Stereolithography (SLA) -- 4.4.1.2  Material Jetting (MJ) -- 4.4.1.3  Digital Light Processing (DLP) -- 4.4.2  Dental Applications of Liquid-Based Materials -- 4.4.2.1  Clear Aligners -- 4.4.2.2  Splints and Occlusal Guards -- 4.4.2.3  Digital Dentures -- 4.4.2.4  Crown and Bridges -- 4.4.2.5  Castable Wax -- 4.4.2.6  Impression Trays -- 4.4.2.7  Surgical Guides -- 4.4.2.8  Indirect Bonding Trays -- 4.4.2.9  Gingiva Masks -- 4.5  Powder-Based Materials -- 4.5.1  Introduction to Powder Material-Based 3D Printing

Technologies -- 4.5.1.1  Selective Laser Sintering (SLS) -- 4.5.1.2  Multi Jet Fusion (MJF) -- 4.5.1.3  Direct Metal Laser Sintering (DMLS) and Selective Laser Melting (SLM) -- 4.5.2  Dental Applications of Powder-Based Materials -- 4.5.2.1  Crowns and Bridges -- 4.5.2.2  Oral Maxillofacial Implants -- 4.5.2.3  Dental and Aligner Models -- 4.6  Solid-Based Materials -- 4.6.1  Introduction to Solid Material-Based 3D Printing Technologies.

4.6.1.1  Fused Deposition Modeling (FDM) -- 4.6.2  Dental Applications of Solid Materials -- 4.6.2.1  Dental and Anatomical Models -- 4.7  Advancements in Materials for Oral Healthcare -- 4.7.1  Biomaterials with AM for Dental Applications -- 4.7.2  3D Printed Ceramics for Dental Applications -- 4.7.3  Other Novel Materials: PEEK, Nitinol -- 4.8  Summary -- References -- 5: Fundamentals of Computer-Aided Design (CAD) in Dental Healthcare: From Basics to Beyond -- 5.1  Introduction -- 5.1.1  A Brief History of Computer-Aided Designing and Computer-Aided Manufacturing (CAD/CAM) -- 5.2  CAD/CAM Workflow in Dentistry -- 5.2.1  Open vs. Closed Systems -- 5.2.2  3D File Formats -- 5.2.3  Chairside vs. Laboratory CAD/ CAM -- 5.3  3D Surface Data Acquisition for Computer-Aided Designing -- 5.3.1  Laboratory Desktop Scanners -- 5.3.2  Chairside Intraoral Scanners -- 5.3.3  Scanning of Edentulous Jaws -- 5.4  Computer-Aided Designing (CAD) for Dental Applications -- 5.4.1  Exocad -- 5.4.2  3Shape -- 5.4.3  CEREC Software and inLab CAD Software -- 5.4.4  Implant Planning Software -- 5.4.5  Virtual Articulator -- 5.4.6  Jaw Motion Tracking -- 5.4.7  Digital Smile Design -- 5.4.8  Digital Orthodontics -- 5.4.9  Digital Denture Design -- 5.5  Computer-Aided Manufacturing for Dental Applications -- 5.5.1  Chairside vs. Laboratory CAM -- 5.5.2  Dry and Wet Milling -- 5.5.3  Material Processing -- 5.6  Summary -- References -- 6: 3D Printing and Its Applications in Maxillofacial Surgery -- 6.1  Introduction -- 6.2  Virtual Surgical Planning (VSP) -- 6.3  3 Dimensional Printing (3D Printing) -- 6.4  Types of 3D-Printed Models -- 6.4.1  Training Models -- 6.4.2  Planning Models -- 6.4.3  Simulation Models -- 6.4.4  Patient-Specific Surgical Guides -- 6.5  Patient-Specific Implants (Custom Implants) -- 6.6  Limitations and Areas of Research.

6.7  Future Perspectives and Summary -- References -- 7: Applications of 3D Printing in Periodontal Tissue Regeneration -- 7.1  Introduction -- 7.2  Methodology -- 7.2.1  Protocol -- 7.2.2  Literature Search Strategy -- 7.2.3  Selection Criteria for Inclusion/Exclusion of Studies -- 7.2.4  Data Extraction -- 7.2.5  Quality Assessment of Animal Studies -- 7.2.6  Outcomes Evaluation -- 7.3  Results -- 7.3.1  Animal Studies -- 7.3.1.1  Study Selection -- 7.3.1.2  Study Characteristics -- 7.3.1.3  Risk of Bias -- 7.3.2  Human Studies -- 7.4  Discussion -- 7.4.1  Overview of Reported Studies -- 7.4.2  Scaffold Materials and Design -- 7.4.3  Biomolecules -- 7.4.4  Printing Technologies -- 7.4.5  Periodontal Tissue Regeneration -- 7.4.6  Merits and Demerits -- 7.4.7  Summary and Future Prospects -- References -- 8: Contemporary Applications of 3D Printing in Prosthodontics -- 8.1  3D Printing Applications in Prosthodontics -- 8.2  3D Printing for Complete Denture Fabrication -- 8.2.1  Procedural Details of 3D Printing in Removable Complete Dental Prosthodontics -- 8.2.1.1  Clinical Visit I: Impression Making (Two-Staged or Single-Staged) and Bite Registration -- Laboratory Procedure I -- Step 1: Preparation of Virtual Study Models -- Step 2: Designing of Denture -- Step 3: Nesting and Incorporation of Supports -- Step 4: Printing -- Step 5: Post-processing -- Step 6: Assembly -- Step 9: Post-cure -- 8.2.1.2  Clinical Visit II -- Laboratory Procedure II -- 8.2.1.3  Clinical Visit III -- Take-Home Points Regarding 3D Printed Removable Complete Denture

-- 8.3  Fixed Prosthodontics -- 8.3.1  3D Printed Casts and Dies -- 8.3.2  Metal Frameworks of Tooth-Supported and Implant-Borne FDPs -- 8.3.2.1  Direct Metal Laser Sintering (DMLS) -- 8.3.2.2  Electron Beam Melting -- 8.3.3  Prosthesis Fabricated in Ceramics and Zirconia.

8.3.4  Provisional Crowns/Bridges Fabrication by 3D Printing.