editorial digital dentistry: new materials and...

EditorialDigital Dentistry: New Materials and Techniques

Francesco Mangano,1,2 Jamil A. Shibli,3 and Thomas Fortin4

1Department of Surgical and Morphological Science, Dental School, University of Varese, Varese, Italy2Academic Unit of Digital Dentistry, IRCCS San Raffaele Hospital, Milan, Italy3Guarulhos University, Guarulhos, SP, Brazil4University of Lyon, Lyon, France

Correspondence should be addressed to Francesco Mangano; [email protected]

Received 27 September 2016; Accepted 28 September 2016

Copyright © 2016 Francesco Mangano et al. This is an open access article distributed under the Creative Commons AttributionLicense, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properlycited.

The digital revolution is changing the world, and dentistry isno exception.

The introduction of a whole range of digital devices(intraoral, extraoral, face scanners and cone beam computedtomography (CBCT) with low dose radiation) and process-ing software (computer-assisted-design/computer-assisted-manufacturing (CAD/CAM) prosthetic software, softwarefor planning implant surgery), together with new aestheticmaterials and powerful manufacturing and prototyping tools(millingmachines and 3D printers), is radically transformingthe dental profession.

Classically, case history and physical examination,together with X-ray data from two-dimensional radiology(periapical, panoramic, and cephalometric radiographs),represented the necessary preparatory stages for formulatinga treatment plan and for carrying out the therapy. Withonly two-dimensional X-ray data available, making a correctdiagnosis and an appropriate treatment plan could bedifficult; therapies essentially depended on the manual skillsand experience of the operator.

Today, the digital revolution is changing the workflowand consequently changing operating procedures. Inmoderndigital dentistry, the four basic phases of work are imageacquisition, data preparation/processing, the production, andthe clinical application on patients.

Image acquisition is the first operational phase of digitaldentistry and this employs powerful tools such as digitalcameras, intraoral scanners, and CBCT.

Digital photography, combined with the use of appro-priate software for image processing, allows us to design a

patient’s smile virtually: this is digital smile design, a valuabletool for previsualization and communication in modernaesthetic and cosmetic dentistry.

Intraoral scanners allow us to take accurate opticalimpression of the dental arches, using only a beam of light.The optical impression is now supplanting the classic methodwith tray and impression materials: this last procedure, neverliked by patients and often technically difficult, is likely to dis-appear over the next few years.The information on dentogin-gival tissues acquired from an optical impression can be usednot only tomake a diagnosis and for communication, but alsoto design prosthetic restorations. Indeed, optical impressiondata (e.g., the scanning of prosthetic preparations) is easilyimported into processing software for designing/planningprosthetic restorations; the models created in this way arethen physically produced with materials of high aestheticvalue, with powerful milling machines. These restorationsare then delivered to patients. In simple cases (e.g., in thecase of inlays/onlays, temporary restorations in resin or singlecrowns), all these procedures can be performed directly inthe dental office, without the help of a dental technician,through a “full in-office” or “chairside” procedure. In thecase of more complex restorations (such as crowns andmonolithic bridges or copings and frameworks which needto be veneered with ceramic), collaboration with a dentaltechnician is fundamental. Optical impressions can findapplication in orthodontics and surgery, too. In orthodontics,they are useful in diagnosis and in the design of a wholeseries of custom devices, such as invisible aligners. In surgery,optical impressions allow useful data to be obtained for

Hindawi Publishing CorporationInternational Journal of DentistryVolume 2016, Article ID 5261247, 2 pageshttp://dx.doi.org/10.1155/2016/5261247

2 International Journal of Dentistry

the planning of implant operations. Indeed, information ondentogingival tissues can be combined and overlaid withthat relating to the patient’s bone structure obtained fromCBCT, by using specific planning software packages. Withinthese processing software packages, the surgeon can designtemplates for guided implant placement, which are physicallymanufactured by milling or 3D printing and used clinically.Implants positioned through a guided surgical procedure canbe loaded immediately, using prosthetic restorations in resin,printed in 3Dbefore the fixtures are positioned.This is knownas the “full-digital” technique.

The data obtained by CBCT can also be used for design-ing personalized implants (“custom-made”), or personalizedbone grafts, to be used in implant and regenerative surgery,respectively. In fact, by importing data from CBCT intospecific modelling software, it is currently possible for thesurgeon to design a whole series of customized implants(root analogue implants, blade implants, and maxillofacialimplants); such implants can be physically produced bymeans of additive manufacturing and 3D printing proce-dures, such as direct metal laser forming (printing of metals).The use of customized implants offers the patient severaladvantages. With 3D printing techniques (the real “thirdindustrial revolution”) becoming established in the biomed-ical field, the cost of equipment will fall and the printers willalso increasingly become accessible to dental professionals:hence, it is likely that such modelling procedures and thefabrication of “customized” implants will spread.The produc-tion of personalized bone grafts for regenerative surgery alsocomes under this heading. The possibility of using custom-made bone grafts, offering macro- and microtopographywith controlled characteristics, represents an undoubtedadvantage for the practitioner and for the patient. In fact,the availability of customized grafts which fit the individualpatient’s bone defect perfectly will greatly simplify and speedup otherwise complex regenerative operations; reducing thesurgical time will allow the risk of infection to be lowered andimprove healing. Thus, the outcome of regenerative therapywill also be improved with significant benefit for the patient.

In this special issue, the first in the world dedicatedentirely to the topic of digital dentistry, you will find thatwe have gathered together a number of scientific and clinicalpapers which deal with various “digital” themes: we hope thatyou will find them interesting and that they will attract yourattention.

Francesco ManganoJamil A. ShibliThomas Fortin

Submit your manuscripts athttp://www.hindawi.com

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