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Volume 6, Issue 9 (Suppl)

Dentistry 2016

ISSN: 2161-1122 Dentistry, an open access journal

Euro Dental Congress 2016

October 24-26, 2016

October 24-26, 2016 Rome, Italy

15

th

Euro Congress on

Dental & Oral Health

Dentistry 2016, 6:9 (Suppl)

http://dx.doi.org/10.4172/2161-1122.C1.006

The next big thing in clear aligner therapy: Enhancement of the digital workflow

Sherif Kandil

K Line Europe, Germany

Introduction:

Clear aligner therapy has been developing recently thanks to the advancements in CAD/CAM software. The standard

method of clear aligners' manufacturing comprises undertaking tooth movements on dental digital models with specialized software,

then 3D printing of physical prototypes and finally fabricating the aligners through vacuum (thermoforming) technique. This

method has its limitations being lengthy, costly, requiring human intervention in addition to some material waste. We introduce a

new methodology of fabricating aligners in a completely digital platform and in a fast, inexpensive manner with minimal human

intervention and least material consumption.

Objectives:

The objectives of the present study are: To exploit the advancing CAD/CAM technology in digital dentistry via producing

3D-printed clear aligners; to produce the largest number of clear aligners in short duration; to introduce a cost-effective method of

fabrication of clear aligners with minimal material waste and to eliminate human intervention in clear aligners' manufacturing.

Materials & Methods:

Digital models were prepared with data processing and subsequent teeth segmentation on orthodontic

software (Ortho Analyzer by 3shape). Tooth movement was carried out and subdivided onto sub-setups. Each sub-setup was installed

in another facility of the software (Splint Designer). A splint was designed for each digital sub-setup with thickness less than 1 mm

similar to clear aligners. At the end of designing, the splint's margins were smoothened using finishing tools in the software. Each

splint (aligner) was 3D printed with a variety of material, each with different transparency, strength, flexibility and biocompatibility

properties (basically, in soft and rigid forms). The produced aligners were made in different colors to allow for inspection of finishing

of their margins.

Results:

Different aligners with different colors could be produced using this method. Each aligner had different strength, clarity

& flexibility and biocompatibility properties. Rigid aligners had good strength but low elasticity; soft ones had better adaptation,

resistance to fracture but less strength. Aligners' margins were finely smoothened without any intervention of lab personnel. The

aligners were not clinically tested.

Conclusion:

Using CAD/CAM technology, clear aligners could be produced in a completely digital fashion with computer-assisted

designing and 3D printing. The 3D-printed aligners were produced in relatively short duration compared to the vacuum method;

however, designing a splint for each movement sub-setup is still time consuming. The given methodology was very cost-effective

compared to the standard thermoforming method (cost of models and sheets was eliminated) with much less material waste. Human

intervention was eliminated as the designing and finishing were done digitally.

s.kandil@kline-europe.de

Indirect adhesive CAD/CAM composite restorations on vital and devital teeth

Ivo Krejci

University of Geneva, Switzerland

I

ndirect adhesive CAD/CAM composite restorations are becoming a real alternative to PFM and full ceramic crowns on both vital

and devital teeth. The presentation will focus on the latest clinical and

in vitro

research with this type of restorations and will present

clinical concepts and procedures as well.

ivo.krejci@bluewin.ch