Pompa, Giorgio, Di Carlo, Stefano, De Angelis, Francesca, Cristalli, Maria Paola, and Annibali, Susanna
BioMed Research International. Annual, 2015
Laser, Rapid prototyping -- Comparative analysis, Lasers -- Usage, and Prosthodontics -- Production processes
1. Introduction Fixed dental prostheses (FDPs) are the rehabilitation of choice after endodontic and operative treatments, especially among all over the world . Moreover, the introduction of implant restorations has [...] This study assessed whether there are differences in marginal fit between laser-fusion and conventional techniques to produce fixed dental prostheses (FDPs). A master steel die with 2 abutments was produced to receive a posterior 4-unit FDPs and single copings. These experimental models were divided into three groups (n = 20/group) manufactured: group 1, Ni-Cr alloy, with a lost-wax casting technique; group 2, Co-Cr alloy, with selective laser melting (SLM); and group 3, yttria-tetragonal zirconia polycrystal (Y-TZP), with a milling system. All specimens were cut along the longitudinal axis and their adaptation was measured at the marginal and shoulder areas on the right and left sides of each abutment. Measurements were made using a stereomicroscope (x60 magnification) and a scanning electron microscope (x800 magnification). The data were analyzed using one-way analysis of variance and the Bonferroni post hoc test, with a significance cutoff of 5%. Significant differences (P < 0.05) were observed between group 3 and the other groups. The marginal opening was smallest with Co-Cr alloy substructures, while the shoulder opening was smallest with Ni-Cr alloy substructures. Within the limitations of this study, the marginal fit of an FDP is better with rapid prototyping (RP) via SLM than conventional manufacturing systems.
Laser Focus World. May 2005, Vol. 41 Issue 5, p129, 5 p.
Laser and Lasers
Since it's introduction in the 1980s, rapid prototyping has evolved from a relatively simple modeling technique that allows design engineers to "test" their ideas in three dimensions to a sophisticated [...]
The RapidX250 laser micromachining system can be used in rapid prototyping applications to fabricate microfluidic devices, microelectromechanical systems (MEMS), and medical devices with tolerances approaching 1 urn. Offered by Resonetics [...]
Laser Focus World. Jan 2007, Vol. 43 Issue 1, p15, 1 p.
Laser, Fiber optics -- Equipment and supplies, and Lasers
Rapid prototyping (also called generative manufacturing) is evolving from polymer-based prototyping to metal-based prototyping, thanks to the development of titanium, stainless, aluminum, and cobalt-chrome powders that can be melted or [...]