The Impact of Thermocycling on the Physico-mechanical Properties of SLA and DLP 3D-Printed Dental Ceramics: A Comparative Study

The Impact of Thermocycling on the Physico-mechanical Properties of SLA and DLP 3D-Printed Dental Ceramics: A Comparative Study

Objective: Three-dimensional (3D) printing technology is highly promising for producing nanoceramic resin dental restorations. However, the effects of environmental stressors on the structural integrity and clinical performance of these restorations require further elucidation. To investigate the e...

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Bibliographic Details
Main Author: Nadia H Hasan
Format: Article
Language:English
Published: University Library System, University of Pittsburgh 2025-04-01
Series:Dentistry 3000
Subjects:
3D printing
dental materials
digital light processing
flexural strength
microhardness
stereolithography
Online Access:http://dentistry3000.pitt.edu/ojs/dentistry3000/article/view/866
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Summary:Objective: Three-dimensional (3D) printing technology is highly promising for producing nanoceramic resin dental restorations. However, the effects of environmental stressors on the structural integrity and clinical performance of these restorations require further elucidation. To investigate the effects of Stereolithography (SLA) and digital light processing (DLP) 3D printing technologies on the physical-mechanical properties of a 3D-printed resin material used in dental applications. Methods: A total of 120 resin specimens (Senertek P-Crown V2) were fabricated using SLA and DLP technologies. The microhardness, flexural strength, and surface roughness of the specimens were evaluated under control and thermocycling conditions to evaluate their long-term performance. To assess statistical significance a two independent sample t-tests (P < 0.05) were used to analysis the data. Results: SLA samples exhibited significantly higher microhardness (P = 0.001) and flexural strength than DLP samples, both in the control state and after thermocycling. After thermocycling, the microhardness of SLA samples increased, whereas that of DLP samples decreased. Surface roughness values increased significantly in both SLA and DLP samples after thermocycling, with SLA samples exhibiting higher roughness values. Conclusion: SLA-printed resin demonstrated superior microhardness and flexural strength compared to DLP-printed resin. However, its long-term durability is affected by immersion and thermocycling. This study highlights the impact of water sorption, polymerization mechanisms, and surface morphology on material performance.
ISSN:2167-8677

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