The effect of immersion in water on deformation with the variety of denture base materials and manufacturing techniques.

Abstract

To evaluate the effect of immersion in water on deformation of maxillary denture bases created by computer-aided design and computer-aided manufactured (CAD-CAM), and heat-polymerized resin fabrication techniques under loading condition. Two-millimeter thick denture bases were fabricated using four techniques: CAD-CAM milling (CCM) (Polywax; Yamahachi), 3D printing (3DP) (BV0005; NextDent), compression molding (CM) (Luciton 199), and injection molding (IM) (Ivobase) (n = 5 per group). Three static 49 N loads were applied perpendicular to each denture base, and the mean strain value (MSV) was recorded by strain gauges attached to the denture surface. The denture bases were stored at 37°C in distilled water for 14 and 28 days, and the MSVs under the same static load were recorded. The highest MSVs were observed at the posterior palatal seal, tuberosity, and labial notches of the dentures. The lowest MSVs were recorded for the CCM group, then the CM and IM. The highest MSVs were recorded for the 3DP group. No significant differences in regional MSVs (P > .05) were observed among the CCM, CM, and IM after 14 and 28 days in water. Large deviations in MSVs were recorded for the 3DP group across the measurement sites after water exposure (P < .05). CCM had the lowest denture deformation under static loading. After immersion in water, the deformation changes under static loading were stable for CCM, CM, and IM. However, variations among the materials used in 3DP group influenced the mechanical performance and presented larger deformations. Int J Prosthodont. 10.11607/ijp.8332.