https://www.selleckchem.com/products/mrtx0902.html Printed denture bases of 100-μm layer thickness showed good adaptation to tissues and accuracy, and it can be recommended that the prosthesis be cleaned in ethanol followed by postcuring for better biocompatibility. Nanoand microparticles can be added to provide antimicrobial activity and better resistance. Printing angle and mechanical properties must be better evaluated. Printed denture bases of 100-μm layer thickness showed good adaptation to tissues and accuracy, and it can be recommended that the prosthesis be cleaned in ethanol followed by postcuring for better biocompatibility. Nanoand microparticles can be added to provide antimicrobial activity and better resistance. Printing angle and mechanical properties must be better evaluated. To investigate the fracture load of different veneers for monolithic single-unit fixed dental prostheses (FDPs) made of a novel potential framework material, polyphenylene sulfone (PPSU). The fracture loads of four PPSU frameworks with different veneers (manual polymer veneer with Ceramage Body A3B; prefabricated polymer veneer with Novo.lign; digital polymer veneer with Telio CAD; digital ceramic veneer with IPS Empress CAD) and a monolithic control group (PPSU, Gehr) were examined initially and after 1,200,000 masticatory (50 N, 1.3 Hz) and 6,000 thermal cycles (5°C/55°C). Fracture analysis was performed using light microscope imaging. Fracture types were classified, and relative frequencies were determined. Univariate analysis of variance, post hoc Scheffé, partial eta squared, Kruskal-Wallis test, and Weibull moduli using the maximum likelihood estimation method were calculated. The defined level of significance was adjusted by Bonferroni correction (P < .005). Aging did not affect the fracture load values. Single-unit FDPs with a digital ceramic veneer showed lower values than monolithic and manual polymer-veneer specimens. Single-unit FDPs with a prefabricated and digital