Mechanical behavior of Class I cavities restored by different material combinations under loading and polymerization shrinkage stress. A 3D-FEA study

Pietro Pedroso Ausiello; Stefano Ciaramella; Antonio Lanzotti; Maurizio Ventre; Alexandre Ls Borges; Joao P Tribst; Amanda Dal Piva; Franklin Garcia-Godoy

Mechanical behavior of Class I cavities restored by different material combinations under loading and polymerization shrinkage stress. A 3D-FEA study

Am J Dent. 2019 Apr;32(2):55-60.

Authors

Pietro Pedroso Ausiello¹, Stefano Ciaramella², Antonio Lanzotti², Maurizio Ventre³, Alexandre Ls Borges⁴, Joao P Tribst⁴, Amanda Dal Piva⁴, Franklin Garcia-Godoy^{5

6}

Affiliations

¹ Department of Neurosciences, Reproductive and Odontostomatological Sciences, University of Naples Federico II, Naples, Italy, pietro.ausiello@unina.it.
² Fraunhofer Laboratory IDEAS, Department of Industrial Engineering, University of Naples Federico II, Naples, Italy.
³ Department of Chemical, Materials and Industrial Production Engineering, University of Naples Federico II & Center for Advanced Biomaterials for HealthCare@CRIB, Italian Institute of Technology, Naples, Italy.
⁴ Institute of Science and Technology, Department of Dental Materials and Prosthodontics, Paulista State University (UNESP), São Joséé dos Campos, São Paulo, Brazil.
⁵ Bioscience Research Center College of Dentistry, College of Dentistry, University of Tennessee Health Science Center, Memphis, Tennessee, USA.
⁶ The Forsyth Institute, Cambridge, Massachusetts, USA.

PMID: 31094138

Abstract

Purpose: To examine the influence of different bulk and block composite and flowable and glass-ionomer material combinations in a multi-layer technique and in a unique technique, in deep Class I dental restorations.

Methods: 3D CAD of the sound tooth were built-up from a CT scan dataset using reverse engineering techniques. Four restored tooth models with Class I cavity were virtually created from a CAD model of a sound tooth. 3D-finite element (FE) models were created and analyzed starting from CAD models. Model A with flowable resin composite restoring the lower layer and bulk-fill resin composite restoring the upper layer, model B with glass-ionomer cement (GIC) restoring the lower layer and bulk-fill resin composite restoring the upper layer, model C with block composite as the only restoring material and model D with bulk-fill resin composite as the only restoring material. Polymerization shrinkage was simulated with the thermal expansion approach. Physiologic masticatory loads were applied in combination with shrinkage effect. Nodal displacements on the lower surfaces of FE models were constrained in all directions. Static linear analyses were carried out. The maximum normal stress criterion was used to assess the influence of each factor.

Results: Considering direct restoring techniques, models A, B and D exhibited a high stress gradient at the tooth/restorative material interface. Models A and D showed a similar stress trend along the cavity wall where a similar stress trend was recorded in the dentin and enamel. Model B showed a similar stress trend along enamel/restoration interface but a very low stress gradient along the dentin/restoration interface. Model C with a restoring block composite material showed a better response, with the lowest stress gradient at the dentin, filling block composite and enamel sides.

Clinical significance: Bulk resin-based composite materials applied in a multilayer technique to deep and large Class I cavities produced adverse stress distributions versus block resin composite. Polymerization shrinkage and loading determined high stress levels in deep Class I cavities with bulk multi-layer restorations, while its impact on adhesion in block composite restorations was insignificant.

MeSH terms

Composite Resins*
Dental Cavity Preparation
Dental Restoration, Permanent*
Dental Stress Analysis
Finite Element Analysis
Materials Testing
Polymerization
Stress, Mechanical

Substances

Composite Resins