Adhesive class I restorations in sound molar teeth incorporating combined resin-composite and glass ionomer materials: CAD-FE modeling and analysis

Pietro Ausiello; Stefano Ciaramella; Alessandra Di Rienzo; Antonio Lanzotti; Maurizio Ventre; David C Watts

doi:10.1016/j.dental.2019.07.017

Adhesive class I restorations in sound molar teeth incorporating combined resin-composite and glass ionomer materials: CAD-FE modeling and analysis

Dent Mater. 2019 Oct;35(10):1514-1522. doi: 10.1016/j.dental.2019.07.017. Epub 2019 Aug 5.

Authors

Pietro Ausiello¹, Stefano Ciaramella², Alessandra Di Rienzo³, Antonio Lanzotti², Maurizio Ventre⁴, David C Watts⁵

Affiliations

¹ Department of Neurosciences, Reproductive and Odontostomatological Sciences, University of Naples Federico II, Italy. Electronic address: pietro.ausiello@unina.it.
² Department of Industrial Engineering, Fraunhofer JL IDEAS - University of Naples Federico II, Italy.
³ Department of Neurosciences, Reproductive and Odontostomatological Sciences, University of Naples Federico II, Italy.
⁴ Department of Chemical, Materials and Industrial Production Engineering, University of Naples Federico II & Center for Advanced Biomaterials for HealthCare@CRIB, Istituto Italiano di Tecnologia, Naples, Italy.
⁵ School of Medical Sciences and Photon Science Institute, University of Manchester, United Kingdom.

PMID: 31395448
DOI: 10.1016/j.dental.2019.07.017

Abstract

Objectives: To investigate the influence of different resin composite and glass ionomer cement material combinations in a "bi-layer" versus a "single-layer" adhesive technique for class I cavity restorations in molars using numerical finite element analysis (FEA).

Materials and methods: Three virtual restored lower molar models with class I cavities 4mm deep were created from a sound molar CAD model. A combination of an adhesive and flowable composite with bulk fill composite (model A), of a glass ionomer cement with bulk fill composite (model B) and of an adhesive with bulk fill composite (model C), were considered. Starting from CAD models, 3D-finite element (FE) models were created and analyzed. Solid food was modeled on the occlusal surface and slide-type contact elements were used between tooth surface and food. Polymerization shrinkage was simulated for the composite materials. Physiological masticatory loads were applied to these systems combined with shrinkage. Static linear analyses were carried out. The maximum normal stress criterion was adopted as a measure of potential damage.

Results: All models exhibited high stresses principally located along the tooth tissues-restoration interfaces. All models showed a similar stress trend along enamel-restoration interface, where stresses up to 22MPa and 19MPa was recorded in the enamel and restoration, respectively. A and C models showed a similar stress trend along the dentin-restoration interface with a lower stress level in model A, where stresses up to 11.5MPa and 7.5MPa were recorded in the dentin and restoration, respectively, whereas stresses of 17MPa and 9MPa were detected for model C. In contrast to A and C models, the model B showed a reduced stress level in dentin, in the lower restoration layer and no stress on the cavity floor.

Significance: FE analysis supported the positive effect of a "bi-layer" restorative technique in a 4mm deep class I cavities in lower molars versus "single-layer" bulk fill composite technique.

Keywords: 3D-finite element analysis; GIC; Resin composites; Shrinkage; Stress.

MeSH terms

Acrylic Resins
Composite Resins
Dental Cements*
Dental Restoration, Permanent*
Dental Stress Analysis
Glass Ionomer Cements
Materials Testing
Molar
Silicon Dioxide
Stress, Mechanical

Substances

Acrylic Resins
Composite Resins
Dental Cements
Glass Ionomer Cements
glass ionomer
Silicon Dioxide