1

Introduction

Resin-composites are now the preferred choice for direct posterior restorations, due to an increased demand of aesthetically acceptable restorations, and their improved mechanical strength and wear resistance . In class I and II posterior cavities, it is important to obtain tight proximal contacts before curing and good post-cure mechanical properties to promote appropriate clinical service.

The vast majority of in-vitro research published in the past 25 years, is on post-cure properties of resin-composites . Interestingly, there are very few studies that deal with the pre-cure handling properties , despite the interest of clinicians in this subject which includes stickiness, slumping, and sculpting of the occlusal anatomy of the restored teeth . Handling behavior will ultimately affect the clinical selection of a material for a specific restoration. In consequence, there is increased demand for the development of restorative composites, which not only exhibit good post-cured mechanical properties, but also improved handling characteristics .

Resin-composites are viscoelastic materials exhibiting both viscous and elastic nature at the same time depending on their composition, which also affect their response to an external force, and afterward their stress relaxation . Many rheological properties of restorative materials are related to their handling characteristics, such as viscosity, elasticity, flowability and adaptability to cavity walls .

However rheology properties of filled resin-composites are rare and difficult to produce consistent results . Clinically a composite paste will be packed into a cavity or onto a shallow tooth surface. Particularly in a cavity, cavity dimension such as width will influence the packability. This influence of cavity-wall proximity may be termed the wall effect .

The aim of this paper is to present a methodology for characterizing the relative stiffness and packability of the composite paste. This method will take into account the wall effect and also temperature. The null hypotheses tested in this investigation were: (i) there was no wall effect apparent resulting from different cavity sizes; (ii) Force or stress required for packing composite paste into a standardized cavity did not vary with composite formulation; (iii) Force or stress required for packing composite paste into a standardized cavity did not vary with composite temperature.

2

Materials and methods

Five representative dimethacrylate and one silorane based resin-composites were selected for this investigation ( Table 1 ). Maximum packing force of the resin-composite with and without wall-effect was measured using a sensitive stress strain instrument (TA.XT2i Stable Micro Systems, Godalming, Surrey, UK) . The analyzer comprised a stainless-steel cylindrical probe of varying diameter ( φ = 2 or 6 mm) connected to a force transducer to measure the force acting on the probe. Modifications to the analyzer were carried out as follows: a thermostatically controlled frame ( φ = 70 mm) was constructed and fixed to the stainless steel stand, this frame contained a cylindrical mould cavity ( Fig. 1 ), the dimensions of which could be altered ( φ = 7, depth = 5 mm; or φ = 3, depth = 5 mm) and into which the composite sample to be tested was placed. The temperature of the mould cavity was regulated using an embedded thermostat and an adjustable power supply unit, with a thermocouple in close proximity to the sample: the temperature was set at either 26 °C (room temperature) or 37 °C (oral cavity temperature).

Experimental setup used for the bulk packing analysis.

The modified apparatus was used to measure and analyze the maximum packing force ( F _p , N) during bulk packing. A flat-ended stainless-steel probe with a diameter of either 6 mm or 3 mm was mechanically lowered onto the surface of the unset sample with a pre-test speed of 5 mm/s, then after touching the material surface and obtaining the trigger resistance force of 0.049 N (app 5 g) it moved with a test speed of 0.50 mm/s to a trigger depth of 2 mm and stayed there for a holding time of 10 s or in few cases longer than that. Data acquisition commenced when the probe acquires the trigger force of 0.049 N and continued during the movement of the probe up to a depth of 2 mm and for the holding time.

Compressive force data (N) was plotted against the time (s). F _P , was obtained from the maximum height of the peak of this graph ( Fig. 2 ). F _p can be re-expressed as peak stress S _p by dividing the F _p by area of the probe used. The test conditions used allowed for the magnitude of the wall-effect to be determined.

Typical force time profile obtained for Grandio at 26 °C.

Data were entered into statistical software (SPSS ver. 16, SPSS Inc., Illinois, USA) and analyzed with Univariate ANOVA (Plunger vs cavity, temperature and material as independent variables). Multiple pair-wise comparisons using a Tukey post-hoc test were conducted to establish homogenous subsets at ( p = 0.05).

2

Materials and methods

Five representative dimethacrylate and one silorane based resin-composites were selected for this investigation ( Table 1 ). Maximum packing force of the resin-composite with and without wall-effect was measured using a sensitive stress strain instrument (TA.XT2i Stable Micro Systems, Godalming, Surrey, UK) . The analyzer comprised a stainless-steel cylindrical probe of varying diameter ( φ = 2 or 6 mm) connected to a force transducer to measure the force acting on the probe. Modifications to the analyzer were carried out as follows: a thermostatically controlled frame ( φ = 70 mm) was constructed and fixed to the stainless steel stand, this frame contained a cylindrical mould cavity ( Fig. 1 ), the dimensions of which could be altered ( φ = 7, depth = 5 mm; or φ = 3, depth = 5 mm) and into which the composite sample to be tested was placed. The temperature of the mould cavity was regulated using an embedded thermostat and an adjustable power supply unit, with a thermocouple in close proximity to the sample: the temperature was set at either 26 °C (room temperature) or 37 °C (oral cavity temperature).

Table 1

Resin composite restorative materials used for the investigation.

Materials	Code	Lot no	Filler wt%	Manufacturer
Clearfil Majesty Esthetic	CME	00001A	66%	Kuraray Medical, Germany
Clearfil Majesty posterior	CMP	00006A	82%	Kuraray Medical, Germany
Filtek Silorane	FS	7AR	76%	3M ESPE, St. Paul, USA
XRV Herculite ultra enamel	XRV	07-1032E/05-1263D	79%	Kerr, USA
Quixfil	Qu	0703002499	66%	Dentsply, Germany
Grandio	Gr	630877	87%	Voco, Cuxhaven Germany

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