2.1

Materials

2,2-Bis[4-(2-hydroxy-3-methacrylyloxypropoxy)phenyl]propane (Bis-GMA) and triethylene glycol dimethacrylate (TEGDMA) (both from Esstech, Essington, PA) were used in a 70:30 mass ratio as a model dental resin. A visible light initiating system consisting of 0.3 wt% camphorquinone (CQ) as initiator and 0.8 wt% ethyl 4-dimethylaminobenzoate (EDAB) (Sigma–Aldrich, Milwaukee, WI) as co-initiator was incorporated. Barium glass (mean particle size 0.7 μm) surface treated with a coating of 5 wt% γ-methacryloxypropyltrimethoxysilane (γ-MPS), was used as the inorganic filler (Esstech). The filler was mixed with resin in varying amounts to obtain total final weight percentages of 0, 20, 40, 60 and 70, which correspond to filler volume fractions of 0, 9.4, 21.6, 38.3 and 49.1 respectively, based on densities of filler (2.71 g/cm ³ ) and uncured resin (1.12 g/cm ³ ) . Fillers and resin were blended in a centrifugal mixer (DAC 150 FVZ, Flakteck) to ensure thorough mixing.

2.2

Sample curing

Visible light irradiation was provided by a halogen dental curing lamp (VIP, Bisco, Schaumburg, IL). Light intensities and irradiation times were varied in order to achieve a wide range of conversions for specimens used in the various testing protocols. A radiometer (Model 100, Demetron Research, Danbury, CT, USA) was used to measure the output light intensity.

2.3

Infrared spectroscopy

Double bond conversion in the resin and composite specimens was monitored in transmission mode using near-infrared (NIR) spectroscopy (Nexus 670, Nicolet Instruments, Madison, WI). The area of the peak at 6165 cm ⁻¹ signifying the CH ₂ absorption was used to track the double bond conversion. All NIR measurements were taken at a wavenumber resolution of 4 cm ⁻¹ . For the static measurements, 64 scans per spectrum were taken for, while 2 scans per spectrum were used for collection of real-time series measurements with approximate 1 Hz sampling temporal resolution.

2.4

Shrinkage stress measurement

Shrinkage stress was measured using a cantilever beam-based tensometer, which was designed and fabricated at the Paffenberger Research Center of the American Dental Association Health Foundation (ADAHF–PRC, Gaithersburg, MD, USA). This device measures the dynamic tensile forces generated by a polymerizing sample that causes deflection of the calibrated beam. A more detailed description of the experimental technique has been reported in a previous study . Briefly, a composite sample is placed between two cylindrical quartz rods that have been treated with a methacrylate functional silane to promote bonding with the resin in the composite. The lower quartz rod is fixed whereas the upper quartz rod is attached to the cantilever. A curing light is connected by an adapter to the bottom of the lower quartz rod and light is transmitted through the rod to the sample causing polymerization and deflection of the cantilever with system compliance determined by positioning on the beam and designed to generally reflect tooth flexure. An LVDT (linear variable differential transformer) continuously tracks the beam deflection and this data is converted to a force measurement, which when divided by the composite cross-sectional area, provides the stress in the composite. The cavity in which the samples were placed was 6 mm in diameter and 1.5 mm in thickness. For the simultaneous measurement of conversion with shrinkage stress, the NIR signal was guided to/from the sample using optical fiber cables (1 mm diameter).

For the stress measurements, the samples ( n = 3) were irradiated with the VIP curing light at an incident irradiance of 250 mW/cm ² for 60, 10 and 5 s and also at 35 mW/cm ² for 20, 10 and 5 s, to obtain a wide range of conversion and associated stress values. Irradiance was measured at the end of the quartz rod in contact with the sample. The coupled stress/conversion data was collected continuously for 15 min.

2.5

Shrinkage measurement

Shrinkage was measured using a linometer (ACTA Foundation, Netherlands). In this method a liquid monomer or uncured composite paste sample was placed between a fixed upper glass plate and a freely moving aluminum disc, both of which were lightly greased to provide radial freedom of movement for the shrinking sample, which allows the linear post-gel shrinkage to be recalculated in terms of volumetric shrinkage. Disc specimens ( n = 3) of 6 mm in diameter and 1.5 mm in thickness were irradiated from the upper surface and the displacement of the aluminum disc was monitored by a LVDT. Irradiation intensity and times were used to coincide with those used for the stress measurements. Shrinkage was monitored continuously for 10 min. NIR scans of each specimen were taken prior to polymerization and immediately after removal from the linometer to avoid any significant post-cure conversion development.

2.6

Flexure modulus measurement

Flexural modulus was measured in three-point bending (MTS 858 Mini Bionix II). The specimen dimensions were 2 mm × 2 mm × 10 mm. Samples ( n = 5) were irradiated on one side and immediately inverted and irradiated under equivalent conditions from the opposite side to optimize conversion uniformity throughout the sample. A range of light intensities, from 25 to 575 mW/cm ² , were used. Samples were cured for 30–60 s on each side. Conversion was measured by NIR spectroscopy directly from the flexural test specimens before and immediately after curing. As soon as the NIR polymer spectrum was collected, the sample was submitted to mechanical testing. Again this was done to ensure well correlated conversion and mechanical property results.

2.7

Vicker’s microhardness test

Disc-shaped specimens (2 mm thickness and 10 mm diameter, n = 3) of each formulation were obtained by photopolymerization with the dental light at 700 mW/cm ² for three minutes on each flat surface. The Vicker’s hardness was measured using a microhardness tester (LM700AT, Leco, St. Joseph, MI). The specimens were indented with a diamond tip using a force of 300 gf for 15 s. The length of the indents was measured and the VHN was calculated using the following formula:

where F is the applied force in gf and d is the size of the indent in millimeters.

2.1

Materials

2,2-Bis[4-(2-hydroxy-3-methacrylyloxypropoxy)phenyl]propane (Bis-GMA) and triethylene glycol dimethacrylate (TEGDMA) (both from Esstech, Essington, PA) were used in a 70:30 mass ratio as a model dental resin. A visible light initiating system consisting of 0.3 wt% camphorquinone (CQ) as initiator and 0.8 wt% ethyl 4-dimethylaminobenzoate (EDAB) (Sigma–Aldrich, Milwaukee, WI) as co-initiator was incorporated. Barium glass (mean particle size 0.7 μm) surface treated with a coating of 5 wt% γ-methacryloxypropyltrimethoxysilane (γ-MPS), was used as the inorganic filler (Esstech). The filler was mixed with resin in varying amounts to obtain total final weight percentages of 0, 20, 40, 60 and 70, which correspond to filler volume fractions of 0, 9.4, 21.6, 38.3 and 49.1 respectively, based on densities of filler (2.71 g/cm ³ ) and uncured resin (1.12 g/cm ³ ) . Fillers and resin were blended in a centrifugal mixer (DAC 150 FVZ, Flakteck) to ensure thorough mixing.

2.2

Sample curing

Visible light irradiation was provided by a halogen dental curing lamp (VIP, Bisco, Schaumburg, IL). Light intensities and irradiation times were varied in order to achieve a wide range of conversions for specimens used in the various testing protocols. A radiometer (Model 100, Demetron Research, Danbury, CT, USA) was used to measure the output light intensity.

2.3

Infrared spectroscopy

Double bond conversion in the resin and composite specimens was monitored in transmission mode using near-infrared (NIR) spectroscopy (Nexus 670, Nicolet Instruments, Madison, WI). The area of the peak at 6165 cm ⁻¹ signifying the CH ₂ absorption was used to track the double bond conversion. All NIR measurements were taken at a wavenumber resolution of 4 cm ⁻¹ . For the static measurements, 64 scans per spectrum were taken for, while 2 scans per spectrum were used for collection of real-time series measurements with approximate 1 Hz sampling temporal resolution.

2.4

Shrinkage stress measurement

Shrinkage stress was measured using a cantilever beam-based tensometer, which was designed and fabricated at the Paffenberger Research Center of the American Dental Association Health Foundation (ADAHF–PRC, Gaithersburg, MD, USA). This device measures the dynamic tensile forces generated by a polymerizing sample that causes deflection of the calibrated beam. A more detailed description of the experimental technique has been reported in a previous study . Briefly, a composite sample is placed between two cylindrical quartz rods that have been treated with a methacrylate functional silane to promote bonding with the resin in the composite. The lower quartz rod is fixed whereas the upper quartz rod is attached to the cantilever. A curing light is connected by an adapter to the bottom of the lower quartz rod and light is transmitted through the rod to the sample causing polymerization and deflection of the cantilever with system compliance determined by positioning on the beam and designed to generally reflect tooth flexure. An LVDT (linear variable differential transformer) continuously tracks the beam deflection and this data is converted to a force measurement, which when divided by the composite cross-sectional area, provides the stress in the composite. The cavity in which the samples were placed was 6 mm in diameter and 1.5 mm in thickness. For the simultaneous measurement of conversion with shrinkage stress, the NIR signal was guided to/from the sample using optical fiber cables (1 mm diameter).

For the stress measurements, the samples ( n = 3) were irradiated with the VIP curing light at an incident irradiance of 250 mW/cm ² for 60, 10 and 5 s and also at 35 mW/cm ² for 20, 10 and 5 s, to obtain a wide range of conversion and associated stress values. Irradiance was measured at the end of the quartz rod in contact with the sample. The coupled stress/conversion data was collected continuously for 15 min.

2.5

Shrinkage measurement

Shrinkage was measured using a linometer (ACTA Foundation, Netherlands). In this method a liquid monomer or uncured composite paste sample was placed between a fixed upper glass plate and a freely moving aluminum disc, both of which were lightly greased to provide radial freedom of movement for the shrinking sample, which allows the linear post-gel shrinkage to be recalculated in terms of volumetric shrinkage. Disc specimens ( n = 3) of 6 mm in diameter and 1.5 mm in thickness were irradiated from the upper surface and the displacement of the aluminum disc was monitored by a LVDT. Irradiation intensity and times were used to coincide with those used for the stress measurements. Shrinkage was monitored continuously for 10 min. NIR scans of each specimen were taken prior to polymerization and immediately after removal from the linometer to avoid any significant post-cure conversion development.

2.6

Flexure modulus measurement

Flexural modulus was measured in three-point bending (MTS 858 Mini Bionix II). The specimen dimensions were 2 mm × 2 mm × 10 mm. Samples ( n = 5) were irradiated on one side and immediately inverted and irradiated under equivalent conditions from the opposite side to optimize conversion uniformity throughout the sample. A range of light intensities, from 25 to 575 mW/cm ² , were used. Samples were cured for 30–60 s on each side. Conversion was measured by NIR spectroscopy directly from the flexural test specimens before and immediately after curing. As soon as the NIR polymer spectrum was collected, the sample was submitted to mechanical testing. Again this was done to ensure well correlated conversion and mechanical property results.

2.7

Vicker’s microhardness test

Disc-shaped specimens (2 mm thickness and 10 mm diameter, n = 3) of each formulation were obtained by photopolymerization with the dental light at 700 mW/cm ² for three minutes on each flat surface. The Vicker’s hardness was measured using a microhardness tester (LM700AT, Leco, St. Joseph, MI). The specimens were indented with a diamond tip using a force of 300 gf for 15 s. The length of the indents was measured and the VHN was calculated using the following formula:

Stay updated, free dental videos. Join our Telegram channel

Join