1

Introduction

In restorative dentistry, there exists a significant demand for reduction in curing duration to minimize chairside procedure times of multi-increment resin composite restorations. Combined with the increasing popularity and demand for photoactive resin-based restorations as a replacement for dental amalgam, major financial implications have been suggested for dentists who chose to use high power, fast curing light sources . In order to achieve shorter exposure times (<10 s), whilst maintaining optimum material properties, the general trend among manufacturers has been to produce light curing units with increased irradiance. This is based on the assumption that the total energy of the irradiation, i.e. radiant exposure (J/cm ² ), is the main determining factor in degree of conversion and mechanical properties of the photoactive material. As radiant exposure is the product of irradiance ( I , mW/cm ² ) and irradiation time ( t , s), it supposed that comparable material properties result from similar radiant exposure, no matter how it is obtained (by different combinations of I and t ). This is the principle known as the “exposure reciprocity law”. While in certain cases this law is upheld , other studies have reported that although radiant exposure plays an important role, I and t independently influence polymer chain length, extent of crosslinking and mechanical properties, and as such, exposure reciprocity does not hold under all conditions . A major difference among these previous citations is that some consider filled and others unfilled materials. As the experimental conditions seem critical to study exposure reciprocity law validity, it is relevant to include both classes of material in a single study, which to our knowledge has yet to be investigated.

Alternative photoinitiators have been integrated in commercially available materials in the last few years, mostly for aesthetic reasons, due to yellowing by camphorquinone/amine systems . As some of these alternative photoinitiators are also interesting in terms of photopolymerization efficiency, they might also have an impact on the validity of exposure reciprocity law. Notably, Lucirin-TPO, a monoacylphosphine oxide, seems to be a promising molecule, as it presents higher molar absorptivity and curing efficiency . However, considering the absorption characteristics of TPO and the increased scattering of light of shorter wavelength, inferior curing depth of materials that replace CQ with TPO may be a cause for concern . Although recent work has highlighted the potential of TPO-based polymers to be cured in thick layers and for use in dental adhesives , its application in filled resin composites has not been fully described. To date, the curing efficiency of TPO in filled resin-based composite has only been studied in commercial materials , in which TPO is not used by itself but in combination with CQ. In the latter case, lower quantum yields were measured for polymerization initiated by a mixture of TPO and CQ compared to systems in which TPO was used alone, probably due to a transfer from the more efficient photoinitiator (TPO) to the less efficient one (CQ) . In addition, the exact photoinitiator concentration and ratio in commercially available composite materials is usually proprietary.

Consequently, the aim of this work was to investigate the impact of photoinitiator type on the polymerization efficiency in unfilled and filled experimental resins. Degree of conversion (DC) and depth of cure were measured to investigate the influence of the photoinitiator type and the presence or absence of fillers on the applicability of exposure reciprocity law.

2

Materials and methods

50/50 mass% Bis-GMA/TEGDMA resins were prepared with two different photoinitiator systems at equimolar concentration (0.0134 mol dm ⁻³ ): either camphorquinone (CQ), and the co-initiator, dimethylaminoethyl methacrylate (0.20/0.80 mass%) or Lucirin-TPO. The more bulky TPO structure has a molecular weight of almost twice that of CQ (348 and 166, respectively; Fig. 1 ) and an equimolar concentration of TPO corresponded to 0.42 mass%. The resins were tested either unfilled or filled with silanated barium glass fillers (0.7 μm) (Esschem Europe Ltd., Seaham) and fumed silica (14 nm) (Aerosil 150, Evonik Industries, Germany) to 65/10 mass%, respectively. Specimens were cured with a 11 mm diameter tip halogen Swiss Master Light (EMS, Switzerland), chosen for its broad spectrum, overlapping the absorption spectrum of both photoinitiators (albeit only partially with TPO). Emission spectra were measured by calibrating a UV–Vis spectrometer (USB4000, Ocean Optics) using a deuterium tungsten light source (calibrated to NIST standards) with known spectral output in the UV–VIS and NIR range (Mikropack DH2000-CAL, Ocean Optics, Dunedin, USA), which allowed absolute measurements of irradiance for the light curing unit (LCU). The intensity of the LCU was controlled by stacking neutral density filters (Thorlabs, UK) which produced a 6-fold reduction in irradiance over the whole spectrum. The absorption spectra of the photoinitiators were determined in methyl methacrylate (Sigma–Aldrich, UK) using the UV–Vis spectrometer coupled to a standard cuvette holder in absorbance mode. Three different curing protocols were applied to compare the applicability of exposure reciprocity law and another one to assess the potential of time reduction at the highest irradiance. 400 mW/cm ² for 45 s was chosen as the reference protocol and compared to protocols of the same radiant exposure (18 J/cm ² ): 1500 mW/cm ² for 12 s and 3000 mW/cm ² for 6 s. The last irradiation protocol, 3000 mW/cm ² for 3 s, was chosen to assess the effect of half the radiant exposure on TPO-based materials. The irradiance values were based on the in-built radiometer of the curing-unit and verified by the spectrometer. Degree of conversion (DC) and rate of polymerization ( R _p ) were measured in real-time by Fourier Transform near infrared spectroscopy (FT-NIRS; Fig. 2 ) by monitoring the height of the peak at 6164 cm ⁻¹ , which corresponded with the vinyl –CH ₂ absorbance. Curing kinetics of resins and resin composites were measured for 70 s through a 12 mm × 1.4 mm cylindrical white Teflon mould placed on a glass slide and covered by a thin glass cover slip ( n = 3) ( Fig. 2 ). Though DC is known to slightly evolve up to 24 h after irradiation, the major part of the polymerization occurs during irradiation . For that reason, DC at 70 s after the start of irradiation was chosen for comparison and will be referred to as DC ^max . A real time measurement of the maximum temperature rise (Δ T ^max ) during the polymerization was performed using a similar set up as for FTIR measurements, except that the mould was split on one side to insert a thermocouple. The latter was glued in place so that the bead of the thermocouple (1.5 mm diameter) was in contact with the outer edge of the sample. The thermocouple was calibrated against a standard mercury thermometer. The depth of cure was measured by an penetrometer technique after curing the samples in a cylindrical Teflon mould (5 mm diameter) ( n = 3). Statistical analyses were performed on the DC ^max , <SPAN role=presentation tabIndex=0 id=MathJax-Element-1-Frame class=MathJax style="POSITION: relative" data-mathml='Rpmax’>RmaxpRpmax
R p max
, depth of cure and Δ T ^max data sets using a general linear model (GLM) three-way analysis of variance (ANOVA) with PI (2 levels), filler inclusion (2 levels) and curing mode (4 levels) as the independent variables. Supplementary two-way ANOVA and post hoc Tukey multiple comparison tests ( p = 0.05) were also performed.

The chemical structure of the photoinitiators tested in the present study.

Experimental setup for of real-time FT-NIRS measurements.

2

Materials and methods

50/50 mass% Bis-GMA/TEGDMA resins were prepared with two different photoinitiator systems at equimolar concentration (0.0134 mol dm ⁻³ ): either camphorquinone (CQ), and the co-initiator, dimethylaminoethyl methacrylate (0.20/0.80 mass%) or Lucirin-TPO. The more bulky TPO structure has a molecular weight of almost twice that of CQ (348 and 166, respectively; Fig. 1 ) and an equimolar concentration of TPO corresponded to 0.42 mass%. The resins were tested either unfilled or filled with silanated barium glass fillers (0.7 μm) (Esschem Europe Ltd., Seaham) and fumed silica (14 nm) (Aerosil 150, Evonik Industries, Germany) to 65/10 mass%, respectively. Specimens were cured with a 11 mm diameter tip halogen Swiss Master Light (EMS, Switzerland), chosen for its broad spectrum, overlapping the absorption spectrum of both photoinitiators (albeit only partially with TPO). Emission spectra were measured by calibrating a UV–Vis spectrometer (USB4000, Ocean Optics) using a deuterium tungsten light source (calibrated to NIST standards) with known spectral output in the UV–VIS and NIR range (Mikropack DH2000-CAL, Ocean Optics, Dunedin, USA), which allowed absolute measurements of irradiance for the light curing unit (LCU). The intensity of the LCU was controlled by stacking neutral density filters (Thorlabs, UK) which produced a 6-fold reduction in irradiance over the whole spectrum. The absorption spectra of the photoinitiators were determined in methyl methacrylate (Sigma–Aldrich, UK) using the UV–Vis spectrometer coupled to a standard cuvette holder in absorbance mode. Three different curing protocols were applied to compare the applicability of exposure reciprocity law and another one to assess the potential of time reduction at the highest irradiance. 400 mW/cm ² for 45 s was chosen as the reference protocol and compared to protocols of the same radiant exposure (18 J/cm ² ): 1500 mW/cm ² for 12 s and 3000 mW/cm ² for 6 s. The last irradiation protocol, 3000 mW/cm ² for 3 s, was chosen to assess the effect of half the radiant exposure on TPO-based materials. The irradiance values were based on the in-built radiometer of the curing-unit and verified by the spectrometer. Degree of conversion (DC) and rate of polymerization ( R _p ) were measured in real-time by Fourier Transform near infrared spectroscopy (FT-NIRS; Fig. 2 ) by monitoring the height of the peak at 6164 cm ⁻¹ , which corresponded with the vinyl –CH ₂ absorbance. Curing kinetics of resins and resin composites were measured for 70 s through a 12 mm × 1.4 mm cylindrical white Teflon mould placed on a glass slide and covered by a thin glass cover slip ( n = 3) ( Fig. 2 ). Though DC is known to slightly evolve up to 24 h after irradiation, the major part of the polymerization occurs during irradiation . For that reason, DC at 70 s after the start of irradiation was chosen for comparison and will be referred to as DC ^max . A real time measurement of the maximum temperature rise (Δ T ^max ) during the polymerization was performed using a similar set up as for FTIR measurements, except that the mould was split on one side to insert a thermocouple. The latter was glued in place so that the bead of the thermocouple (1.5 mm diameter) was in contact with the outer edge of the sample. The thermocouple was calibrated against a standard mercury thermometer. The depth of cure was measured by an penetrometer technique after curing the samples in a cylindrical Teflon mould (5 mm diameter) ( n = 3). Statistical analyses were performed on the DC ^max , <SPAN role=presentation tabIndex=0 id=MathJax-Element-2-Frame class=MathJax style="POSITION: relative" data-mathml='Rpmax’>RmaxpRpmax
R p max
, depth of cure and Δ T ^max data sets using a general linear model (GLM) three-way analysis of variance (ANOVA) with PI (2 levels), filler inclusion (2 levels) and curing mode (4 levels) as the independent variables. Supplementary two-way ANOVA and post hoc Tukey multiple comparison tests ( p = 0.05) were also performed.

The chemical structure of the photoinitiators tested in the present study.

Experimental setup for of real-time FT-NIRS measurements.

3

Results

Fig. 3 presents a comparison between the absorption spectra of both photoinitiators (CQ and TPO) and the emission spectra of the curing-unit at 400, 1500 and 3000 mW/cm ² . An increased power of the curing unit resulted in a greater effective irradiance at shorter wavelengths and thus the overlap with TPO absorption was improved. However, spectral emission was better adapted to CQ absorption, as a greater overlap of the two spectra was evident.

Absorption spectra (left axis, in L mol ⁻¹ cm ⁻¹ ) of CQ (light grey shade) and L (dark grey shade) compared to emission spectra of the Swiss Master Light (right axis, in μW/cm ² nm) at different irradiances, i.e. 400, 1500 and 3000 mW/cm ² . An improvement of the overlap with L absorption can be observed with increased power of the curing unit.

The GLM of all independent variables revealed significant differences ( p < 0.001) where PI (df = 1; F = 5971) > filler inclusion (df = 1; F = 1302) > curing mode (df = 3; F = 809). A two-way ANOVA test of DC ^max results revealed significant overall differences for both PI and curing mode ( p < 0.001). Comparing irradiation modes of similar radiant exposure (18 J/cm ² ), DC ^max was significantly higher for all resin and resin composite TPO-based materials compared with CQ-based materials ( p < 0.05; Figs. 4a and 5a , Tables 1 and 2 ). For TPO, an increase in irradiance resulted in higher DC ^max regardless of exposure duration, while a reverse trend was observed for CQ-based materials where longer exposure led to higher DC ^max regardless of irradiance. DC ^max significantly decreased in most cases with addition of fillers ( p < 0.05), except for CQ-based materials cured with the highest irradiance where filled resins exhibited a significantly increased DC ^max compared with the unfilled parent resin ( p < 0.05).

DC (a) and R _p (b) curves in real time during 70 s for 50/50 mass% Bis-GMA/TEGDMA resin. Grey and black curves correspond respectively to TPO-based and CQ-based resins. Irradiation modes are indicated on the charts.

DC (a) and R _p (b) curves in real time during 70 s for 50/50 mass% Bis-GMA/TEGDMA resin filled with 75 mass% fillers. Grey and black curves correspond respectively to TPO-based and CQ-based resins. Irradiation modes are indicated on the charts.

Table 1

Unfilled resins.

Photo-initiator	Mode		Radiant exposure (J/cm 2 )	DC max (%) mean (±SD)	<SPAN role=presentation tabIndex=0 id=MathJax-Element-3-Frame class=MathJax style="POSITION: relative" data-mathml='Rpmax’>RmaxpRpmax R p max (s −1 ) mean (±SD)	Δ T max (°C) mean (±SD)	Depth of cure (mm) mean (±SD)
	Time (s)	Irradiance (mW/cm 2 )
CQ	45	400	18	72.1 (0.7) d	0.024 (0.000) e	33.6 (2.0) b,c	18.2 (0.2) a
	12	1500	18	65.8 (0.5) e	0.043 (0.001) c,d	29.1 (1.4) c	16.9 (0.1) b
	6	3000	18	43.9 (1.2) f	0.040 (0.001) d	19.5 (3.9) d	14.4 (0.1) c
	3	3000	9	25.7 (1.3) g	0.028 (0.001) d,e	10.6 (1.4) e	9.5 (0.1) f
TPO	45	400	18	76.0 (0.1) c	0.058 (0.001) c	29.5 (1.9) b,c	9.6 (0.3) f
	12	1500	18	83.3 (0.5) a,b	0.133 (0.005) b	41.5 (3.2) a	11.8 (0.2) d
	6	3000	18	85.0 (0.3) a	0.186 (0.006) a	41.1 (1.8) a	10.4 (0.2) e
	3	3000	9	82.1 (0.2) b	0.177 (0.014) a	36.4 (3.3) a,b	4.4 (0.2) g

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