2.1

Tooth preparation

Unerupted, unidentifiable extracted human third molars were screened to determine if they were permeable enough to be used in this study. The teeth were mounted enamel side down on cylindrical aluminum stubs using extra fast set epoxy cement (Hardman, Belleville, NJ, USA). Two sections were made using a slow-speed diamond saw under water lubrication (Isomet: Buehler Ltd., Lake Bluff, IL, USA). The first section, made 90° to the long axis of the tooth, removed the roots approximately 3 mm below the cementum–enamel junction. The second section, made in the same plane, was made 2–3 mm below the deepest occlusal pit or central groove to expose middle to deep coronal dentin. This removed all occlusal enamel and superficial dentin, creating a crown segment with a remaining dentin thickness between the highest pulp horn and the exposed dentin surface of between 0.6 and 1.2 mm, as measured with a digital pincer micrometer (Renfert GmbH, Hilzingen, Germany). This dentin thickness is permeable enough for screening desensitizing agents via this in vitro model .

The pulpal soft tissue was removed taking care not to touch the soft surface lining of the pulp chamber. The crown segment was then mounted to 2 cm × 2 cm × 0.5 cm squares of acrylic with a viscous cyanoacrylate adhesive (Zapit™ Glue, Dental Ventures of American, Corona, CA, USA). The center of the acrylic square was penetrated by a 1.5 cm length of 18 gauge stainless tubing, permitting the pulp chamber to be filled with fluid. A 0.02% sodium azide aqueous solution was used as the liquid medium to prevent microbial growth. All air bubbles were removed from the pulp chamber using a 23 gauge needle and syringe filled with the azide solution.

2.2

Fluid flow (permeability) measurements

The rate of fluid flow through a dentin specimen was measured using the Flodec device (DeMarco Engineering, Geneva, Switzerland) illustrated in Fig. 1 , which follows the movement of a tiny air bubble as it passes down a 0.6 mm diameter glass capillary located between a water reservoir under 140 cm (2 psi) of water pressure and the dentin specimens . An infrared light source passes through the capillary and is detected by a diode, allowing the unit to follow the progress of the air bubble along the length of the capillary. Linear displacement is automatically converted to volume displacement per unit time, from which the instantaneous volumetric flow rate is calculated and logged into a spreadsheet. Flow was measured until a steady-state was reached, typically 0–3 min; then the flow was measured for at least 2 min; since one datum was taken every second, this resulted in at least 100 readings for each condition. Permeability was expressed as a fluid flow rate in μL min ⁻¹ .

Schematic of permeability measurement system.

All teeth were acid-etched with 37% phosphoric acid for 30 s to ensure maximum permeability was achieved for each specimen. Following etching, dentin permeability was determined. After measuring the baseline permeability of all specimens, they were placed into three groups so that the mean permeability values were not statistically significantly different. During the investigation, some failures of the glue or of the dentin at thin pulp horns resulted in loss of specimens and thus in slightly different numbers of specimens among the groups; the final groups were still found to be balanced with respect to post-acid-etch (baseline) permeability.

2.3

Application of coating materials

Two materials were used in this study: a one-bottle, total etch adhesive with stabilized silica nanofiller, and a resin-modified glass ionomer coating material; lot and expiration date information are shown in Table 1 .

In group SBP-OPN, SBP was applied per manufacturer’s instructions to 11 acid-etched crown segments with open (OPN) tubules that had been measured for acid-etched (baseline) permeability. Two layers of SBP were applied in rapid succession to visibly moist dentin; after each layer the solvent was evaporated with an air stream for 5–10 s. The adhesive was light-cured for 20 s with a dental curing light (VIP™ Variable Intensity Polymerizer, Bisco Dental Products Co., Schaumburg, IL, USA). The oxygen-inhibited layer was removed with a Kimwipe™ tissue (Fisher Scientific) saturated with 100% ethanol. After 10 min in air, the treated crown segment was inverted into a small beaker half-filled with 0.02% sodium azide aqueous solution to prevent evaporative water loss from the dentin and to hydrate the dentin and adhesive; permeability was then measured again.

In group VXT-OPN, material VXT was mixed according to the manufacturer’s instructions, then applied to 11 blot-dried, moist dentin specimens that had been acid-etched with open (OPN) tubules as in the SBP treatment. After spreading the material in a thin layer, it was light-cured for 20 s. The cured VXT was kept hydrated via immersion at all times. Ten minutes after light-curing, permeability was measured in the same manner as group SBP-OPN.

In group VXT-SMR, a thin smear (SMR) layer was created after acid-etch (baseline) permeability measurements were made. The smear layer was created by lapping the etched dentin surface with three manual strokes on wet 400 grit silicon carbide abrasive paper. After measuring permeability through the smear-layer dentin, thereby confirming the presence of a smear layer (via decreased permeability), VXT was applied to the smear layer-covered dentin of 7 specimens as described above; the cured VXT was kept hydrated at all times. Again, 10 min after light-curing, permeability of the coated tooth specimens was measured.

Permeability reduction and residual permeability were calculated as a percent of the maximum (i.e. acid-etched) of each crown segment; for group VXT-SMR, permeability reduction and residual permeability were also calculated as a percent of the smear layer-covered value. Thus, each tooth served as its own control.

2.4

Scanning electron microscopy (SEM)

After completing the permeability measurements, a composite build-up (Filtek™ Z100 Restorative: 3M ESPE, Maplewood, MN, USA) was placed and light-cured over the coating on three teeth from each group in order to minimize the effects of dehydration. The specimens were then divided longitudinally via cryofracturing into equal halves. The fractured surfaces were acid-etched with 37% phosphoric acid for 5 s to remove any smear layer created by cryofracturing, and then treated with 5% NaOCl for 2 min to remove any uninfiltrated dentin matrix. All specimens were rinsed extensively in water prior to processing through an ascending alcohol series and critical-point drying . Each half was sputter coated with gold and examined by SEM.

2.1

Tooth preparation

Unerupted, unidentifiable extracted human third molars were screened to determine if they were permeable enough to be used in this study. The teeth were mounted enamel side down on cylindrical aluminum stubs using extra fast set epoxy cement (Hardman, Belleville, NJ, USA). Two sections were made using a slow-speed diamond saw under water lubrication (Isomet: Buehler Ltd., Lake Bluff, IL, USA). The first section, made 90° to the long axis of the tooth, removed the roots approximately 3 mm below the cementum–enamel junction. The second section, made in the same plane, was made 2–3 mm below the deepest occlusal pit or central groove to expose middle to deep coronal dentin. This removed all occlusal enamel and superficial dentin, creating a crown segment with a remaining dentin thickness between the highest pulp horn and the exposed dentin surface of between 0.6 and 1.2 mm, as measured with a digital pincer micrometer (Renfert GmbH, Hilzingen, Germany). This dentin thickness is permeable enough for screening desensitizing agents via this in vitro model .

The pulpal soft tissue was removed taking care not to touch the soft surface lining of the pulp chamber. The crown segment was then mounted to 2 cm × 2 cm × 0.5 cm squares of acrylic with a viscous cyanoacrylate adhesive (Zapit™ Glue, Dental Ventures of American, Corona, CA, USA). The center of the acrylic square was penetrated by a 1.5 cm length of 18 gauge stainless tubing, permitting the pulp chamber to be filled with fluid. A 0.02% sodium azide aqueous solution was used as the liquid medium to prevent microbial growth. All air bubbles were removed from the pulp chamber using a 23 gauge needle and syringe filled with the azide solution.

2.2

Fluid flow (permeability) measurements

The rate of fluid flow through a dentin specimen was measured using the Flodec device (DeMarco Engineering, Geneva, Switzerland) illustrated in Fig. 1 , which follows the movement of a tiny air bubble as it passes down a 0.6 mm diameter glass capillary located between a water reservoir under 140 cm (2 psi) of water pressure and the dentin specimens . An infrared light source passes through the capillary and is detected by a diode, allowing the unit to follow the progress of the air bubble along the length of the capillary. Linear displacement is automatically converted to volume displacement per unit time, from which the instantaneous volumetric flow rate is calculated and logged into a spreadsheet. Flow was measured until a steady-state was reached, typically 0–3 min; then the flow was measured for at least 2 min; since one datum was taken every second, this resulted in at least 100 readings for each condition. Permeability was expressed as a fluid flow rate in μL min ⁻¹ .

Schematic of permeability measurement system.

All teeth were acid-etched with 37% phosphoric acid for 30 s to ensure maximum permeability was achieved for each specimen. Following etching, dentin permeability was determined. After measuring the baseline permeability of all specimens, they were placed into three groups so that the mean permeability values were not statistically significantly different. During the investigation, some failures of the glue or of the dentin at thin pulp horns resulted in loss of specimens and thus in slightly different numbers of specimens among the groups; the final groups were still found to be balanced with respect to post-acid-etch (baseline) permeability.

2.3

Application of coating materials

Two materials were used in this study: a one-bottle, total etch adhesive with stabilized silica nanofiller, and a resin-modified glass ionomer coating material; lot and expiration date information are shown in Table 1 .

In group SBP-OPN, SBP was applied per manufacturer’s instructions to 11 acid-etched crown segments with open (OPN) tubules that had been measured for acid-etched (baseline) permeability. Two layers of SBP were applied in rapid succession to visibly moist dentin; after each layer the solvent was evaporated with an air stream for 5–10 s. The adhesive was light-cured for 20 s with a dental curing light (VIP™ Variable Intensity Polymerizer, Bisco Dental Products Co., Schaumburg, IL, USA). The oxygen-inhibited layer was removed with a Kimwipe™ tissue (Fisher Scientific) saturated with 100% ethanol. After 10 min in air, the treated crown segment was inverted into a small beaker half-filled with 0.02% sodium azide aqueous solution to prevent evaporative water loss from the dentin and to hydrate the dentin and adhesive; permeability was then measured again.

In group VXT-OPN, material VXT was mixed according to the manufacturer’s instructions, then applied to 11 blot-dried, moist dentin specimens that had been acid-etched with open (OPN) tubules as in the SBP treatment. After spreading the material in a thin layer, it was light-cured for 20 s. The cured VXT was kept hydrated via immersion at all times. Ten minutes after light-curing, permeability was measured in the same manner as group SBP-OPN.

In group VXT-SMR, a thin smear (SMR) layer was created after acid-etch (baseline) permeability measurements were made. The smear layer was created by lapping the etched dentin surface with three manual strokes on wet 400 grit silicon carbide abrasive paper. After measuring permeability through the smear-layer dentin, thereby confirming the presence of a smear layer (via decreased permeability), VXT was applied to the smear layer-covered dentin of 7 specimens as described above; the cured VXT was kept hydrated at all times. Again, 10 min after light-curing, permeability of the coated tooth specimens was measured.

Permeability reduction and residual permeability were calculated as a percent of the maximum (i.e. acid-etched) of each crown segment; for group VXT-SMR, permeability reduction and residual permeability were also calculated as a percent of the smear layer-covered value. Thus, each tooth served as its own control.

2.4

Scanning electron microscopy (SEM)

After completing the permeability measurements, a composite build-up (Filtek™ Z100 Restorative: 3M ESPE, Maplewood, MN, USA) was placed and light-cured over the coating on three teeth from each group in order to minimize the effects of dehydration. The specimens were then divided longitudinally via cryofracturing into equal halves. The fractured surfaces were acid-etched with 37% phosphoric acid for 5 s to remove any smear layer created by cryofracturing, and then treated with 5% NaOCl for 2 min to remove any uninfiltrated dentin matrix. All specimens were rinsed extensively in water prior to processing through an ascending alcohol series and critical-point drying . Each half was sputter coated with gold and examined by SEM.