2.1

Specimen preparation and treatment

A total of 100 PEEK composite blocks (PEI/Nano-SiO ₂ /PEEK, reinforced with 7 wt% Nano-SiO ₂ , Jilin University Super Engineering Plastics Research Co., Ltd., China) each measuring 80 mm × 5 mm × 4 mm were prepared. The bonding surfaces of the blocks were polished with silicon carbide (grit 600, 800). The surfaces were cleaned in an ultrasonic water bath (Euronda, Italy) for 10 min and air-dried carefully before surface treatment. The specimens were randomly divided into five test groups ( n = 20) according to the following surface treatments:

2.1.1

Group A: no treatment

Group B (sulfuric acid etching): Bonding surfaces of the PEEK composite materials were etched with 98% sulfuric acid (Beijing Chemical Works, China) for 60 s. The acid was rinsed off with distilled water for 60 s and then dried with oil-free compressed air.

Group C (hydrofluoric acid etching): Bonding surfaces of the PEEK composite materials were etched with 9.5% hydrofluoric acid (Sino-Dentex Co., Ltd., China) for 60 s. The gel was rinsed off with distilled water for 60 s and then dried with oil-free compressed air.

Group D (argon plasma treatment): The surfaces of the PEEK composite materials were treated using radio frequency (RF) plasma device (Nanjing, China) at 13.56 MHz. Argon plasma gas was introduced into the chamber at a flow rate of 30 sccm. The working gas pressure was 30 Pa, and the operating power of the RF reflected power was 500 V. The PEEK samples were treated for 25 min.

Group E (air abrasion): The PEEK composite material surfaces were sandblasted with 50 μm Al ₂ O ₃ particles (Masel, USA) for 15 s at a pressure of 0.4 MPa and a distance of 10 mm perpendicular to the treated surface. The specimens were cleaned with distilled water for 60 s and then dried with oil-free compressed air.

To perform micro-morphologic examination of each surface treatment group, an additional specimen was produced and analyzed by scanning electron microscopy (SEM, Quanta600, FEI, Netherlands). Each group was sputter-coated with gold and analyzed at 1600× magnification.

2.2

Bonding procedure

Each group was divided into two subgroups ( n = 10) of different cements: RelyX™ Unicem and SE Bond/Clearfil AP-X™. Each sample was prepared on two bonded specimens. A double-sided adhesive tape with two 3.0 mm-diameter circular holes on the surface was placed on the specimen to define the bonding area. Acrylic plastic tubes with an inner diameter of 3.0 mm and a height of 4.0 mm were filled with RelyX™ Unicem or Clearfil AP-X™ and pressed onto the PEEK composite block, where the tube axis was perpendicular to the sample surface. On the one side, RelyX™ Unicem cements were applied in an acrylic plastic tube. Excess cement was removed from the bonding margin using small disposable brushes. The samples were light-cured under a SmartLite PS LED curing light (Dentsply DeTrey, Konstanz, Germany, 950 mW/cm ² ) for 40 s and then stored at room temperature for 30 min. Thereafter, the cylinders were carefully removed from the specimens. On the other side, when SE Bond/Clearfil AP-X™ was applied, the primer of SE bond adhesive system was used as the first layer of adhesive with micro-brushes for 20 s and then dried thoroughly in moderately mild oil-free air. A layer of SE Bond adhesive was applied, blown with gentle oil-free air, and then light-cured for 10 s. Clearfil AP-X™ composite resin was applied in the acrylic plastic tube and light-cured for an additional 40 s. Finally, the mold was carefully removed. Following the bonding procedure, all specimens were stored in distilled water at 37 °C for 24 h.

2.3

Shear bond strength measurements

Shear bond strength was measured with a Universal Testing Machine (5869 50 kN, Instron, USA). The specimens were fixed with a special fixture. The loading piston was closed to the bonding surface. The load was applied with a crosshead speed of 1 mm/min with the bonding surface parallel to the loading piston. The maximal load was measured before de-bonding occurred. The shear bond strength values were calculated using the formula τ = F / A , where τ is the shear bond strength (MPa), F is the fracture load ( N ), and A is the bond area (mm ² ). The de-bonding surface was examined under a stereomicroscope (40× magnification) (Shanghai Pudan Optical Instrument Co., Ltd., China) to evaluate the failure type of the samples. Failure was classified into the following types: (i) adhesive failure (no luting cement remnants on the polished specimen surface), (ii) cohesive failure (failure within the PEEK composite materials or resin cements), and (iii) mixed failure (luting cement remnants and polished specimen surface exposed).

2.4

Statistical analysis

SPSS 17.0 (SPSS Inc. Chicago, Illinois, USA) was used to analyze the values of shear bond strength. Two-way ANOVA testing and t tests were used to compare the impact of different luting cements and type of treatments of PEEK composite materials. Tukey post hoc tests ( α = 0.05) were applied. The level of significance was set for 5%.

2.1

Specimen preparation and treatment

A total of 100 PEEK composite blocks (PEI/Nano-SiO ₂ /PEEK, reinforced with 7 wt% Nano-SiO ₂ , Jilin University Super Engineering Plastics Research Co., Ltd., China) each measuring 80 mm × 5 mm × 4 mm were prepared. The bonding surfaces of the blocks were polished with silicon carbide (grit 600, 800). The surfaces were cleaned in an ultrasonic water bath (Euronda, Italy) for 10 min and air-dried carefully before surface treatment. The specimens were randomly divided into five test groups ( n = 20) according to the following surface treatments:

2.1.1

Group A: no treatment

Group B (sulfuric acid etching): Bonding surfaces of the PEEK composite materials were etched with 98% sulfuric acid (Beijing Chemical Works, China) for 60 s. The acid was rinsed off with distilled water for 60 s and then dried with oil-free compressed air.

Group C (hydrofluoric acid etching): Bonding surfaces of the PEEK composite materials were etched with 9.5% hydrofluoric acid (Sino-Dentex Co., Ltd., China) for 60 s. The gel was rinsed off with distilled water for 60 s and then dried with oil-free compressed air.

Group D (argon plasma treatment): The surfaces of the PEEK composite materials were treated using radio frequency (RF) plasma device (Nanjing, China) at 13.56 MHz. Argon plasma gas was introduced into the chamber at a flow rate of 30 sccm. The working gas pressure was 30 Pa, and the operating power of the RF reflected power was 500 V. The PEEK samples were treated for 25 min.

Group E (air abrasion): The PEEK composite material surfaces were sandblasted with 50 μm Al ₂ O ₃ particles (Masel, USA) for 15 s at a pressure of 0.4 MPa and a distance of 10 mm perpendicular to the treated surface. The specimens were cleaned with distilled water for 60 s and then dried with oil-free compressed air.

To perform micro-morphologic examination of each surface treatment group, an additional specimen was produced and analyzed by scanning electron microscopy (SEM, Quanta600, FEI, Netherlands). Each group was sputter-coated with gold and analyzed at 1600× magnification.

2.2

Bonding procedure

Each group was divided into two subgroups ( n = 10) of different cements: RelyX™ Unicem and SE Bond/Clearfil AP-X™. Each sample was prepared on two bonded specimens. A double-sided adhesive tape with two 3.0 mm-diameter circular holes on the surface was placed on the specimen to define the bonding area. Acrylic plastic tubes with an inner diameter of 3.0 mm and a height of 4.0 mm were filled with RelyX™ Unicem or Clearfil AP-X™ and pressed onto the PEEK composite block, where the tube axis was perpendicular to the sample surface. On the one side, RelyX™ Unicem cements were applied in an acrylic plastic tube. Excess cement was removed from the bonding margin using small disposable brushes. The samples were light-cured under a SmartLite PS LED curing light (Dentsply DeTrey, Konstanz, Germany, 950 mW/cm ² ) for 40 s and then stored at room temperature for 30 min. Thereafter, the cylinders were carefully removed from the specimens. On the other side, when SE Bond/Clearfil AP-X™ was applied, the primer of SE bond adhesive system was used as the first layer of adhesive with micro-brushes for 20 s and then dried thoroughly in moderately mild oil-free air. A layer of SE Bond adhesive was applied, blown with gentle oil-free air, and then light-cured for 10 s. Clearfil AP-X™ composite resin was applied in the acrylic plastic tube and light-cured for an additional 40 s. Finally, the mold was carefully removed. Following the bonding procedure, all specimens were stored in distilled water at 37 °C for 24 h.

2.3

Shear bond strength measurements

Shear bond strength was measured with a Universal Testing Machine (5869 50 kN, Instron, USA). The specimens were fixed with a special fixture. The loading piston was closed to the bonding surface. The load was applied with a crosshead speed of 1 mm/min with the bonding surface parallel to the loading piston. The maximal load was measured before de-bonding occurred. The shear bond strength values were calculated using the formula τ = F / A , where τ is the shear bond strength (MPa), F is the fracture load ( N ), and A is the bond area (mm ² ). The de-bonding surface was examined under a stereomicroscope (40× magnification) (Shanghai Pudan Optical Instrument Co., Ltd., China) to evaluate the failure type of the samples. Failure was classified into the following types: (i) adhesive failure (no luting cement remnants on the polished specimen surface), (ii) cohesive failure (failure within the PEEK composite materials or resin cements), and (iii) mixed failure (luting cement remnants and polished specimen surface exposed).

2.4

Statistical analysis

SPSS 17.0 (SPSS Inc. Chicago, Illinois, USA) was used to analyze the values of shear bond strength. Two-way ANOVA testing and t tests were used to compare the impact of different luting cements and type of treatments of PEEK composite materials. Tukey post hoc tests ( α = 0.05) were applied. The level of significance was set for 5%.