2.1

Groups

The groups differed in the used restorative material ( Table 1 ) and the fabrication technique. In total, 3 groups of 20 specimens each (n = 20) were included: (1) “3DP”: 3D-printed occlusal veneers made out of zirconia (Lithoz, Vienna, Austria); (2) “CAM”: CAD/CAM-fabricated occlusal veneers milled out of zirconia (Ceramill Zolid FX; Amann Girrbach, Pforzheim, Germany); (3) “HPR”: heat-pressed occlusal veneers made out of lithium-disilicate ceramic (IPS e.max press; Ivoclar Vivadent, Schaan, Liechtenstein).

2.2

Specimen preparation

In total, 60 extracted and intact human molars were inserted in an acrylic hollow cylinder made out of acrylic glass. The apical part of the tooth was embedded in self-curing resin (Technovit 4071; Kulzer, Wasserburg, Germany). To create typical defects for attrition or erosion, the occlusal enamel of the crown was removed until exposure of the dentin. Furthermore, fissures were slightly opened and sharp edges were rounded off. The specimens were randomly allocated to one of the study groups. During the complete study, the specimens were stored in distilled water.

2.3

Scanning procedures and restoration design

An optical impression of the prepared tooth was taken by means of a desktop scanner (Identica 3D Scanner; Dental Concept Systems, Ulm, Germany) and transmitted to a design software (3Shape software; Copenhagen, Denmark). Occlusal veneers were designed with a homogenous thickness of 0.5 mm ( Fig. 1 ).

Specimen and digitally designed semi-transparent depicted restoration from (a) lateral and (b) latero-occlusal.

2.4

Fabrication of the restorations

According to the group allocation, the ceramic restorations were fabricated.

2.4.1

Group 3DP: fabrication procedures

The occlusal veneers of the group 3DP were fabricated by means of the Lithography-based Ceramic Manufacturing (LCM) process, which is based on the concept of photopolymerization ( Fig. 2 ) [ , ]. Ceramic powder was dispersed into a mixture of photo-curable monomers to create the ceramic slurry (LithaCon 3Y 610 white; Lithoz, Vienna). The materials processed by LCM-technology were slurries comprising a photopolymerizable monomer mixture (dynamic viscosity at 20 °C is 43 Pa s) filled with various types of ceramic powder (3 mol% Y ₂ O ₃ stabilized ZrO ₂ in a purity of 99.9%) in a concentration of 40–60 Vol%. A thin layer of this slurry was automatically coated onto the vat, which is an assembly with transparent glass bottom. Thereafter, the building platform approached the vat, only leaving a small gap of 25 μm, which was filled with slurry. This gap correlates to the thickness of an individual layer in the green part. Consecutively, the photosensitive compounds comprised within this slurry were cured by selective exposure with blue light (wavelength 460 nm). Where this light hit the ceramic-filled slurry, the monomers photopolymerized into a 3-dimensional network, which then acted as a cage for the ceramic filler. After completing the layer, the building platform was elevated and the whole sequence was repeated all over again. The occlusal veneers were layered perpendicular to the tooth axis. The scaling factor was in XY-direction 1.358× and in Z-direction 1.370× to compensate for the sinter-shrinkage. After the layer-by-layer structuring using the CeraFab 7500-system (Lithoz, Vienna) the green parts were cleaned from the excess slurry by using compressed air and an appropriate solvent (LithaSol 20, Lithoz) capable of dissolving the slurry without damaging the cured structure. Postprocessing involved the debinding of the green part in which the organic photopolymer matrix was removed through pyrolysis at stepwise raising temperatures between 115 and 1’450 °C. Then, the resulting white parts were sintered in a high-temperature (1’450 °C, 2 h) furnace (Nabertherm HTCT 08/16; Nabertherm, Lilienthal, Germany) to fully density (99.3%). Thereafter, the supporting structure was cautiously removed ( Fig. 3 ).

Schematic drawing of the 3D printer, producing the occlusal veneers of group 3DP with the Lithography-based Manufacturing process. In this process, LED light of 460 nm wavelength (1) hits a digital micro mirror device (2). In this device, micro mirrors can be positioned in an activated or in a deactivated position. By activating or deactivating the mirrors, light can be selectively transmitted to the vat (3). The vat itself is filled with a slurry of ceramic powder (white symbols) dispersed in a mixture of photo-curable monomers (blue symbols) (4). Where the light hits the ceramic-filled slurry, the monomers photo-polymerize into a 3-dimensional network, which then acts as a cage for the ceramic filler. The building-platform takes up the 3-dimensional network layer by layer (For interpretation of the references to color in this figure legend, the reader is referred to the web version of this article.).

3D-printed occlusal veneer before removing the support structures resulting from the printing process with (a) view from occlusal and (b) view on the inner surface. 3D-printed occlusal veneer (c) after having removed the supporting structure.

2.4.2

Group CAM: fabrication procedures

The ceramic restorations of the group CAD were directly milled out of pre-fabricated zirconia discs (Ceramill Zolid FX; Amann Girrbach) using a 5-axis milling machine (Ceramill Motion2 5×; Amann Girrbach). Thereafter, the restorations were sintered to full density according to the manufacturer’s instructions (Ceramill Therm S; Amann Girrbach).

2.4.3

Group HPR: fabrication procedures

For the ceramic restorations of the group HPR, first, a PMMA template was milled out of a pre-fabricated ingot (Ceramill PMMA; Amann Girrbach) by means of a 5-axis milling machine (Ceramill Motion2 5×; Amann Girrbach). The templates were then used to produce pressed lithium disilicate restorations applying the “lost-wax and press-technique” and following the manufacturer’s instructions. For this purpose, the PMMA-templates were fixed by a wax sprue (IPS Multi Wax Pattern Form A; Ivoclar Vivadent) and vested (IPS PressVEST Premium; Ivoclar Vivadent) into a mold. In an oven (KaVo EWL 5645; KaVo, Kloten, Switzerland), the vested templated was heated to complete dissolution: rate of 5 °C min ⁻¹ from room temperature to 850 °C (holding time 60 min). Thereafter, into the resulting void, lithium-disilicate ceramic (IPS e.max Press; Ivoclar Vivadent) was heat-pressed in a heat-pressing sintering-oven (Programat EP 5010; Ivoclar Vivadent): rate 60 °C min ⁻¹ from 700 °C to 898 °C (holding time 25 min). After cooling, the restorations were carefully devested and cleaned from the investing material by air-abrasion (50 μm Al ₂ O ₃ ; Cobra, Renfert GmbH, Hilzingen, Germany) at a pressure of 2 bar. The surface was glazed and again placed into the sintering-oven.

2.5

Cementation protocols

The conditioning procedure of the inner surface of the ceramic restoration varied according to the groups. In group HPR, etching for 20 s with 5% hydrofluoric acid (IPS ceramic etching gel; Ivoclar Vivadent) followed by water-spraying and air-drying. In groups 3DP and CAM, air-abrasion was applied to the inner parts (Rocatec Plus 30 μm, 2.5 bar; 3 M ESPE, Seefeld, Germany). In all groups, a silane (Monobond Plus; Ivoclar Vivadent) was used and gently air-dried after 60 s. The enamel and the dentin of all specimens were etched with 35% phosphoric acid for 30 s (Ultraetch; Ultradent, Utah, USA). The surface was thereafter water-sprayed (30 s) and air-dried. An adhesive (Syntac Primer/Syntac Adhesive; Ivoclar Vivadent) was used for the dentinal parts. A bonding agent (Heliobond; Ivoclar Vivadent) was applied to the tooth surface and to the ceramic restorations and after 20 s gently air-blown. The restorations were adhesively cemented using a dual-curing resin cement (Variolink Esthetic DC; Ivoclar Vivadent). After removal of excess cement, light-curing was performed (6 × 40 s).

2.6

Aging procedures

A chewing simulator [ ] was used to age the specimens by a vertical indenter (rounded tip of ∅ 8 mm) executing a vertical movement of 1 mm in a perpendicular direction to the occlusal plane (1’200’000 cycles of 49 N force at 1.67 Hz loading frequency) and thermo-cycling (5–55 °C and a dwelling time of 120 s). After aging, the specimens were evaluated under a stereomicroscope (magnification 1.25×) to check for integrity.

2.7

Static loading

The aged specimens were loaded in a universal testing machine (Zwick/Roell Z010; Zwick, Ulm, Germany) to test the static fracture load. An indenter axially hit the occlusal surface of the specimen with a crosshead speed of 1 mm/min. The load which was necessary to initiate a crack (F _initial ) and the load which was needed to completely fracture the specimen (F _max ) were measured. The type of failure was specified under a stereomicroscope (9× magnification; Leica DFC300 FX; Wetzlar, Germany) and on photographs. The following scores were categorized: (1) score 0 = no visible fracture, (2) score 1 = cohesive fracture within the restoration, (3) score 2 = cohesive fracture of the restoration and of the cement layer, (4) score 3 = fracture of the restoration-cement-tooth complex.

2.8

Statistical analysis

The metric variables (F _initial , F _max ) were described with mean, median, standard deviations, quartiles, minimum and maximum. They were compared using a non-parametric Kruskal–Wallis test (KW). The exact p-values were calculated for the pair-wise comparisons between the groups using the Wilcoxon–Mann–Whitney-Test (WMW), applying the Bonferroni correction for the multiple testing.

The categorical variables (failure scores) were summarized by counts and proportions of the categories and compared applying the Chi–squares test with exact determination of the p-value.