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Review

Lithium Silicate-Based Glass Ceramics in Dentistry: A Narrative Review

by
Hanan Al-Johani
1,2,*,
Julfikar Haider
1,3,
Julian Satterthwaite
1 and
Nick Silikas
1
1
Division of Dentistry, School of Medical Sciences, University of Manchester, Manchester M13 9PL, UK
2
Department of Restorative Dentistry, Division of Biomaterials, Faculty of Dentistry, King Abdulaziz University, Jeddah 21589, Saudi Arabia
3
Department of Engineering, Manchester Metropolitan University, Manchester M15 6BH, UK
*
Author to whom correspondence should be addressed.
Prosthesis 2024, 6(3), 478-505; https://doi.org/10.3390/prosthesis6030034
Submission received: 6 April 2024 / Revised: 21 April 2024 / Accepted: 25 April 2024 / Published: 2 May 2024
(This article belongs to the Special Issue Dental Ceramics and Restorative Materials in Prosthodontics: The New Frontier of the Digital Workflow)
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Abstract

:
Considering the rapid evolution of lithium silicate-based glass ceramics (LSCs) in dentistry, this review paper aims to present an updated overview of the recently introduced commercial novel LSCs. The clinical and in vitro English-language literature relating to the microstructure, manufacturing, strengthening, properties, surface treatments and clinical performance of LSC materials was obtained through an electronic search. Findings from relevant articles were extracted and summarised for this manuscript. There is considerable evidence supporting the mechanical and aesthetic competency of LSC variants, namely zirconia-reinforced lithium silicates and lithium–aluminium disilicates. Nonetheless, the literature assessing the biocompatibility and cytotoxicity of novel LSCs is scarce. An exploration of the chemical, mechanical and chemo-mechanical intaglio surface treatments—alternative to hydrofluoric acid etching—revealed promising adhesion performance for acid neutralisation and plasma treatment. The subtractive manufacturing methods of partially crystallised and fully crystallised LSC blocks and the additive manufacturing modalities pertaining to the fabrication of LSC dental restorations are addressed, wherein that challenges that could be encountered upon implementing novel additive manufacturing approaches using LSC print materials are highlighted. Furthermore, the short-term clinical performance of zirconia-reinforced lithium silicates and lithium–aluminium disilicates is demonstrated to be comparable to that of lithium disilicate ceramics and reveals promising potential for their long-term clinical performance.

1. Introduction

Lithium silicate-based glass ceramics (LSCs) were first identified by Stookey [1] in 1959 from precipitations of lithium disilicate crystals in glass and nucleating clusters of Ag, forming a binary lithium disilicate glass ceramic system; this was subsequently reformulated by Beall [2] into a multi-component lithium disilicate and lithium metasilicate system. Later Ivoclar Vivadent (Schaan, Liechtenstein) introduced two pressable LSCs, IP Empress 2 (1998) and IPS e.max Press (2005), along with a machinable LSC block, IPS e.max CAD (2006) [3]. As a measure of the clinical success of its lithium disilicate formulation, Ivoclar Vivadent delivered 75 million IPS e.max Press and IPS e.max CAD restorations from 2005 to 2013 [4]. This success encouraged competing manufacturers to develop a plethora of commercial LSCs with patented chemical compositions and strengthening mechanisms in pressable and machinable formats [5]. In 2013, machinable zirconia-reinforced lithium silicates were developed by VITA Zahnfabrik (Bad Säckingen, Germany) and Dentsply Sirona (Salzburg, Austria) in the form of VITA Suprinity and Celtra Duo, respectively [6], and pressable versions were later introduced (Celtra Press, Dentsply Sirona, Salzburg, Austria, 2017 and VITA AMBRIA, VITA Zahnfabrik, Bad Säckingen, Germany, 2021). Moreover, lithium–aluminium disilicates were offered as fully crystallised CAD/CAM blocks, namely n!ce, by Straumann (Basel Switzerland) in 2017, and CEREC Tessera was developed by Dentsply Sirona (Salzburg, Austria) in 2021 [4,7]. Recent in vitro investigations by Ivoclar Vivadent explored the effects of incorporating lithium tantalate and lithium niobate precipitations in LSC formulations and reported positive findings for future material development [8,9,10]. Considering the similar coefficients of thermal expansion of LSCs and zirconia, novel LSC spray deposition has been advocated as a promising surface pre-treatment for zirconia restorations in an attempt to obtain favourable characteristics from both materials as well as to enhance the bond strength between zirconia and underlying resin cement [11,12,13].
Table 1 and Table 2 highlight the composition, flexural strength and clinical indications of pressable and CAD/CAM LSCs that are currently commercially available.
Previous existing review papers in the literature have investigated the chemical, aesthetic and mechanical aspects that govern the performance of recent LSC materials [5,6,7,14,15], while others have evaluated the outcomes of internal surface treatments on LSC cementation and adhesion [14,16]. The main aim of this narrative review is to shed light on the manufacturing and strengthening methodologies of the notably recent LSC materials pertaining to dental applications and to consolidate a comprehensive understanding of the updated fabrication techniques and surface treatment modalities available in the literature to enhance the knowledge of dental practitioners regarding the contemporary developments in this rapidly evolving field. The review methodology herein comprises applying a search strategy (Table 3), defining inclusion and exclusion criteria, screening relevant abstracts, retrieving the full text of studies from selected abstracts and extracting the main outcomes/findings. Inclusion selection criteria were articles written in English and related to LSC materials, including in vitro studies (comparative or experimental), technique reports, review articles, case reports and clinical studies. Exclusion criteria included any articles that failed to align with the items described in the inclusion criteria. Electronic searches included research in the literature published until February 2024.

2. Microstructure

The microstructure of LSCs comprises lithium disilicate crystals (≥50 vol%) formed via volume crystallisation with phosphorus pentoxide (P2O5) as their primary nucleant and (in some derivatives) zirconia (ZrO2) as a secondary nucleating agent [2,17]. Lithium (Li) was initially extracted from silicate mineral petalite (LiAlSi4O10) and later from spodumene (LiAlSi2O6). LSCs consist of three main silicate forms (Figure 1):
  • Lithium disilicate (Li2Si2O5): a layered silicate (i.e., phyllosilicate) in which silicon shares three oxygen atoms with its neighbouring atoms; this phase exists between 800 and 850 °C;
  • Lithium metasilicate (Li2SiO3): a single-chain silicate (i.e., inosilicate) where silicon shares only two oxygen atoms; this phase is metastable and exists exclusively between 600 and 800 °C;
  • Cristobalite (SiO2): a stable silica framework, i.e., tectosilicate, in which silicon shares all four oxygen atoms; this secondary phase crystallises following that of Li2Si2O5.
The microstructure of LSCs is governed by heterogeneous nucleation via a micro immiscilibity approach where foreign substrates are integrated within a glass matrix and create a microphase that acts as a heterogenous nucleating agent. Microphases gain kinetic energy upon heating, promoting crystal growth, phase separation and the development of additional crystal phases. Phosphorus pentoxide (P2O5) is considered the main LSC nucleant, and supplemental oxides (e.g., Al2O3, K2O, ZrO2, ZnO, MgO and CeO2) are added as secondary nucleating agents, fluxes or fining agents to accelerate crystallisation kinetics, control melting temperatures and viscosity and improve corrosion resistance [18,19,20]. Heating LSCs with P2O5 (>2 mol%) to 500–560 °C results in lithium orthophosphate (Li3PO4) and cristobalite (SiO2) [20]:
6 S i O L i + + P 2 O 5 500 560 ° C 2 L i 3 P O 4 + 3 S i O S i
Li3PO4 serves as a heterogeneous nucleus initiating the layered deposition (i.e., epitaxial growth) of lithium metasilicate crystals (Li2SiO3) starting from 530 to 590 °C until they decompose at 780–820 °C. Cristobalite crystals also decompose below 820 °C; concurrently, lithium disilicate (Li2Si2O5) crystals start growing in a rapid manner at 820 °C [20]:
S i O 2 + L i 2 S i O 3 820 ° C L i 2 S i 2 O 5
The elongated morphology of Li2Si2O5 crystals (i.e., high aspect ratio) toughens LSCs by virtue of crack deflection and crack bridging mechanisms [19]. Furthermore, the resultant LSC crystalline structure is a remarkably interlocked crystal network, and its epitaxial crystal growth relies on the minimal distance (<15%) between the nuclei lattices and growing crystals; fortunately, this is easily attained by the similar orthorhombic structures of Li3PO4 and Li2SiO3 [20]. Furthermore, in general, LSCs are considered to be multi-component and non-stoichiometric (i.e., with non-ratio atomic relationships within its elemental composition) and thereby can be further divided based on the dominance of the microstructural phase/phases [4,5] into four sub-classes:
  • Lithium disilicate ceramic (LDS): predominantly lithium disilicate (Li2Si2O5);
  • Lithium metasilicate ceramic (LM): predominantly lithium metasilicate (Li2SiO3);
  • Zirconia-reinforced lithium silicate (ZLS): biphasic lithium metasilicate/lithium disilicate (Li2SiO3/Li2Si2O5);
  • Lithium aluminium disilicate (ALD): biphasic spodumene/lithium disilicate (LiAlSi2O6/Li2Si2O5).
The majority of the CAD/CAM LSCs in the market (IPS e.max CAD, Rosetta SM, Amber Mill, Obsidian and VITA Suprinity) are available as partially crystallised blocks from Li2SiO3 to facilitate their soft-milling, and then undergo mandatory crystallisation and glaze firing protocols at higher temperatures (>800 °C) for Li2SiO3 phase transformation into the desired Li2Si2O5 crystalline structure. In the pre-sintered state, IPS e.max CAD blocks demonstrate low mechanical properties; however, upon sintering and crystallisation, the strength of the ceramic blocks improves tremendously [3]. More recently, attempts in limiting the CAD/CAM fabrication time have led to the development of fully crystallised LSC blocks either with post-milling glaze firing regimens (Celtra Duo and CEREC Tessera) or without glaze firing prerequisites (Initial LiSi Block and n!ce) [4,7].

2.1. Zirconia-Reinforced Lithium Silicate Ceramics (ZLSs)

The unique microstructure of these ceramics is due to the tetragonal zirconia fillers (ZrO2) added in concentrations of ~10 wt% in the glassy matrix, serving as a secondary nucleant to diphosphorus pentoxide (P2O5) (Figure 2) [21]. Currently, commercial ZLSs are offered as pressable ingots, including Celtra Press (Dentsply Sirona, Salzburg, Austria) and VITA AMBRIA (VITA Zahnfabrik, Bad Säckingen, Germany), as well as machinable blocks in a fully crystallised form, e.g., Celtra Duo (Dentsply Sirona, Salzburg, Austria), and in a partially crystallised from, e.g., VITA Suprinity (VITA Zahnfabrik, Bad Säckingen, Germany) [7]. The partially crystallised ZLS machinable blocks (VITA Suprinity, VITA Zahnfabrik, Bad Säckingen, Germany) are composed of pre-sintered Li2SiO3 nanocrystals embedded within moderately polymerised zirconosilicate glass. Upon heating the block to 810–820 °C, the Li2SiO3 crystals react with the glass to generate Li2Si2O5 (major) and Li3PO4 (minor) precipitates, resulting in a ~60 vol% crystalline phase with an average crystal size of 0.5–1 μm being incorporated in a zirconosilicate glass matrix [4,6,21,22]. This intricate microstructure provides the ZLSs with superior flexural strength, and improved aesthetics and machinability because of the higher percentage of the glassy matrix [23]. In vitro chewing simulation and artificial ageing studies conducted by the manufacturers of Celtra Duo (Dentsply Sirona, Salzburg, Austria) [24] claim that these ceramics behave in an uncharacteristic manner in which they gain strength upon hydrothermal ageing. Other published studies have explained this on the basis of zirconia phase transformation from tetragonal crystals into monoclinic ones, thereby resulting in crack retardation and, in turn, higher fracture loads [25,26,27]. X-ray diffraction (XRD) investigations have been employed to identify and quantify the crystalline structures within ZLS, while some researchers have not detected crystalline zirconia structures [21,28], but others have identified tetragonal ZrO2 crystals and aluminium silicate (VITA Suprinity, VITA Zahnfabrik, Bad Säckingen, Germany) after sintering at 840 °C [29], and extended firing at >875 °C [18].

2.2. Lithium–Aluminium Disilicates (ALDs)

ALDs were initially introduced by Straumann (Basel Switzerland) as one of the n!ce products, distinguished by the high density of ß-spodumene (LiAlSi2O6) (~41 vol%) in addition to Li2Si2O5 (28.5 vol%) and Li3PO4 (~10 wt%) [5,7] (Figure 3). The most recent ALD materials (CEREC Tessera) are advertised as “advanced lithium disilicates”, ostensibly due to the manufacturer (Dentsply Sirona, Salzburg, Austria) marketing of added Al2O3 content (~5 wt%) in the form of γ-spodumene, i.e., virgilite crystals (Li0.5Al0.5Si2.5O6), as well as Li2Si2O5 (~90 wt%) and Li3PO4 (~5 wt%). Toughening of CEREC Tessera occurs as a result of the thermal mismatch between Li0.5Al0.5Si2.5O6 and Li2Si2O5 crystals, which both form between 800 and 850 °C, causing residual stresses and crack tip shielding upon cooling of the ALD [7,30]. However, XRD investigations [5,31] obtained from Rietveld refinement have refuted this claim, stating that instead of virgilite, the crystalline content is composed of quartz (~3 vol%). Although ALDs are currently supplied as fully crystallised CAD/CAM blocks that can be cemented post-milling without further heating or glaze treatment requirements, evidence in the literature suggests that additional sintering is beneficial in minimising milling-induced surface flaws [7].

3. Manufacturing Techniques

The manufacturing of LSC materials is achieved through consolidating and heating ceramic powders by virtue of complex temperature-controlled crystallisation methods.

3.1. Melting Casting Crystallisation Method

Raw glass-forming components and nucleating agents are uniformly mixed and simultaneously melted at high temperatures ranging between 1300 and 1500 °C. The molten glass is quenched via casting it into the desired geometry and slowly cooling it at room temperature, i.e., it is annealed to form a precursor glass. Subsequently, a two-stage controlled heat treatment takes place, initially at temperatures slightly above the glass transition temperature (Tg), to stimulate nucleation; then, the temperature is raised in a second heating stage to facilitate the stable growth of crystals of minimal inherent stresses within the precursor glass. The final microstructure depends on the type and concentration of nucleating agents as well as the dimension and shape of the crystals (Figure 4). Complex geometries can be manufactured using this method, yielding uniformly dense compositions with accurate dimensions. However, as melting temperatures can be reduced via the addition low-melting-temperature oxides, the overall high temperatures and prolonged treatment time are considered limitations of this approach [32,33,34,35].

3.2. Powder Sintering Method

This method attempts to speed up manufacturing through the coincident sintering and crystallisation of glass particles; the raw glass materials are melted at high temperatures, quenched in water, finely ground into a powder, sieved in a blank and pressed at specific temperatures. The final crystalline structure is achieved via bulk nucleation along the glass grain border without the need for additional nucleating agents. This approach is less complex and time-consuming than the melting casting method and allows for the production of high-temperature fused glasses that cannot easily form a molten glass phase. However, a significant drawback is the resultant inherent porosity, which limits the fabrication of geometrically intricate configurations [32,33,34,35,36].

3.3. Sol–Gel Method

Hydrolysis is employed to create a gel from glass element precursors that is then dried into glass powder, moulded and sintered at reduced temperatures (600–800 °C). The main advantages of this method are the nano-scaled dimensions of glass particles that enhance the homogeneity of the final product, and that lower temperatures prevent the possible volatilisation of glass particles, thus reducing contamination. Nonetheless, this approach is time-consuming and expensive, and the sintering shrinkage of the gel poses a potential risk [32,35,37].

4. Strengthening Mechanisms

Owing to their brittle nature, LSCs cannot plastically deform to dissipate pre-existent internal dislocation energy, which could thus potentially result in catastrophic cleavage. Manufacturing processes inevitably generate critical flaws (inherent bulk flaws or outer surface defects) that act as strength-limiting zones of high-stress concentrations. The stochastic fracture behaviour of LSCs is thus due to the multi-fold randomly distributed critical flaws from which cracks of differing dimensions and orientations initiate and, subsequently, propagate. Ultimately, crack progression is governed by the size effect and weakest link theory postulating that cracks originate from the largest flaws oriented in a manner susceptible to the alignment of weakening tensile stresses [38,39,40,41]. Thus, the strengthening or toughening of LSCs is imperative to providing longevity and can be performed via a variety of intrinsic or extrinsic mechanisms [41,42,43,44]; the former focuses on inherent processes located within the crack tip vicinity (Figure 5), whereas the latter are acquired processes that impede the driving force behind the extension of a crack.
  • Intrinsic strengthening mechanisms
  • Crack tip deflection: Added particles in the glass matrix act as obstacles deflecting the crack into an altered plane, increasing the surface area per distance of the crack and consequently causing crack advancement to be decelerated as extra energy is needed for its propagation.
  • Crack tip shielding: This is triggered by high stresses within the crack tip vicinity, where residual stresses arise from mismatches in the coefficients of thermal expansion (CTE) between crystalline particles and the glass matrix; the greater CTE of crystals than that of the surrounding glass matrix stimulates compressive stresses at the crack tip that minimise its opening.
  • Crack bridging: In ceramic networks of high crystalline density, cracks spread in an inter-granular manner, thereby causing friction to be generated between the grains along crack surfaces, triggering grain pull-out, frictional interlocking and bridging, and thus impeding further crack extension. Bridging can also be accomplished via the reinforcement of added fibres or whiskers within the ceramic matrix.
  • Microcrack formation and crack branching: Concentrated stress around the crack tip generates microcracks within adjacent inherent flaws and grain boundaries oriented perpendicularly to the stress plane. Microcracks dissolve the crack expansion energy within the tip region, thereby hindering further crack advancement. Branching at the crack tip also acts to delay crack motion by increasing the crack surface area.
  • Transformation toughening: Stresses surrounding the crack tip region prompt crystalline phase transformations that are accompanied by volumetric expansion exerting favourable compressive residual stresses coalescing the crack tip.
  • Extrinsic strengthening mechanisms
  • Thermal tempering: This involves the controlled heating of a ceramic to a temperature that is slightly above the glass transition point (Tg) and beneath the softening point (Ts), creating a rigid exterior surface that envelopes a molten centre [45]. Upon cooling, the molten core contracts and a temperature gradient is generated between the surface and bulk, yielding residual compressive stresses within the former and inner residual tensile stresses within the latter (Figure 6). Therefore, to fracture tempered ceramic restorations, externally applied tensile loads must counter the residual compressive stresses of the ceramic surface.
  • Chemical tempering: This is also known as ion exchange or ion stuffing, where the exchange of different sized ions at the outer ceramic surfaces yields residual compressive stresses as the larger ions swap those of smaller sizes. This is achieved via the immersion of the LSC in a molten potassium nitrate (KNO3) salt bath; smaller-sized ions on the LSC surface (e.g., Na+ and Li+) are substituted by larger ions in the salt bath (e.g., K+). The resultant chemically tempered ceramics are electroneutral by virtue of the equivalent counter ion flux diffusion (Figure 7) [43,46,47].

5. Fabrication Methods

Currently, various LSC dental restorations can be fabricated via one of the following methods.

5.1. Heat Pressing

Also known as injection moulding, this method utilises the lost wax technique in which a wax model of an LSC restoration is embedded in gypsum materials to create a mould. Subsequently, LSC ingots are heated to a temperature at which they melt into a highly viscous liquid, allowing them to be pressed/injected into the lost wax mould cavity. This fabrication method allows the production of full-contour restorations as well as frameworks designed to be veneered with feldspathic porcelain. The benefit of this technique is its resemblance to and familiarity with the lost wax method used to produce metal castings, therefore minimising potential laboratory mishaps [48,49].

5.2. CAD-CAM Technology

This method is conducted throughout three main processes:
  • Data acquisition: The prepared abutment teeth and their surrounding tissues are recorded indirectly via conventional dental impressions or directly through virtual impressions [50,51];
  • Data processing and computer-aided design: Software programs transfer the acquired data to a processing centre, and the desired restoration is created [50,51,52] with the aid of software tools such as smile design, tooth form libraries, colour shade matching and jaw tracking programs [53];
  • Computer-aided manufacturing: Upon finalising the LSC restoration design, it can be manufactured via subtractive (SM), additive (AM) or hybrid SM and AM mechanisms.

5.2.1. Subtractive Manufacturing

Herein, the LSC block (partially or fully sintered) is fixed onto a workpiece and a milling drill (spindle) subtracts from the material to create the desired restoration. Subtractive manufacturing is executed by a computer numeric-controlled (CNC) milling machine with a series of successive commands regarding the milling tool type, path and speed, as regulated by the thickness and morphology of the desired restoration. Within most CNC milling systems in dentistry, milling burs operate along 3 or 4 defined axes, with 5-axis milling machines being less common (Figure 8):
Three-axis devices function within XYZ spatial paths; the workpiece moves horizontally in the X-axis (left/right) and Y-axis path (forward/backward), and the spindle moves vertically along the Z-axis (up/down). These systems require minimal control and can fabricate restorations in a short milling time with low costs; hence, they are the most popular in dental clinics. However, internal fit and marginal adaptation are frequent concerns. Four-axis milling devices have an additional rotational axis: an A-axis, which pertains to the X-axis, allowing the workpiece to move in a pendulum-like fashion, thereby exposing greater surfaces to be milled by the spindle and allowing access to the undercut areas of the restorations; nonetheless, these devices are less widespread in the dental field due to their higher costs. In terms of 5-axis milling devices, there is an added rotational axis: a B-axis, which relates to the Y-axis, in addition to the XYZA axes. The automated maturity of these systems facilitates the efficient milling of surfaces adjacent to the insertion axis with an accuracy of up to 0.01 mm; nonetheless, their large footprint and financial restraints limit their placement to external laboratories only. The indication of 3- and 4-axis systems are limited to single-unit or short-multi-unit prostheses, whereas 5-axis systems can fabricate long-span multi-unit and geometrically complex restorations [54]. Subtractive manufacturing has increasingly gained popularity within the last decade; however, milling-induced strength-limiting surface flaws and material wastage are significant drawbacks [53,54,55,56,57].

5.2.2. Additive Manufacturing

LSC restorations are constructed as a function of a structured passive layering technique guided by the information from the three-dimensional design data, yielding less material waste, and thus endorsing industrial sustainability. The unique software algorithms of additive manufacturing can generate multi-shade prostheses of geometric complexity. In contrast to subtractive approaches, additive manufacturing allows the fabrication of larger-sized structures with extensive surface irregularities.; therefore, it is preferred for the construction of extra-oral hard- and soft-tissue facial prostheses. This can be accomplished using seven main technologies [58,59,60]:
  • Material jetting (MJ): This is also recognised as direct inkjet printing, in which a layer of tiny droplets of the print material (i.e., ink) are selectively deposited onto a build platform, where the latter is heated or exposed to ultraviolet (UV) radiation to the facilitate immediate photopolymerisation of the jetted layer ink before the subsequent ink layer is added. Ceramic particles can be suspended into water, organic solvents or wax solutions to create the ceramic ink needed to fabricate dental restorations via the material jetting method.
  • Vat polymerisation (VP): This entails the selective photocuring of radiation-sensitive liquid polymers contained within a tank (i.e., vat). This is the most frequently used additive method for fabricating dental ceramics, wherein ceramic suspensions are developed through the incorporation of resin polymers in high concentrations within ceramics powders. VP can be further subdivided into three main technologies; stereolithography (in which a concentrated UV-laser beam is directed onto a photosensitive liquid resin generating layers of the desired object through the crosslinking of the polymers), digital light processing (a digital UV screen simultaneously deposits and photocures an entire layer of photopolymerisable liquid) and continuous liquid interface production (a vat with transparent base serves as an oxygen-permeable window, where resin polymerisation is prevented and can flow freely, creating continuous printed material rather than layered material).
  • Binder jetting (BJ): Binding liquid agents and powder print materials are deposited in alternating layers to create the final build, and the binder acts as an adhesive between powder layers. Layer-wise slurry deposition is a variant of BJ that uses a ceramic slip instead of dry powder.
  • Material extrusion (ME): This is also known as fusion deposition modelling, direct ink writing or robocasting, wherein a heated nozzle contains a thermoplastic filament that is melted into an ink and deposited in layers to generate the 3D object. The fabrication of LSCS via ME is achieved by using a ceramic slurry—composed of chemically or heat-bonded ceramic particles—as the ink material.
  • Powder bed fusion (PBF): In this process, a powdered material is selectively melted and fused via laser or electron beams to fabricate the final product. This method can be further subdivided into the following: selective laser sintering, selective laser melting and electron beam Melting. This method has not been successful in fabricating LSC restorations, due to the laser-induced cracks that result from drastic temperature fluctuations.
  • Sheet lamination (SL): In this process, multiple layered sheets of the build are superimposed, laminated and then cut into the final shape using lasers or CNC milling devices.
  • Direct energy deposition (DED): Deposited materials are concurrently melted and fused via focused thermal energy into their final morphologies. Based on the type of thermal energy employed (focused electron beam or focused laser), this method is further divided into laser engineering net shape or electron beam additive manufacturing, respectively.
In general, dental 3D printers function within an XYZ axis system; the X-, and Y-axes control the horizontal movement of the build platform, while the Z-axis controls the vertical movement of the applied nozzle; hence, the latter determines the layer’s thickness. The additive manufacturing of LSCs is in its nascent phase, as the unique composition of the ceramics and their heat sensitivity permit them to be fabricated with MJ, VP, BJ, MJ, PBF and DED technologies only [57,60,61].
In order to incorporate LSC material within the feedstock supply, a ceramic powder must be first obtained through calcination or ball milling; subsequently, the powder is mixed with binders/additives into a ceramic slurry that is fed as a printing ink into the manufacturing device and that forms the shaped ceramic with the desired anatomy, i.e., a green body. Upon debinding, the binder burns out and the green body is consolidated into a brown body; the latter is heated in a furnace to promote the complete crystallisation of the ceramic microstructure and achieve a densely sintered body [62]. AM has proven its significant potential in fabricating LSC crowns of high density, thereby yielding improved biaxial flexural strength and reliability as well as fracture toughness and hardness values comparable to those of LSC fabricated via traditional heat pressing methods [63]. Furthermore, recent research data regarding additively manufactured glass products have demonstrated promising efficiency in printing multi-material, multi-scale, and multi-functional glass products, and these could be suggested as the research trends for the 3D printing of LSC restorations in the future [64]. The surface accuracy and internal fit of additive manufacturing-fabricated LSCs is impacted by the print material composition and thickness of the print layers. Nonetheless, the layering in additive manufacturing could result in staircase morphologies that alter the surface texture, hence dictating the need for further finishing and polishing. Unfortunately, the inherent porosities of restorations and the prolonged durations of drying, de-binding and sintering have not been resolved and diminish the appeal of fabricating LSC restorations with additive manufacturing [4,55,56,60,65].

6. Properties

6.1. Biocompatibility

Broadly speaking, LSCs are considered to be among the most biocompatible biomaterials in dentistry based on their high resistance to structural degradation in erosive and corrosive environments. To date, there is an absence of clinical reports of allergic reactions or long-term adverse biological effects of LSCs on tooth structure or surrounding soft tissues [66,67,68,69,70]. ZLS have been deemed biocompatible by the North American Science Associates standards of cytotoxicity, genotoxicity and systemic toxicity [71]. Polished ZLS surfaces present a more homogenous topography in comparison with glazed surfaces, thereby inciting less biofilm accumulation and indicating the promising potential of the former for implant-supported restorations with subgingival margins [72]. Furthermore, polished ZLS surfaces reveal lower bacterial adhesion and plaque formation than polished LDS ceramics do [73]. Data regarding ZLS biocompatibility in terms of cellular adhesion are scarce; ZLS has been shown to yield lower human periodontal ligament stem cell adhesion than LDS has [74], and lower human gingival fibroblast proliferation than yttrium-stabilised tetragonal zirconia has [75]. Unfortunately, to date, in vitro studies evaluating the ALDs’ biocompatibility and cytotoxicity are non-existent, excluding manufacturer-supplied safety data sheets.

6.2. Mechanical Properties

In general, the brittle nature of LSCs provides high resistance to compressive stresses and poor resistance to tensile/shear stresses, and the increase in crystalline content is accompanied by an increase in strength and fracture toughness [38,76]. The hardness of LSCs is higher than that of the tooth structure; hence, it may be a cause of detrimental wear in contrast to resin composite restorations [77,78,79,80]. In comparison with leucite reinforced glass-ceramics, LSCs demonstrate superior mechanical properties, allowing them to be applied in high-occlusal-stress-bearing areas [76,81,82]. Studies regarding ZLS restorations have reported high fracture resistance surpassing masticatory occlusal forces, feldspathic ceramics, polymer-infiltrated ceramic networks (PICNs) and bilayered ceramic-veneered zirconia restorations [83,84,85]. Moreover, ZLS yield adequate flexural strength and fracture toughness values comparable to those of LDS and higher than those of feldspathic ceramics and PICNs [5,22,83]. Wear rates of ZLS (Celtra Duo, Denstply Sirona, Salzburg, Austria) have been shown to not be statistically different from those of dental enamel after artificially induced chewing cycles; nonetheless, the reduced wear rate of fully crystallised ZLS has been noted upon glaze firing [86]. ZLS have demonstrated exceptionally low reliability (i.e., a low Weibull modulus), implying the presence of widely distributed material-dependent strength-limiting defects within their microstructure, ostensibly a result of a thermal mismatch between glass and crystalline phases [22]. Regarding ALDs, some studies have reported similar mechanical strengths to those of LDS and inferior mechanical strengths compared with those of ZLS and zirconia [87,88], while others have reported on the inferior mechanical performance of ALDs compared with that of ZLS or LDS [89,90]. Nonetheless, despite their high crystalline content, ALDs have low fracture toughness [4,5] which is attributed to their nano-scale crystal sizes. In terms of marginal adaptation and the trueness of internal fit, both the ZLS and ALD materials have demonstrated acceptable accuracy and internal adaptation within the required clinical values, and thus have proven to be comparable to those of LDS materials [91,92,93,94,95].

6.3. Optical Properties

The chemical composition, crystalline type and crystalline phase of LSCs have been shown to influence their optical properties, e.g., increased crystalline density decreases light transmission and thereby increases opacity. Furthermore, greater translucency is found in LSCs with smaller crystals and when similar refractive indices exist between glass and crystalline phases [96]. The type and shade of cementing agent, surface treatments, substrate thickness, surface texture and ageing all play a crucial role in the final colour of a restoration [97,98,99,100]. LSCs are accessible in a wide range of shades and translucencies; shades are regulated in the manufacturing process by incorporating pigmenting oxides within the glass matrix, while translucency is regulated via the nano-scaling of crystals [7]. Most products are available in four translucency levels: high translucency (HT), medium translucency (MT), low translucency (LT) and high opacity (HO). Partially crystallised LSC HT blocks contain numerous large-size lithium metasilicate crystals while LT blocks comprise an abundance of smaller crystals [101]. Studies have reported that ZLS restorations demonstrate higher translucency than RNCs, PICNs, feldspathic ceramics, LDS and monolithic zirconia [12,101,102,103], which is attributed to the smaller silicate crystals and thereby the higher glassy matrix percentage. Conversely, other studies [104] have stated that ZLS exhibit lower translucency and higher opalescence in comparison with LDS and resin-matrix ceramics, which could be explained by the higher amount of oxides in the former. The translucency of ALD materials is equivalent to that of LDS and ZLS, and is significantly impacted by ageing, glaze treatments and the colour of the underlying substrate [88,105,106].

7. Surface Treatments of LSCs

Mechanical, optical and topographical characteristics of LSC restorations depend on the conditioning treatments applied to the external or internal (intaglio) surfaces.

7.1. Intaglio Surface Treatments

LSC intaglio surfaces must be roughened to amplify the surface area, thereby facilitating luting cement retention and optimising the strength of the bond to the tooth substrate. Nonetheless, extensive alterations to the internal surfaces could be damaging, as they lead to unfavourable glassy matrix removal and grain pull-out, causing adverse volumetric loss that could weaken the LSC [107]. Various chemical, mechanical and chemo-mechanical approaches have been employed to increase the micromechanical retention of LSC substrates.

7.1.1. Mechanical Surface Treatments

  • Airborne particle abrasion: Sandblasting with alumina oxide or silica oxide particles creates surface alterations that are determined by the size, hardness, pressure, incident angle and velocity of abrading particles and the distance between the substrate and sandblasting nozzle. Since sharp edges of alumina particles chip away weaker glassy phases creating microcracks, this method could have a degrading impact on LSCs with high glass contents [108,109].
  • Laser irradiation: Heat introduction by a laser creates conchoidal (scalloped) defects within LSC surfaces, promoting the micromechanical retention needed for bonding. Erbium: yttrium aluminium garnet laser is commonly employed [110,111], as is CO2 laser, to treat LSC surfaces, owing to their complete absorption of CO2 wavelengths [112]. Recently, femtosecond laser treatments have been explored to treat LSC surfaces, wherein ultrashort optical pulses are generated per femtosecond, producing micro-retentive topographical changes [113].

7.1.2. Chemical Surface Treatments

  • Hydrofluoric acid etching: The etching of LSC restorations is most frequently performed using buffered hydrofluoric acid (HF), since the unbuffered version of HF is highly caustic; most HF etching products offered in the dental market are buffered down to 5% or 10% concentrations through the addition of an ammonium fluoride (NH4F) buffering agent. HF reacts with silica in the glassy matrix, yielding a tetrafluorosilane compound (SiF4), succeeded by a hexafluorosilicate complex ([SiF6]−2) and subsequently soluble hydrofluorosilicic acid (H2[SiF6]) that is washed away along with the glassy matrix, hence exposing the underlying crystalline network (Figure 9) and providing the retention needed for LSC cementation [69,107,114,115].
Prosthesis 06 00034 g009
Figure 9. Schematic depiction of LSCs’ crystalline structure (a) before and (b) after etching with HF.
Figure 9. Schematic depiction of LSCs’ crystalline structure (a) before and (b) after etching with HF.
Prosthesis 06 00034 g009
4 HF + SiO2 → SiF4 + 2 H2O
2 HF + SiF4 → [SiF6]−2 + 2 H+
[SiF6]−2 + 2 H+ → H2SiF6
X-ray photoelectron spectroscopy (XPS) of superficial atomic layers of etched LSC nano-surfaces (≤4 nm) [116] has verified that the HF mechanism of action is actually two-fold; it causes the dissolution of the glassy matrix, and alters the chemical composition of LSCs at a nano-level. LSCs with higher crystalline densities demonstrate lower HF-induced SiO2 dissolution, as evident from the percentage of SiO2 remaining in LSC surfaces post-etching; 18.3% SiO2 was found in IPS e.max CAD (Ivoclar Vivadent, Schaan, Liechtenstein) and 9.1% was found in Celtra Duo (Dentsply Sirona, Salzburg, Austria) [116]. Conversely, the complete dissolution of SiO2 glass has been seen in etched VITA Suprinity (VITA Zahnfabrik, Bad Säckingen, Germany) and n!ce (Straumann, Basel Switzerland) nano-surfaces [116]. The microscopic evaluation of etched LSC surfaces has revealed elongated crystals distributed among shallow irregularities (Figure 10), in contrast to etched leucite ceramics surfaces that display a characteristic honeycomb-like appearance [114].
The differences between etching patterns are caused by lithium disilicate crystals’ greater resistance to HF dissolution compared with that of SiO2 as twice the HF concentration is needed to dissolve a single lithium disilicate molecule.
Li2Si2O5 + 14 HF → 2 LiF + 2 H2SiF6 + 5 H2O
Variations in the Li content (atomic%) of nano-layers post-etching are explained by the differing Li:Si ratios in LSCs; a low ratio indicates minimal Li within the glassy matrix, such as in IPS e.max CAD (1:5.75) and in n!ce (1:5.49), whereas a higher ratio implies a lithium-rich glassy matrix, such as in Celtra Duo (1:1.84) and VITA Suprinity (1:2.41) [113]. Many different LSC etching protocols have been investigated in the literature, exploring the effect of etching durations as well as etchant concentration [98,117,118,119,120,121,122,123,124,125,126]. In general, etching LSCs had a negative impact on their flexural strength [98,119,120,127]. Moreover, etching with pre-heated HF (50–70 °C) yielded higher bond strengths compared with etching with room-temperature HF [124,125,126].
  • Acid etching with HF substitutes: Owing to the toxic and corrosive potential of HF as a result of its low dissociation constant, it can easily penetrate dermal, epidermal and mucosal tissues entering into the blood stream; however, its slow interaction with nerve endings delays the burning sensation. Hence, HF must be handled with utmost caution in extra-oral conditions, only with adequate ventilation and protective gear [107,128]. Attempts in minimising occupational hazards with HF have led to the exploration of alternative etching modalities with agents of reduced acidic capacities:
    • Phosphoric acid: Theoretically, etching with phosphoric acid (35–40%) should create LSC morphological modifications; however, microscopic evaluations reveal surfaces minimally altered by phosphoric acid post-etching in comparison with the use of HF and a weaker bond strength [107,129].
    • Acidulated phosphate fluoride (APF): This is composed of 1.23% fluoride ions derived from sodium fluoride and hydrofluoric acid that become acidified through the addition of phosphoric acid. APF has proven to be a more efficient etchant for leucite-based ceramics than for LDS, due to the faster crystalline dissolution rate in the former [130], with greater bond strengths reported upon longer APF etching durations [107].
    • Ammonium bifluoride (ABF): Herein, a linear etching pattern is formed due to the targeted action of ABF on grain boundaries and pre-existing cracks within LSCs, reacting with the silica matrix and generating silicon tetrafluoride and ammonium fluoride:
      4 NH4HF2 +SiO2 → SiF4 + 4 NH4F + 2 H2O
      As ABF is less toxic than HF, longer etching times are required to create etching patterns similar to those of HF of similar concentrations. While etching with ABF results in adequate bonding strengths, it is mainly used as an intermediate for fabricating HF [107,131].
    • Ammonium polyfluoride (AP): This is provided within the composition of self-etching ceramic primers (SEP), serves as a silane coupling agent stabiliser and, despite its notably low acidity, has been shown to create sufficient micro-retentive etching patterns in LSCs [132,133] (Figure 11) and reliable adhesion to the tooth substrate [134,135].
  • Acid neutralisation: Alkaline agents such as calcium gluconate, sodium bicarbonate and calcium carbonate have been used to neutralise the acidity of LSC surfaces caused by HF residues through an acid–base reaction that produces sodium fluoride and calcium fluoride salts and that arrests further etching by HF residues by generating adverse topographical changes (Figure 12) [136,137,138,139,140,141].
    HF + Na2CO3 + Ca2CO3 → NaF + CaF2 + H2CO3
There is contradicting evidence in the literature concerning the impact of acid neutralisation on mechanical and optical traits of ceramics and the strength of their bonding to resin cements. Several studies have observed that neutralising etched ceramic surfaces improves their wettability [89,142] and bond strengths [136,143], while others [140,144] have refuted this observation, claiming that precipitated salts interfere with adequate resin cement penetration and subsequent bonding.
  • Salinisation: Silanes comprise a γ-methacryloxypropyltrimethoxysilane molecule that enables bonding between LSC and resin surfaces via its bifunctional monomers; the alkoxy group (methacryloxy, Si-O-CH3) reacts with the LSCs hydroxyl group (-OH), forming silanol (Si-OH), and, on the silane monomer end, a methacrylate group (C=C) reacts with the organic-matrix monomers of the resin, resulting in a bridging siloxane compound (-Si-O-Si-O-) (Figure 13) that improves LSC wettability and resin penetration [107,109,145]. To achieve the optimal bonding effects of a silane coating, LSCs must be pre-treated, e.g., etched, to increase their roughness [107].
  • Plasma treatment: When low-temperature atmospheric-pressure plasma is applied to LSCs, it acts at a molecular level without violating bulk integrity, thereby decontaminating LSCs and increasing their surface energy. Moreover, the dry conditions in which plasma treatment is carried out eliminate the risk of strength-limiting hydrolytic damage, yielding sufficient bond strength values for LSCs bonding to resin cements [146,147,148].
  • 10-methacryloyloxyidecyl-dihydrogenphosphate application (10-MDP): 10-MDP is a phosphate ester monomer found in primers as well as resin cements that can chemically react with zirconia by forming a bond with its hydroxyl groups. It has displayed promising bonding performance when used following the silanisation of HF-etched ZLS surfaces [149,150].

7.1.3. Chemo-Mechanical Surface Treatments

LSC silanisation is facilitated via tribochemical silica-coating, “silicatisation”, through a three-fold mechanism: Al2O3 particle airborne abrasion, silica-coated Al2O3 particle airborne abrasion and silanisation (Figure 14) [151,152,153,154]. Upon contact with LSC surfaces, the kinetic energy of silica-coated Al2O3 particles is transferred into thermal energy, thereby melting the silica coating and fusing the former with the LSC surface, creating surfaces that are susceptible for silane chemical interactions and, consequently, improving the strength of bonding to the resin luting agents.

7.2. External Surface Treatments

It is necessary to implement adequate intra-oral finishing and polishing regimens after intra-oral adjustments are made to LSCs to yield a degree of clinically acceptable surface smoothness [155,156]. Finishing and polishing can be executed lab-side or chairside and the efficacy depends on various parameters such as the abrasive particle size, hardness and shape, applied velocity and pressure, and the LSCs hardness and microstructure. The glazing of LSCs can be accomplished by over-glazing, in which low-fusing glass coating is applied and fired at lower temperatures (~700 °C) or via auto-glazing (self-glazing), where a superficial layer of unfilled glass is created upon heating LSCs at a maximum temperature (~940 °C) [157]. Glazing pastes, powder–liquid mixtures or sprays are commonly employed in the over-glazing method, all of which comprise a wide range of chemical compositions, some with added pigments or fluorescent agents, applied before the crystallisation of LSC restorations to facilitate simultaneous glazing and crystallisation [158] Firing and cooling protocols of LSCs also play a significant role in their optical and mechanical performance, as altering the temperature gradients gives rise to residual stresses within the surface and bulk of LSC structures [159].

8. Discussion and Conclusions

In terms of LSC restoration longevity, success rate is a measure of their endurance in situ without the need for any interventions, survival rate is a measure of on-site permanence despite the presence of clinically acceptable complications that may or may not involve further amendments and failure rate is a measure of the technical, biological or aesthetic complications that dictate the replacement of the restoration (e.g., fracture, marginal discrepancy, debonding and discolouration) [160]. Multiple long-term studies have confirmed the high success rate of lithium silicate ceramic restorations [161,162,163,164,165,166,167]; however, owing to the recent availability of ZLS and ALD materials in the dental market, there is a lack of long-term systematic data in terms of clinical longevity. Unfired fully crystallised ZLS crowns (Celtra Duo, Dentsply Sirona, Salzburg, Austria) revealed high fracture rates (26%) after one year of clinical function [168], whereas when the same material was exposed to glaze firing, it exhibited a high success rate (98%) after 3 years [169]. Conversely, others [170] reported similar failure rates in unfired and fired ZLS materials after one year of clinical use. Moreover, a 5-year prospective clinical trial of ZLS partial crowns (VITA Suprinity, VITA Zahnfabrik, Bad Säckingen, Germany) showed a success rate of 80% and a 91% survival rate [171]. In general, failure rates of chairside-fabricated ZLS crowns within the first 3 years are comparable to those of lithium disilicate materials with similar clinical durations [172]. In terms of pressable ZLS, the 2-year clinical performance of implant- and tooth-supported three-unit FPD’s revealed that complications were mainly due to shade mismatches (7%) and less likely to be mechanical failures (1%) [173]. Limited in vitro studies have investigated the longevity of ALD restorations; a clinical study followed the one-year clinical performance of restorations fabricated from Cerec Tessera (Dentsply Sirona, Salzburg, Austria) and reported a 100% success rate [174]. On the other hand, others have observed the clinical survival of implant-supported monolithic crowns fabricated from n!ce (Straumann, Basel Switzerland) after 33 months and reported a 80.2% success rate. Nevertheless, similar outcomes have been reported for predrilled blocks compared with those of blocks that were manually drilled prior to their sintering [175].
The appealing aesthetics and sufficient strength of LSCs have significantly contributed to their popularity in both the material development sector as well as the clinical application sector. Nonetheless, certain material limitations remain, considering that the mechanical requirements of LSC dental materials still cause them to be inadequate in delivering the strength needs of multiunit prostheses within the molar region [176]. Recently, in vitro experimentations of LSCs have explored the effects of the incorporation of lithium tantalate (LiTaO3) and lithium niobate (LiNbO3) precipitations within the crystalline phase composition [8,9,10] on the radiopacity and hardness, wherein authors concluded positive findings. Furthermore, novel LSC coatings such as DCMHotbond that are applied in thin layers (<20 µm) on the zirconia fitting surface permitting HF etching and subsequent salinisation should, in theory, yield higher bond strengths. However, the technical sensitivity of this approach and concerns about the thickness and durability of the coating layer have not yet been resolved [11,12,13].
The improvement of LSCs in terms of dentistry via 3D printing should focus on optimising material composition and printability, refining the surface finish and detail, and enabling customisation for patient-specific needs. Enhancements in additive manufacturing could be tailored to focus on mechanical properties, biocompatibility and longevity. Furthermore, the long-term cost-effectiveness and scalability of these materials are essential considerations for the wider adoption of 3D-printed LSC restorations.

Author Contributions

Conceptualisation, H.A.-J.; methodology, H.A.-J. and J.H.; software, H.A.-J.; validation, H.A.-J., J.H., N.S. and J.S.; formal analysis, H.A.-J. and J.H.; investigation, H.A.-J.; resources, H.A.-J.; data curation, H.A.-J.; writing—original draft preparation, H.A.-J.; writing—review and editing, H.A.-J., J.H., N.S. and J.S.; visualisation, H.A.-J. and J.H.; supervision, J.H., N.S. and J.S.; project administration, J.S. and N.S.; funding acquisition, H.A.-J. All authors have read and agreed to the published version of the manuscript.

Funding

The first author (HA) was funded by a full time scholarship provided by the Saudi Arabian Cultural Bureau in London, UK. The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data presented in this study are available on request from the corresponding author.

Acknowledgments

The authors acknowledge the contribution of Hayley Andrews (Faculty of Science and Engineering, Manchester Metropolitan University) for the experimental work on scanning electron microscopy.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Molecular representation of (a) lithium disilicate, (b) lithium metasilicate and (c) cristobalite.
Figure 1. Molecular representation of (a) lithium disilicate, (b) lithium metasilicate and (c) cristobalite.
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Figure 2. Molecular representation of nucleating agents: (a) zirconia and (b) diphosphorus pentoxide.
Figure 2. Molecular representation of nucleating agents: (a) zirconia and (b) diphosphorus pentoxide.
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Figure 3. Molecular representation of spodumene.
Figure 3. Molecular representation of spodumene.
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Figure 4. Melting casting crystallisation manufacturing method; raw minerals (a) are milled into fine powders (b), mixed, then heated into a molten state (c), quenched and cast within a mould (d), slowly annealed (e) to form a precursor glass (f), re-heated to illicit nucleation, (g) re-heated a second time to active crystallisation kinetics (h) and finally cooled slowly to obtain a glass ceramic with optimum properties (i).
Figure 4. Melting casting crystallisation manufacturing method; raw minerals (a) are milled into fine powders (b), mixed, then heated into a molten state (c), quenched and cast within a mould (d), slowly annealed (e) to form a precursor glass (f), re-heated to illicit nucleation, (g) re-heated a second time to active crystallisation kinetics (h) and finally cooled slowly to obtain a glass ceramic with optimum properties (i).
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Figure 5. LSC intrinsic strengthening mechanisms: (a) crack tip deflection, (b) crack tip shielding, (c) grain bridging, (d) fibre bridging, (e) microcracks, (f) crack branching and (g) transformation toughening.
Figure 5. LSC intrinsic strengthening mechanisms: (a) crack tip deflection, (b) crack tip shielding, (c) grain bridging, (d) fibre bridging, (e) microcracks, (f) crack branching and (g) transformation toughening.
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Figure 6. Thermal tempering of a ceramic restoration (a), placed in a furnace, initially heated to a temperature between its Ts and Tg (b), and then cooled rapidly via assisted forced air cooling (c). The final tempered ceramic has two-fold residual stresses: outer compressive stresses (blue arrows) and inner tensile stresses (orange arrows) (d).
Figure 6. Thermal tempering of a ceramic restoration (a), placed in a furnace, initially heated to a temperature between its Ts and Tg (b), and then cooled rapidly via assisted forced air cooling (c). The final tempered ceramic has two-fold residual stresses: outer compressive stresses (blue arrows) and inner tensile stresses (orange arrows) (d).
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Figure 7. Chemical tempering of a lithium-based ceramic restoration composed of small-sized Na+ and Li+ ions within its silicate network (a). The ceramic is heated (T < Tg) within a salt bath saturated with large-sized K+ ions (b). An Ion exchange proceeds as Na+ and Li+ ions are replaced with K+ ions; the latter generates favourable compressive stresses throughout the silicate framework that retard the propagation of pre-existing crack (c).
Figure 7. Chemical tempering of a lithium-based ceramic restoration composed of small-sized Na+ and Li+ ions within its silicate network (a). The ceramic is heated (T < Tg) within a salt bath saturated with large-sized K+ ions (b). An Ion exchange proceeds as Na+ and Li+ ions are replaced with K+ ions; the latter generates favourable compressive stresses throughout the silicate framework that retard the propagation of pre-existing crack (c).
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Figure 8. Depiction of the axis orientation in subtractive manufacturing; the milling bur moves along the Z-axis, whereas the LSC block moves along the X-, A-, Y- and B-axes.
Figure 8. Depiction of the axis orientation in subtractive manufacturing; the milling bur moves along the Z-axis, whereas the LSC block moves along the X-, A-, Y- and B-axes.
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Figure 10. FE-SEM image (×20,000) of an LSC (Celtra Duo, Dentsply Sirona, Salzburg, Austria) following etching with 9% hydrofluoric acid for 30 s.
Figure 10. FE-SEM image (×20,000) of an LSC (Celtra Duo, Dentsply Sirona, Salzburg, Austria) following etching with 9% hydrofluoric acid for 30 s.
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Figure 11. FE-SEM image (×20,000) of an LSC (Cerec Tessera, Dentsply Sirona, Salzburg, Austria) following etching with a self-etch primer (Monobond Etch & Prime, Ivoclar Vivadent, Schaan, Liechtenstein) under 20 s of active application with a microbrush and then 40 s of passive application.
Figure 11. FE-SEM image (×20,000) of an LSC (Cerec Tessera, Dentsply Sirona, Salzburg, Austria) following etching with a self-etch primer (Monobond Etch & Prime, Ivoclar Vivadent, Schaan, Liechtenstein) under 20 s of active application with a microbrush and then 40 s of passive application.
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Figure 12. FE-SEM image (×20,000) of LSC (Celtra Duo, Dentsply Sirona, Salzburg, Austria) after etching with 5% hydrofluoric acid for 30 s and immersion in a neutralising solution for 1 min.
Figure 12. FE-SEM image (×20,000) of LSC (Celtra Duo, Dentsply Sirona, Salzburg, Austria) after etching with 5% hydrofluoric acid for 30 s and immersion in a neutralising solution for 1 min.
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Figure 13. Depiction of the formation of the bridging siloxane compound (-Si-O-Si-O-) as a result of chemical interactions between the silane coupling agent and the etched silicate surfaces. The methacrylate group (C=C) at the monomer end of the silane coupling agent reacts with the luting agent’s organic matrix monomers via the breaking of its double bonds (dashed blue circle). Modified from Benetti et al. [145].
Figure 13. Depiction of the formation of the bridging siloxane compound (-Si-O-Si-O-) as a result of chemical interactions between the silane coupling agent and the etched silicate surfaces. The methacrylate group (C=C) at the monomer end of the silane coupling agent reacts with the luting agent’s organic matrix monomers via the breaking of its double bonds (dashed blue circle). Modified from Benetti et al. [145].
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Figure 14. Schematic representation of tribochemical silica coating: (a) Silica (orange)-coated alumina particles (grey) approaching zirconia surfaces. (b) Upon contact with zirconia surfaces, alumina particles’ kinetic energy is converted into thermal energy that melts and fuses the silica coating with the zirconia substrate. (c) Most alumina particles are removed completely (left); however, some alumina fragments and unfused silica particles remain (right). Modified from Nagaoka et al. [154].
Figure 14. Schematic representation of tribochemical silica coating: (a) Silica (orange)-coated alumina particles (grey) approaching zirconia surfaces. (b) Upon contact with zirconia surfaces, alumina particles’ kinetic energy is converted into thermal energy that melts and fuses the silica coating with the zirconia substrate. (c) Most alumina particles are removed completely (left); however, some alumina fragments and unfused silica particles remain (right). Modified from Nagaoka et al. [154].
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Table 1. Composition, flexural strength and clinical indications of pressable lithium silicate-based ingots as published by representative manufacturers.
Table 1. Composition, flexural strength and clinical indications of pressable lithium silicate-based ingots as published by representative manufacturers.
Ceramic TypeProduct Name, Manufacturer (Launch Date)Chemical
Composition (wt%)		Flexural Strength
(MPa)		Clinical
Indications
Lithium-
disilicate
(Li2Si2O5)		IPS e.max® Press, Ivoclar Vivadent, Schaan,
Liechtenstein (2005)		SiO2 (57.0–80.0), Li2O (11.0–19.0), K2O (<13.0), P2O5 (<11.0) ZrO2 (<8.0), ZnO (<8.0), colouring oxides (<12.0)470Inlays, onlays,
veneers, crowns,
3-unit FPDs up to 2nd premolar,
implant-supported crowns
InitialTM LiSi Press, GC Corp., Tokyo, Japan (2016)SiO2 (71.0), Li2O (13.0), Al2O3 (5.4), Na2O (1.4), K2O (2.0), P2O5 (2.6), ZrO2 (1.7), B2O3 (0.007), CeO2 (1.2), V2O5 (0.15), Tb2O3 (0.35), Er2O4 (0.4), HfO2 (0.03)508Inlays, onlays, veneers, anterior and posterior crowns, implant crowns, 3-unit FPDs on teeth or implants up to 2nd premolar
Amber® Press, HASS Corp., Gangwon State, Korea (2020)SiO2 (<78), Li2O (<12), colouring oxides (<12)460Inlays, onlays, veneers, anterior and posterior crowns, 3-unit FPDs on teeth up to 2nd premolar
Livento Press, Cendres + Métaux, Biel/Bienne, Switzerland (2019)SiO2 (65–80), Al2O3 (<11), Li2O (11–19), K2O (<7), Na2O (<5), CaO (<10), P2O5 (1.5–7), ZnO (<7), others (<15)300Inlays and onlays, veneers, partial crowns, anterior and posterior crowns, hybrid abutment crowns, 3-unit anterior and posterior bridges up to 2nd premolar
Zirconia
reinforced lithium
silicates (Li2SiO3/Li2Si2O5)		Celtra® Press, Dentsply Sirona, Salzburg, Austria (2017)SiO2 (58), Li2O (18.5), ZrO2 (10.1), P2O5 (5), Al2O3 (1.9), CeO2 (2), Tb4O7 (1)>500Inlays, onlays, veneers, anterior and posterior crowns, 3 unit anterior bridges
VITA
AMBRIA®, VITA Zahnfabrik, Bad Säckingen, Germany (2021)		SiO2 (58–66), Li2O (12–16), Al2O3 (1–4), K2O (1–4), P2O5 (2–6), ZrO2 (8–12), B2O3 (1–4), CeO2 (<4), V2O5 (<1) Tb2O3 (1–4), Er2O4 (<1), Pr6O11 (<1)400Inlays, onlays, veneers, anterior and posterior crowns, implant crowns, 3-unit FPDs on teeth or implants up to 2nd premolar
Table 2. Composition, flexural strength and clinical indications of CAD/CAM lithium silicate-based blocks as published by representative manufacturers.
Table 2. Composition, flexural strength and clinical indications of CAD/CAM lithium silicate-based blocks as published by representative manufacturers.
Ceramic TypeProduct Name, Manufacturer (Launch Date)Chemical
Composition (wt.%)		Flexural Strength
(MPa)		ProcessingClinical
Indications
Lithium-
disilicate
(Li2Si2O5)		IPS e.max® CAD, Ivoclar Vivadent, Schaan, Liechtenstein (2006)SiO2 (57.0–80.0), Li2O (11.0–19.0), K2O (<13), P2O5 (<11), ZrO2 (<8.0), ZnO (<8.0), Al2O3 (<5.0), MgO (<5.0), pigments (<0.8)360 ± 40Two-stepInlays, onlays, veneers, anterior and posterior crowns, 3-unit FPDs up to 2nd premolar, implant supported crowns
Rosetta SM, HASS Corp., Gangwon State, Korea (2013)SiO2 (<78), Li2O (<120, colouring oxides (<12)400Two-stepInlays, onlays, veneers, anterior and posterior crowns, 3-unit anterior FPDs
Amber® Mill, HASS Corp., Gangwon State, Korea (2018)SiO2 (<78), Li2O (<12), colouring oxides (<12)450Two-stepInlays, onlays, veneers, anterior and posterior crowns, 3-unit FPDs (up to 2nd premolar)
InitialTM LiSi Blocks, GC Corp., Tokyo, Japan (2021)SiO2 (81), P2O5 (8.1), K2O (5.9), Al2O3 (3.8), TiO2 (0.5), CeO2 (0.6)408One-stepInlays, onlays, veneers, anterior and posterior crowns, implant-supported crowns
Lithium-metasilicate
(Li2SiO3)		Obsidian®, Glidewell Laboratories, CA, USA (2013)SiO2 (50–58), Li2O (10–20), GeO2 (1–10), K2O (2–6), P2O5 (2–4), Al2O3 (2–4), ZrO2 (2–4), others (<10)385Two-stepInlays, onlays, veneers, anterior and posterior crowns
Zirconia
reinforced lithium
silicates (Li2SiO3/Li2Si2O5)		Celtra® Duo, Dentsply Sirona, Salzburg, Austria (2013)SiO2 (58), Li2O (18.5), ZrO2 (10.1), P2O5 (5), Al2O3(1.9), CeO2 (2), Tb4O7 (1)370One-stepInlays, onlays, veneers, partial crowns, anterior and posterior crowns, implant-supported crowns
VITA Suprinity® VITA Zahnfabrik, Bad Säckingen, Germany (2013)SiO2 (56–64), Li2O (15–21), ZrO2 (8–12), P2O5 (3–8), Al2O3 (1–4), K2O (1–4), CeO2 (<4), La2O3 (0.1), pigments (<6)420Two-stepInlays, onlays, veneers, partial crowns, anterior and posterior crowns, implant-supported crowns
Lithium aluminium disilicate (LiAlSi2O6/Li2Si2O5)n!ce®, Straumann, Basel, Switzerland
(2017)		SiO2 (64–70), Li2O (10.5–12.5), Al2O3 (10.5–11.5), Na2O (1–3), K2O (0–3), P2O5 (3–8), ZrO2 (<0.5), CaO (1–2), colouring oxides (<9)350 ± 50One-stepInlays, onlays, veneers, anterior and posterior crowns, implant-supported crowns
CEREC TesseraTM, Dentsply Sirona, Salzburg, Austria (2021)Li2Si2O5 (90), Li3PO4 (5), Li0.5Al0.5Si2.5O6 (5)700Two-stepInlays, onlays, veneers, anterior and posterior crowns
Table 3. Search strategy for narrative review.
Table 3. Search strategy for narrative review.
DatabaseSearch Terms
Pubmed/
Medline		“Lithium silicate-based glass-ceramics” OR “Lithium disilicate” OR “Zirconia-reinforced lithium silicate” OR “Lithium aluminum disilicate” OR “Advanced lithium disilicate” OR “Glass-ceramics” OR “Dental ceramics” OR “dental materials” [Mesh] OR “dentistry” [Mesh] OR “CAD/CAM” [Mesh] OR “machinable lithium silicate” OR “pressable lithium silicate” OR “heat pressed lithium silicate”
Scopus “Lithium AND silicate-based AND dental AND ceramics” OR “Zirconia-reinforced AND lithium AND silicate” OR “Advanced AND lithium AND disilicate” OR “Reinforced AND lithium AND silicate” OR “CAD/CAM AND lithium AND silicate” OR “Heat AND pressed AND lithium AND silicate”
Google Scholar“Lithium silicate-based glass-ceramics” OR “Lithium disilicate” OR “Zirconia-reinforced lithium silicate” OR “Lithium aluminum disilicate” OR “Advanced lithium disilicate” OR “Glass-ceramics” OR “CAD/CAM lithium silicates” OR “machinable lithium silicate” OR “pressable lithium silicate” OR “heat pressed lithium silicate”
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Al-Johani, H.; Haider, J.; Satterthwaite, J.; Silikas, N. Lithium Silicate-Based Glass Ceramics in Dentistry: A Narrative Review. Prosthesis 2024, 6, 478-505. https://doi.org/10.3390/prosthesis6030034

AMA Style

Al-Johani H, Haider J, Satterthwaite J, Silikas N. Lithium Silicate-Based Glass Ceramics in Dentistry: A Narrative Review. Prosthesis. 2024; 6(3):478-505. https://doi.org/10.3390/prosthesis6030034

Chicago/Turabian Style

Al-Johani, Hanan, Julfikar Haider, Julian Satterthwaite, and Nick Silikas. 2024. "Lithium Silicate-Based Glass Ceramics in Dentistry: A Narrative Review" Prosthesis 6, no. 3: 478-505. https://doi.org/10.3390/prosthesis6030034

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