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Review

A Comparison of Bioactive Glass Scaffolds Fabricated ‎by Robocasting from Powders Made by Sol–Gel and Melt-Quenching Methods

Department of Materials and Ceramic Engineering/CICECO—Aveiro Institute of Materials, University of Aveiro, 3810‎-‎193 Aveiro, Portugal
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Authors to whom correspondence should be addressed.
Processes 2020, 8(5), 615; https://doi.org/10.3390/pr8050615
Submission received: 26 February 2020 / Revised: 11 May 2020 / Accepted: 16 May 2020 / Published: 21 May 2020
(This article belongs to the Special Issue Synthesis and Characterization of Biomedical Materials)

Abstract

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Bioactive glass scaffolds are used in bone and tissue biomedical implants, and there is great interest in their fabrication by additive manufacturing/3D printing techniques, such as robocasting. Scaffolds need to be macroporous with voids ≥100 μm to allow cell growth and vascularization, biocompatible and bioactive, with mechanical properties matching the host tissue (cancellous bone for bone implants), and able to dissolve/resorb over time. Most bioactive glasses are based on silica to form the glass network, with calcium and phosphorous content for new bone growth, and a glass modifier such as sodium, the best known being 45S5 Bioglass®. 45S5 scaffolds were first robocast in 2013 from melt-quenched glass powder. Sol–gel-synthesized bioactive glasses have potential advantages over melt-produced glasses (e.g., greater porosity and bioactivity), but until recently were never robocast as scaffolds, due to inherent problems, until 2019 when high-silica-content sol–gel bioactive glasses (HSSGG) were robocast for the first time. In this review, we look at the sintering, porosity, bioactivity, biocompatibility, and mechanical properties of robocast sol–gel bioactive glass scaffolds and compare them to the reported results for robocast melt-quench-synthesized 45S5 Bioglass® scaffolds. The discussion includes formulation of the printing paste/ink and the effects of variations in scaffold morphology and inorganic additives/dopants.

Graphical Abstract

1. Introduction

Robocasting is an additive manufacturing or 3D printing technique, in which designed 3D structures are built layer-by-layer by extruding a continuous filament of a paste/printing ink from a nozzle, guided by an automated computerized system (Figure 1) [1]. It was initially developed at Sandia National Laboratories in 1996 to fabricate free-formed objects with a slurry containing low levels of binder [2,3], and was rapidly adopted to manufacture periodic 3D ceramic structures [4]. Robocasting is a particularly promising technique for bone scaffold fabrication as the scaffold can be designed to specifically mimic and replace an injured or missing part of the body as a “bespoke” implant [5], with improved mechanical properties compared to older fabrication techniques [6]. In robocasting, the ink is extruded from a nozzle to construct 3D structures. The extrusion speed and scaffold shape and size are all controlled by a computer-aided design–computer-aided manufacturing (CAD–CAM) [7] model, deposited layer-by-layer as a 3D structure [8] from an ink or paste formulated from a powder with liquid and polymeric additives.
Robocasting has been used to produce porous scaffolds of calcium phosphate bioceramics for biomedical bone implants since the beginning of the 21st century [9,10], but SiO2-CaO-P2O5-based bioactive glasses have only been robocast in the last decade [11,12,13,14,15]. The best known example of a bioactive glass is Bioglass® (45S5) [16], discovered by Hench and co-workers in 1969 [17]. 45S5 is known by its commercial brands Bioglass®, PerioGlas® and NovaBone® in particulate form, and NovaMin® in toothpaste, and it contains 45 wt% SiO2, 24.5 wt% CaO, 24.5 wt% Na2O, and 6.0 wt% P2O5, with a Ca/P ratio of ~5 [17]. This high sodium content (as a glass modifier) means it is soft in comparison to other glasses and can be easily machined or ground to a powder [18], but it has to be stored in a dry environment as it readily absorbs and reacts with moisture. It has also proven difficult to fabricate as porous 3D scaffolds and sinter into a dense material, as it crystallizes at a relatively low temperature, with a small sintering window [19]. Indeed, it was not robocast successfully until 2013 [11].
An alternative preparation method to melt-quenching, which has been greatly explored for the synthesis of bioactive glasses, is sol–gel [20]. Apart from the potential to avoid unwanted crystallization during synthesis, one of the great advantages of sol–gel bioactive glasses is that the glass powder can be much more porous than that produced from a melt. This should result in a greater degree of bioactivity in any resulting implant. For example, the ternary 58S glass (containing 60 wt% SiO2, 36 wt% CaO, and 4 wt% P2O5), when produced by the sol–gel process, had a much greater specific surface area than melt-derived 45S5 (79 vs. 2.7 m2/g, respectively) [20]. Hench used sol–gel about two decades after its initial discovery to prepare 45S5 glass, which enhanced both its surface morphology and bioactivity [21,22], but this sol–gel 45S5 has never been successfully robocast to date. This is because sol–gel-derived bioactive glasses have proven problematic for robocasting, as the high specific surface area and porous structure of the glass powder results in absorption of a significant portion of the dispersing liquid from the suspension, impeding paste/ink formulation and greatly reducing printability. The first robocast sol–gel-synthesized bioactive glass scaffolds were only reported in 2019 [23,24]. These were of a quaternary high-silica sol–gel glass (HSSGG) with a low sodium composition of 64.4 wt% SiO2, 4.9 wt% Na2O, 21.5 wt% CaO, and 9.1 wt% P2O5 [24]. This glass was synthesized by an innovative rapid sol–gel synthesis route, which produced a bioactive glass powder in about 1 h—more than one hundred times faster than the quickest reported standard sol–gel methods, which require lengthy drying and ageing processes of several days to weeks [25].

2. Bone Scaffolds

Scaffolds for bone regeneration must contain interconnected pores/voids on the scale of 100 μm or more to enable cell seeding, proliferation, and vascularization (formation of blood vessels), which results in the formation of new bone [26]. The scaffold must be strong enough to replace the bone temporarily while providing a suitable substrate for cell attachment and proliferation, and it should also slowly degrade (be resorbable) and be replaced as the new tissue grows [27]. Therefore, it must be made of a bioactive and biocompatible material, which allows precipitation/crystallization of the calcium phosphate minerals (typically hydroxyapatite, Ca10(PO4)6(OH)2, HAp), which enhances the bonding between the implant and the bone, ensuring good fixation and preventing micro-movements and implant failure, and it cannot be cytotoxic to the cells [28,29].
Scaffolds are usually formed in what is known as a “wood pile” or “log-cabin” structure of extruded struts, with voids between them (Figure 2). This forms an extracellular matrix in which the cells can grow and function, and this also helps define the structural properties of the resultant tissue. The scaffold serves as a temporary template to support/guide the growth of new tissue to restore normal function, but during the healing process, the scaffold should also gradually degrade to be replaced by new cells as they grow and proliferate to regenerate new tissue [30].
As the 3D shapes are fabricated by the extrusion of a paste from a nozzle layer-by-layer, this paste, sometimes also called a printing ink, must have optimized rheological properties such as a high viscosity at zero shear and thinning behavior at applied shear. It must also have excellent shape retention capabilities, such as high elastic modulus and yield stress, after deposition and throughout the printing, drying, and sintering steps [31]. The extruded filament must retain its shape and resist the exerted loads of the subsequent layers printed above it, and casting (extrusion) can either take place in air or in a liquid medium to allow homogeneous drying. In the case of a robocast glass, the green scaffold must be dried at room temperature and then heated or sintered gradually to eliminate any organic additives to produce the final form.
To function well, a scaffold should have:
  • Biocompatibility: It must be non-cytotoxic and tissue-compatible, allowing the necessary cells to attach, differentiate, and proliferate. Any dissolved materials from the scaffold must not have any toxic/inflaμμatory influence on cells and tissues, and the body should be able to get rid of these degraded products without any side-effects.
  • Bioactivity: It must actively interact with body fluids and tissues to function, for example, crystallize new calcium phosphate minerals for bone growth. A scaffold can also be used to influence cell morphology and position, deliver growth factors to speed regeneration, or to release or trap biomolecules in a regulated manner.
  • Biodegradability: It must degrade with time (weeks/months) after implantation as it is gradually replaced by new generative tissues. It should degrade at a rate similar to that of the new tissue growth.
  • Suitable morphology and structure: It must have sufficient void/pore volume for new tissue formation and growth, needing large interconnected macropores >50–100 µm to permit cells to infiltrate easily into the scaffold core, and allow any waste to diffuse out of it. Ideally, it should also have a hierarchical degree of porosity within the scaffold struts in the size range of 2–50 µm (mesopores) to facilitate cell anchorage and proliferation, permit vascularisation, and enable nutrient/metabolite transport without compromising mechanical stability.
  • Similar mechanical properties to the host tissue: It must withstand the exerted loads, but with no stress shielding effect from a mechanical mismatch, which can cause bone resorption and implant failure. Cells have shown an ability to be sensitive to the stiffness of the scaffold, which can affect cell adhesion [32] and differentiation [33], and the scaffold needs to maintain overall mechanical integrity during the new bone formation and resorption processes [27,34].

3. Bioactive Glass

When implanted in the body, bioactive glasses such as 45S5 react with body fluid, exchanging the Na+ and Ca2+ ions on their surface with H+ ions in the fluid to hydrolyze and form Si-OH bonds, accompanied by an initial increase in pH. This creates more OH ions at the surface, which go on to break Si-O-Si bonds (forming more Si-OH bonds), dissolving the silica glass network. The Si-OH groups at the surface then recondense and re-polymerize, reforming new Si-O-Si bonds as a new silica–gel layer on the surface, which will now have a very low Na+ content. At the same time, Ca2+ and PO43− ions from both the bioactive glass and body fluid form a calcium phosphate layer on top of the silica layer. This also incorporates CO32− and OH ions from the body fluid, crystallizing a hydroxycarbonate apatite (Ca10−x−y/2(HPO4)x(PO4)6−x−y(CO3)y(OH)2−x, HCAp) layer, which, in a few hours, begins to convert to crystalline HAp, forming bone–like material [35]. Over the following weeks, M2 macrophages (which promote wound healing) attract mesenchymal stem cells and osteoprogenitor cells, which, in turn, differentiate to become bone tissue cells such as osteoblasts. Other bone components such as collagen also form, and they combine with HAp nanocrystals to form new bone, as the silica bioactive glass implant degrades, dissolves, and resorbs [36].

3.1. Bioactive Glass Synthesis Methods

Bioactive glasses are mainly produced by two techniques: Sol–gel [25,37,38,39] and melt- quenching methods [39,40,41]. Hench was a pioneer in using both of these techniques for bioactive glass synthesis. He initially used the melt-quenching technique in 1969 [17] to prepare 45S5 and used sol–gel about twenty years later to prepare the same glass, but enhancing the surface morphology and bioactivity [22]. Both methods are now commonly adopted for producing bioactive glasses.

3.1.1. Melt-Quenching Method

In the melt-quenching method, glass is obtained by mixing, homogenizing, calcining, and fusing glass precursors such as oxides or carbonates above 1300–1500 °C. After heating the mixed precursors in a platinum crucible, the melt is quenched (rapidly cooled to avoid crystallization) in cold water to obtain a glass frit, or cast/quenched in graphite molds to obtain bulk glasses [19,40,41]. This is the method typically used to obtain Bioglass® 45S5 and other commercial bioactive glasses.

3.1.2. Sol–Gel Method

In the sol–gel method, an aqueous solution of the precursors (alkoxides and/or metal salts) is stirred for hydrolysis and condensation, resulting in a clear sol. This is then dried and aged for a long period of time, often weeks [25], followed by calcination to obtain glass granules or monolithic shapes [22,42]. Sol–gel-derived bioactive glasses have high porosity in comparison to those made from melt-quenching, which generally improves their bioactivity. The minimum ideal total porosity for good bone growth in a scaffold is generally accepted to be ~50% [43]. The long aging and drying periods can be problematic and lead to unwanted crystallization, which needs to be minimized, and this long process is very much a rate limiting step for the sol–gel method.

3.1.3. Rapid Sol–Gel Method

For the reasons given above, Ben-Arfa et al. developed an innovative rapid sol–gel synthesis route for a quaternary bioactive glass system, which can produce a bioactive glass powder in about 1 h—more than one hundred times faster than the quickest reported standard sol–gel methods [25]. This involves the sequential combination of the bioactive glass precursors in an aqueous solution, followed by rapid drying on a rotary evaporator, avoiding any ageing (Figure 3). This was shown to produce stabilized (devitrified) bioactive glasses with virtually identical properties, and enhanced bioactivity, compared to those made by conventional routes.

4. Robocasting and Printing Paste/Ink Preparation

Many materials have been used to robocast scaffolds including calcium phosphate bioceramics [43,44,45] and polymer/ceramic composites [46,47]. However, the robocasting of bioactive glass scaffolds proved to be more difficult, even when using melt-quenched glass frit powders, which themselves exhibit less porosity than sol–gel bioactive glasses. The high porosity of sol–gel-derived bioactive glass powders created even greater difficulties in the paste preparation process, as a significant part of the dispersing liquid is absorbed and trapped in the pores, reducing the flow and stability of the paste/ink. Due to these issues, there have been far fewer reports on the robocasting of bioactive glass scaffolds compared to bioceramics, and this was limited entirely to glass compositions prepared by melt-quenching [48,49], until the successful robocasting of sol–gel-derived bioactive glass scaffolds was reported for the first time in 2019 by Ben-Arfa et al. [23,24].
Essential for the successful fabrication of scaffolds by robocasting are factors such as the simplicity of ink preparation, printability, and the ability of the glass composition to sinter [15]. The well-known 45S5 Bioglass® does not meet several of these requirements, as the high degree of leaching of Na+ and the abrupt increase in pH hinders an efficient dispersion, and the successful preparation of robocasting pastes of melt-quenched 45S5 glasses was only quite recently achieved [15,48]. Much of the work on the robocasting of glass scaffolds was carried out using less soluble and low-alkali glasses with broader sintering windows, such as the 13–93 composition (53 wt% SiO2, 6 wt% Na2O, 12 wt% K2O, 5 wt% MgO, 20 wt% CaO, 4 wt% P2O5) [49], but any gains in sinterability and mechanical properties were achieved at the expense of poorer bioactivity [8]. Indeed, despite over 40 years of research on bioactive glasses by many groups since Hench’s invention of 45S5, no other bioactive glass composition has been found to have significantly better biological properties than the original Bioglass® 45S5 composition [19].
The formulation of inks/pastes for robocasting from bioactive sol–gel glasses is even more difficult due to their higher specific surface area and more porous structure, which, while improving bioactivity, has until recently constituted the main barrier to using them in robocasting.
A high-quality scaffold must have well-defined and interconnected pores/voids to allow good vascularization, and it must be mechanically stable and fully capable of supporting its own weight during robocasting, drying, sintering, and use without evident shape deformation or the overlapping of layers, but with strong adhesion between adjacent layers. The strength of cancellous bone (also known as trabecular bone, the spongy interior part) is between 2 and 12 MPa [50], so a bone scaffold should ideally be in this range as well. This is important, as one of the major causes of postoperative bone implant failure is a stiffness mismatch between the implanted biomaterial and surrounding bone tissue. 45S5 robocast scaffolds are typically within this range, but the mechanical properties of the denser low-sodium-glass robocast scaffolds such as 13–93 are too high for compatibility with cancellous bone. 13–93 scaffolds have been measured as having a compressive strength between 48 and 142 MPa [8,12,14], in the region of cortical (hard exterior) bone (100–150 MPa) [50], which is less useful for implants and much greater than the values for cancellous bone, resulting in a mismatch. For these reasons, this review will focus on comparing 45S5 glass robocast scaffolds with sol–gel glass robocast scaffolds.
Throughout the rest of this review, we will use the word “voids” to describe the macropores between the struts from robocasting to avoid confusion with any microporosity within the struts themselves.

4.1. Powder Milling

Milling, comminution, and pulverization are interchangeable phrases for the mechanical reduction in particle size of the glass powder. Powder milling is a very important part of the successful formulation of the paste in robocasting, particularly for bioactive glasses for robocasting, which justifies renewed investigations of the powder milling process. The powder can be subjected to wet or dry milling, although wet milling usually proves more effective and is recommended when agglomeration between particles is induced due to their high surface energy [51]. The decrease in particle size taking place during milling results from accumulated stresses induced in the particles from the applied mechanical energy. This causes cracks that propagate and break the particle [52].
Various important parameters need to be taken into account when performing wet milling, such as solids loading (liquid-to-powder ratio (LPR)), the balls-to-powder ratio (BPR) [53], and the speed and type of milling machine [54]. Elevated heat treatment temperatures (HTT) can result in the formation of hard agglomerates that are difficult to destroy with milling. The individual and mutual influences of HTT and BPR on the wet-milling performance and morphology of the powders produced have been studied and well documented [55].
Although powder milling is of key importance in the formulation of the printing ink, few details are usually given of the milling conditions/parameters in articles published on the robocasting of bioactive glasses produced by melt-quenching, often just stating the mill type/model and milling time. Some research groups employed exaggerated milling times of the glass continuously for several days, neglecting the effect of contamination from the milling balls and milling jars, as in the case of wet milling an alkali-free bioactive glass for 2 h in a planetary mill, then 6 days in a ball mill, followed by attrition milling for time periods from 2 and 12 h (158 h in total, in ethanol) [56]. Such a long milling time will almost certainly lead to contamination of the glass, and involves high costs of energy and time. On the other hand, it was demonstrated by Ben Arfa et al. [31,55] that a simple, cheap rapid milling machine was sufficient to mill glass granules for robocasting in 2 h, and that highly expensive and sophisticated milling machines (attrition mills, planetary mills) are not necessary. These authors also used ethanol as the milling medium and, employing a BPR of 10 and LPR of 1.5, reduced the milling time further to just 1 h to prepare a sol–gel glass robocasting paste [23,24].
A detailed experimental procedure for different milling conditions for 13–93 glass was fully described in [8], and these authors also compared the effects of different milling media (water/ethanol) on the subsequent mechanical and biomineralization performance of the robocast 13–93 scaffolds [57]. The results revealed that wet milling using ethanol led to scaffolds with higher bioactivity and better mechanical properties than using water as milling media. The effects of wet-milling parameters and calcination temperature on the final powder morphology of the HSSGG sol–gel glass were also studied in detail [55], and it was found that BPR has an important influence on the final particle size distribution of the powders, as shown in Figure 4, with higher BPR values generally resulting in a smaller particle size and lower size distribution. A narrow particle size distribution is generally preferable in ink formulation to achieve a good dispersion, as, with large distributions, fine particles will be dispersed while the coarser ones will tend to sediment.
On the other hand, pore volume and powder morphology were found to be mostly determined by variations in calcination temperature (Figure 5) [55]. These are important parameters, as an increase in pore volume will lead to the absorption of a larger fraction of the dispersion solution, effectively “freezing” the motion of particles and their flow. The availability of open, small-volume pores is a good attribute for the easier preparation of a glass suspension suitable for robocasting. As Figure 5 shows, heating sol–gel HSSGG to 800 °C was sufficient to obtain a glass powder with pore morphology and reduced the pore volume suitable for ink preparation for robocasting.

4.2. Paste Formulation and Preparation

High-solids loading pastes are recommended in order to reduce the shrinkage of the final sintered scaffold, and values of up to 45 vol% solids loading have been achieved in robocast bioactive glass pastes. Additives are also an important constituent in the recipe of paste formulation. However, it is preferred to use a very small amount of additive in paste preparation to facilitate their elimination in the post-treatment process. The additives play two significant roles in paste formulation, providing pseudoplastic behavior that promotes paste flowability, and aiding the shape retention and providing resistance to the loads of subsequent layers during and after robocasting. The paste must not contain air bubbles or agglomerations of powder, as the air will result in an irregular, discontinuous extrusion, whereas agglomerates tend to block the nozzle and prevent extrusion. Moreover, the paste must exhibit relatively high viscosity at zero shear stress, and thinning behavior at high shear rates, to ensure the extrusion of the paste from the nozzle [58].
Solids loading is the fractional volume of the solids phase to the total volume of powder and liquid forming the paste [59], the liquid being removed during the drying process. A high solids loading significantly increases the viscosity of the paste, as well as the mechanical properties of the green body and the final sintered scaffold [60]. The glass synthesis method used does not present a great change in the maximum solids loading, with a narrow variation in range of between 35 and 45 vol% for 45S5 [15,48] and HSSGG robocast glasses [23,24], reflecting the need for a reasonably high solids loading value for a successful robocasting glass paste/ink.
In general, the paste is formulated from a mixture of glass powder, water, and additives such as dispersants, thickeners (binder), and coagulants. Dispersants are polymers used for steric stabilization (surface active agents—surfactants). They are added to aqueous suspensions to be adsorbed on the powder particle surfaces to overcome the Van der Waals interparticle attractive forces and prevent aggregation, enabling the printability of the paste by robocasting. Binders/thickeners/plasticizers are polymers with high molecular weight and are added to increase the viscosity of the suspension to manifest flow behavior, e.g., hydroxyl propyl methylcellulose. Coagulants are also types of polymers that act as physical glue, providing resistance to the external forces exerted on the extruded struts due to the load of the subsequent layer above. Such mixtures were used in the early robocasting of bioactive glasses, but these days, a single additive is mostly used, such as carboxymethyl cellulose (CMC) [23,24,48] or Pluronic F–127 [8,12], as a combined dispersant, plasticizer, and coagulant. The use of a single additive enables a fast and easy process, especially in the case of CMC, which can be used at room temperature, whereas Pluronic F–127 needs a non-ambient temperature to prepare the suspension.
An example of the effects of BPR and calcination temperature of the glass powder on the rheological properties of a robocasting paste, in this case, for sol–gel HSSGG printing inks with 25 and 40 vol% solids loading, is shown in Figure 6 [31]. Ideally, both a reasonably high viscosity at zero shear stress followed by a gradual decrease in the viscosity (shear thinning behavior) with increased shear rate, and a stable elastic modulus of ~1 MPa throughout the viscoelastic region, are required features for an ink suitable for robocasting.

5. Glass-Melt-Synthesized Bioglass® Robocast Scaffolds

45S5 was first robocast in 2013 by Eqtesadi et al. [15] with a solids loading of 45 vol%, and sintered at 1000 °C/1 h. The scaffolds had ~200 μm struts and ~100 × 250 μm rectangular voids, and were robocast in a variety of geometries and up to 60 layers deep. They had a total porosity of 63% (from an initial macroporosity of 52%) and compressive strength of 13 MPa, stated to be vastly superior to previously reported values for 45S5 scaffolds made by lithography, although they were less porous than scaffolds made by foam replication.
A very detailed paper on the sintering of 45S5 robocast scaffolds from a melt-derived glass was published by Eqtesadi et al. in 2014 [48]. TGA/DTA measurements on the as-fabricated scaffold showed a weight loss of ~10% between 200 and 400 °C due to water and surface OH groups being lost, followed by CMC degradation at 225 and 350 °C. They observed a second phase of weight loss of ~4% between 700 and 800 °C attributed to the loss of carbonaceous remains of the CMC, and isotropic shrinkage of ~5% between 200 and 400 °C and ~7% between 800 and 900 °C, reaching a total of ~18% shrinkage at 1000 °C (Figure 7b). They also stated that there was an equal degree of shrinkage in both the struts and the voids. A glass transition was observed at 560 °C by DTA, followed by primary crystallization at 600 °C, a second glass transition at 910 °C, and secondary crystallization at 850 °C, with the glass melting at 1100 °C, matching findings on bulk 45S5 glass [61]. A very minor Na2CO3 phase was detected by XRD in the otherwise amorphous glass, and this persisted to 550 °C, beyond which Na2CaSi2O6 crystallized as the major phase at 600 °C. A secondary phase of Na2Ca4(PO4)2Si2O4 crystallized at 850 °C, with both Na2CaSi2O6 and Na2Ca4(PO4)2Si2O4, then remaining at 1050 °C.
The 45S5 scaffold sintered at 1000 °C is shown in Figure 7a. Upon heating to 500–1100 °C/1 h to study their sintering behavior, the initial strut (400 μm) and void (200 μm) diameters began to significantly shrink above 500 °C, decreasing 300 and 150 μm, respectively, at ~1000 °C (Figure 7b) [48]. This printing paste had a solids loading of 45 vol% with an initial porosity of ~80%, 50% being macroporosity from the voids and 30% being microporosity in the struts. This remained constant to 500 °C, until a small initial loss of porosity occurred between 500 and 550 °C (the glass transition) followed by a continuous loss of porosity from ~70% at 800 °C to ~60% at 1000 °C (Figure 7c). The bulk of this porosity was lost within the struts, and not in the macroporosity of the scaffold framework. Indeed, the surface of the struts appeared sealed at 1000 °C as the intergranular phase was lost, and the 10% microporosity remaining in the struts was in the form of closed internal pores. This 80% and 70% total porosity at 550 and 800 °C, respectively, was less than those compared to 45S5 scaffolds made from other methods, but was still enough to allow bone regeneration and vascularization. The poor sinterability of 45S5 is demonstrated by the 60% porosity remaining at 1000 °C. The compressive strength of the sintered scaffolds was ~2–5 MPa at 600 °C, ~5 MPa at 800 °C, and ~10 MPa at 1000 °C (Figure 7d), within the range for cancellous bone, the authors claiming this to be up to 4000% greater than values seen in 45S5 scaffolds made by foam replication and additive lithography methods.
Robocast 45S5 bioactive glass scaffolds were also reported in another paper by Eqtesadi et al., this time with a total of 35 vol% solids in the printing paste [62]. However, these were sintered under a flowing Ar atmosphere in a graphite furnace, first heated to 400 °C/1 h, and then to 550 or 1000 °C/1 h. Tetragonal and cylindrical lattice scaffolds with up to 50 layers high were created, and after sintering, the strut diameter was ~400 μm with rectangular ~100–150 × 250 μm voids. A wide endotherm up to 200 °C was seen as free water and surface OH groups were lost, with an exothermic peak at 225 °C as the CMC was removed in TGA/DTA measurements. The bioactive glass crystallized between 600 and 650 °C with a total weight loss of ~10% at 800 °C. Sintering in Ar had the effect of improving the density of the scaffolds, being 4%–5% more than those sintered in air. There was less bubbling and lower in-strut microporosity due to a decrease in the glass’s viscosity in the Ar atmosphere, but some pores were still observed as a result of the glass bubbling.
XRD measurements of these amorphous Bioglass® scaffolds sintered in Ar at 550 °C indicated crystalline Na2Ca(CO3)2·2H2O, originating from the hydration of Na2Ca(CO3)2 crystals formed during heating in the graphite furnace and that became hydrated on standing at ambient temperature and humidity. Upon sintering at 1000 °C in Ar, Na2CaSi2O6 was the major phase and Na2Ca4(PO4)2Si2O4 the minor phase, due to the decomposition of Na2Ca(CO3)2. When sintered in air at 1000 °C, Na2CaSi2O6 and Na2Ca4(PO4)2Si2O4 were both observed, without previous Na2Ca(CO3)2 formation. On sintering in Ar, the relative density of the scaffolds was ~31% at 550 °C and ~42.5% at 1000 °C. Their compressive strength was 2.5 MPa after heating at 550 °C in Ar, at the bottom of the cancellous bone to range, and this increased to ~12 MPa when heated to 1000 °C in Ar.
It should be noted that in this same paper [62], Eqtesadi et al. also produced composite scaffolds based on 45S5 glass mixed with reduced graphene oxide additives. As these are not pure bioactive glass scaffolds, exhibited no significant improvements in mechanical properties over other 45S5 scaffolds, and had no reported data for biocompatibility or bioactivity, we have not added them to the discussion here.

6. Sol–Gel-Synthesized Bioactive Glass Robocast Scaffolds

Due to its high sodium content, the excessive leaching of Na+ from 45S5 printing pastes, accompanied by an increase in pH, causes problems in the creation of an efficient dispersion. Although this was partially overcome by the use of CMC as a single printing additive, the sintered 45S5 scaffolds still exhibited poor densification due to the narrow sintering window between the onset of crystallization and the first glass transition in 45S5.
For this reason, a high-silica, low-sodium sol–gel-based bioactive glass (HSSGG) was developed by Ben-Arfa et al. for robocasting. Despite the potential advantages of bioactive sol–gel glasses, until recently, there had been insurmountable problems in formulating robocasting inks. Their high specific surface area and porous structure, the very features that are advantageous in terms of bioactivity, were also responsible for up-taking a significant portion of the dispersing liquid, adversely affecting printability. The first robocast sol–gel-synthesized bioactive glass scaffolds were reported by the authors in 2019 [24].
As discussed above, an in-depth investigation to understand the combined effects of porosity and particle/agglomerate size on the rheological properties of the suspensions prepared from sol–gel-derived bioactive glass powders was required [31]. Powder milling was found to be a crucial step in creating a printable sol–gel ink, with control of factors such as rotation speed and BPR, allowing the milling time of the sol–gel bioactive glass powders to be reduced to only 1 h using a simple mechanical mill. This work enabled the prediction of sol–gel glass ink printability for a complex quaternary system, and resulted in the successful printing of a scaffold from the high-silica sol–gel glass (HSSGG, composition = 64.4 wt% SiO2, 4.9 wt% Na2O, 21.5 wt% CaO, and 9.1 wt% P2O5) [24]. This was robocast from a paste with 40 vol% solids loading and the scaffolds were sintered at 800 °C/2 h [24]. Three types of scaffold were produced with as-printed void widths of 300, 400, and 500 μm, and after sintering, the strut diameter was 383 μm. The cubic voids had shrunk to ~270, ~370, and ~460 μm wide after sintering (9.5% shrinkage). The sintered HSSGG scaffold with an original void size of 300 μm is shown in Figure 8a. The total porosity of this scaffold was 46.7%, close to the optimum 50% value, and much lower than that of 45S5 scaffolds sintered at equivalent temperatures. This was achievable because, coupled with the low shrinkage, the sol–gel-derived glass was highly microporous, with an estimated microporosity of ~36 vol% in the bioactive glass struts—this being a great advantage of the sol–gel process. The majority of these micropores were also shown to be open, not closed, which is relevant as open micropores play an important role in biological activity.
When heated to 550 °C, HSSGG was an amorphous but highly porous powder [37,38], this high degree of porosity preventing the preparation of printing pastes with over 25 vol% solids loading. To overcome this, the HSSGG powder was heat-treated at 800 °C (the same temperature was used to sinter the scaffolds), reducing the porosity of the glass powder and enabling a solids loading of 40 vol% in the paste, after milling of the powder. This higher heat treatment of the HSSGG powder resulted in the crystallization of three phases in the glass: Sodium calcium silicate, HAp, and cristobalite silica. This partial crystallization of the powder prior to the robocasting of the scaffold was also partly responsible for the high degree of microporosity remaining in the struts after sintering of the scaffold, as it limits the diffusion of the atoms.
The compressive strength of the HSSGG scaffolds is shown in Figure 8b, and the effects of void size can be clearly observed. It decreased from 5.0 MPa with a void size of 270 μm, to 3.3 and 2.2 MPa with voids of 370 and 460 μm, respectively, as the macroporosity of the scaffold structure increases (values not published). All of these compressive strength values are in the region of cancellous bone, despite the inherent microporosity of the HSSGG scaffolds. The biocompatibility of the scaffolds was tested, and they were shown not to be cytotoxic toward MG63 osteoblast cells, with no significant difference between the scaffolds with different void sizes. They were also submersed in SBF for up to 4 weeks to test their bioactivity, and showed evidence of nano-HAp crystallization on the surface after 72 h (Figure 8c), with web-like filaments forming, probably consisting of a mixture of silica gel and nanoHAp. XRD patterns indicated an increase in intensity of peaks for both cristobalite and HAp with immersion, and HAp formation was also observed in FT-IR spectra. After 4 weeks immersion, both nano-HAp platelets/needles and micron-scale HAp grains were observed (Figure 8d), along with some dissolution of the bulk scaffold structure being observed.
In order to enhance the mechanical properties of these scaffolds, HSSGG was doped with 5 mol% copper and lanthanum ions [23]. A previous sintering study utilizing Taguchi analysis had indicated that the addition of these ions could aid the sintering of HSSGG [63]. These scaffolds were also printed from pastes with 40 vol% solids loading, and sintered at 800 °C/2 h. The SEM images in Figure 9a–d show that while the La-doped scaffold did not appear to be significantly different, the Cu-doped scaffold contained less microporosity and appeared more sintered. The total porosities of the 300 μm void scaffolds had decreased with doping, to 42.6% and 37.8% respectively for La and Cu. High-magnification SEM images showed that there was a small increase in the formation of necks between glass particles with La addition in comparison to the parent glass, and a much greater increase with Cu addition. This demonstrated that both additives behaved as sintering aids for the glass, but with a much greater effect observed with the lower-melting-point copper additive acting as a flux agent. Due to this, a small increase in the compressive strength (7%–18%) accompanied the addition of La (Figure 9e). However, a much greater improvement in the compressive strength was observed with Cu addition, it being up to 221% greater than the HSSGG scaffolds, with compressive strength values of up to 14 MPa for the scaffold with the smallest void dimensions (Figure 9e). As with the pure HSSGG glass, an increase in void size and macroporosity led to a decrease in compressive strength in all cases. This demonstrated that the compressive strength of the HSSGG scaffolds could be modified to cover the whole cancellous bone region by addition of copper as a sintering aid, without significantly impacting the printability of the ink. It was also demonstrated that the La3+ and Cu2+-doped HSSGG were still bioactive and fully biocompatible with various cell lines, including osteoblasts [64].

7. Comparison of Robocast Scaffolds from 45S5 Bioglass® and HSSGG Sol–Gel Bioactive Glass

The properties of the 45S5 Bioglass® robocast scaffolds and sol–gel HSSGG robocast scaffolds are compared in Table 1. These two glasses make for a good comparison as they have similar compressive strength in the unadulterated sintered scaffolds at similar temperatures, although the compressive strength of the HSSGG sol–gel glass could be improved with metallic dopants. It is immediately apparent that the range of compressive strength values covers the entire cancellous bone region (~2–12 MPa). They were also both produced with a single organic additive to the printing paste (CMC). The main difference in composition between the two glasses is in silica and sodium content. 45S5 is a high-sodium-content glass, with 45 wt% SiO2 and 24.5 wt% Na2O, whereas HSSGG contains 64.4 wt% SiO2 and only 4.9 wt% Na2O. Due to problems with sintering, 45S5 robocast scaffolds rarely achieve under 60% porosity, even when sintered at 1000 °C, and at the temperatures at which they remain amorphous (<600 °C), they can have up to 80% porosity. The lowest reported porosity is still a high 57.5%, and that was only attained when sintered in an Ar atmosphere. The sol–gel-synthesized HSSGG scaffolds had surprisingly low total porosity values, all <47%, but nevertheless contained a high level of internal microporosity, an advantage of the sol–gel method and ideal for bioactivity, and compressive strength was also in the cancellous bone region. Dopants, especially 5 wt% copper, could further reduce the total porosity by acting as a sintering aid and encouraging shrinkage of the scaffold skeleton, increasing compressive strength to the top end of the cancellous bone range in a scaffold still only sintered at 800 °C. To achieve similar values, 45S5 needs to be sintered at 1000 °C. It can also be observed in both 45S5 and HSSGG scaffolds that the void dimensions have a significant effect on compressive strength when other factors are equal, with smaller-diameter voids resulting in significantly higher values. This allows for the opportunity to tune the compressive strength by merely adjusting the CAD–CAM model for the robocasting scaffold design, without changing other parameters such as glass or printing paste composition, strut dimension, or sintering temperature.
The development of the first robocastable sol–gel-synthesized glasses is an important step, and may lead to glass scaffolds with an improved, greater microporosity in the strut structure and enhanced bioactivity as a result. The rapid sol–gel synthesis route, which is 100 times quicker than the fastest conventional sol–gel ageing bioactive glass synthesis methods, has also attracted a great deal of interest, and a patent for this is currently being applied for, hopefully to develop and commercialize this technology further.

Author Contributions

Conceptualization, B.A.E.B.-A. and R.C.P.; writing—original draft preparation, B.A.E.B.-A. and R.C.P.; writing—review and editing, B.A.E.B.-A. and R.C.P.; supervision, R.C.P.; funding acquisition, R.C.P. All authors have read and agree to the published version of the manuscript.

Funding

R. C. Pullar was funded by the FCT (Fundação para a Ciência e a Tecnologia, Portugal) grant number IF/00681/2015. This research was funded by, and this work was developed within the scope of, the project CICECO–Aveiro Institute of Materials, UIDB/50011/2020 & UIDP/50011/2020, financed by national funds through the FCT/MEC and when appropriate co-financed by FEDER under the PT2020 Partnership Agreement.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

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Figure 1. Schematic illustration and in-situ images of the robocasting process within an oil bath, and an example of a sintered scaffold for human mandibular defect reconstruction. [https://www.euroceram.org/en/technologies/material-extrusion/robocasting-direct-ink-writing.html, accessed on January 2020].
Figure 1. Schematic illustration and in-situ images of the robocasting process within an oil bath, and an example of a sintered scaffold for human mandibular defect reconstruction. [https://www.euroceram.org/en/technologies/material-extrusion/robocasting-direct-ink-writing.html, accessed on January 2020].
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Figure 2. The typical “wood pile” or “log-cabin” scaffold structure.
Figure 2. The typical “wood pile” or “log-cabin” scaffold structure.
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Figure 3. A depiction of the rapid sol–gel bioactive glass synthesis route developed by Ben-Arfa et al. [25].
Figure 3. A depiction of the rapid sol–gel bioactive glass synthesis route developed by Ben-Arfa et al. [25].
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Figure 4. Particle size distributions of the bioactive sol–gel glass powders heat-treated at different temperatures followed by wet-ball milling in ethanol under given values of balls-to-powder ratio (BPR): (a) 5; (b) 10; (c) 15; (d) 20. Reproduced with permission from [55], Copyright Elsevier Ltd and Techna Group S.r.l., 2018.
Figure 4. Particle size distributions of the bioactive sol–gel glass powders heat-treated at different temperatures followed by wet-ball milling in ethanol under given values of balls-to-powder ratio (BPR): (a) 5; (b) 10; (c) 15; (d) 20. Reproduced with permission from [55], Copyright Elsevier Ltd and Techna Group S.r.l., 2018.
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Figure 5. Effects of the processing parameters on the nitrogen sorption isotherms for the bioactive sol–gel glass powders: (a,b) Comparison of two BPRs (5 and 10) used in wet-ball milling in ethanol for samples heat-treated at different temperatures (550, 675, 800, 925 °C); (c,d) comparison of two heat treatment temperatures for powders wet-ball milling in ethanol under different BPR values (5, 10, 15, 20). Reproduced with permission from [55], Copyright Elsevier Ltd and Techna Group S.r.l., 2018.
Figure 5. Effects of the processing parameters on the nitrogen sorption isotherms for the bioactive sol–gel glass powders: (a,b) Comparison of two BPRs (5 and 10) used in wet-ball milling in ethanol for samples heat-treated at different temperatures (550, 675, 800, 925 °C); (c,d) comparison of two heat treatment temperatures for powders wet-ball milling in ethanol under different BPR values (5, 10, 15, 20). Reproduced with permission from [55], Copyright Elsevier Ltd and Techna Group S.r.l., 2018.
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Figure 6. Effects of the processing parameters on the rheological properties of the bioactive glass suspensions. The viscosity behavior of 25% SL (a) and 40% SL (b) and the viscoelastic properties of the paste at 25% SL (c) and 40% SL (d). Reproduced with permission from [31], Copyright the American Ceramic Society, 2018.
Figure 6. Effects of the processing parameters on the rheological properties of the bioactive glass suspensions. The viscosity behavior of 25% SL (a) and 40% SL (b) and the viscoelastic properties of the paste at 25% SL (c) and 40% SL (d). Reproduced with permission from [31], Copyright the American Ceramic Society, 2018.
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Figure 7. (a) Robocast 45S5 scaffold sintered at 1000 °C/1 h. (b) Shrinkage of the 45S5 scaffold during sintering. (c) Change in porosity of the scaffold with sintering temperature. (d) Variation in compressive strength with sintering temperature, and comparison to other 45S5 scaffolds made by alternative additive manufacturing methods. Reproduced with permission from [48], Copyright Elsevier Ltd. 2014.
Figure 7. (a) Robocast 45S5 scaffold sintered at 1000 °C/1 h. (b) Shrinkage of the 45S5 scaffold during sintering. (c) Change in porosity of the scaffold with sintering temperature. (d) Variation in compressive strength with sintering temperature, and comparison to other 45S5 scaffolds made by alternative additive manufacturing methods. Reproduced with permission from [48], Copyright Elsevier Ltd. 2014.
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Figure 8. Robocast scaffolds of high-silica-content sol–gel bioactive glasses (HSSGG) sol–gel bioactive glass. (a) Optical and SEM images of scaffolds with 300 μm as-printed void size, after sintering at 800 °C/2 h. (b) Compressive strength of the scaffolds with different void sizes (300, 400, and 500 μm as printed) sintered at 800 °C/2 h. Structural and morphological features of the scaffolds with 300 μm printed void size after immersion in SBF for 72 h (c) and 4 weeks (d). Reproduced with permission from [24], Copyright Elsevier Ltd. 2018.
Figure 8. Robocast scaffolds of high-silica-content sol–gel bioactive glasses (HSSGG) sol–gel bioactive glass. (a) Optical and SEM images of scaffolds with 300 μm as-printed void size, after sintering at 800 °C/2 h. (b) Compressive strength of the scaffolds with different void sizes (300, 400, and 500 μm as printed) sintered at 800 °C/2 h. Structural and morphological features of the scaffolds with 300 μm printed void size after immersion in SBF for 72 h (c) and 4 weeks (d). Reproduced with permission from [24], Copyright Elsevier Ltd. 2018.
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Figure 9. SEM images of robocast HSSGG sol–gel bioactive glass scaffolds, with 300 μm as-printed void size and after sintering at 800 °C/2 h, with addition of (a,c) 5 wt% Cu2+ and (b,d) 5 wt% La3+. (e) Compressive strength of the scaffolds with different void sizes (300, 400, and 500 μm as printed) sintered at 800 °C/2 h. Reproduced with permission from [23], Copyright Acta Materialia Inc. 2019.
Figure 9. SEM images of robocast HSSGG sol–gel bioactive glass scaffolds, with 300 μm as-printed void size and after sintering at 800 °C/2 h, with addition of (a,c) 5 wt% Cu2+ and (b,d) 5 wt% La3+. (e) Compressive strength of the scaffolds with different void sizes (300, 400, and 500 μm as printed) sintered at 800 °C/2 h. Reproduced with permission from [23], Copyright Acta Materialia Inc. 2019.
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Table 1. Comparison of sol–gel robocast HSSGG bioactive glass scaffolds and 45S5 Bioglass® scaffolds robocast from glass powders produced by melt-quenching.
Table 1. Comparison of sol–gel robocast HSSGG bioactive glass scaffolds and 45S5 Bioglass® scaffolds robocast from glass powders produced by melt-quenching.
Glass SynthesisGlass TypeSintering Temp. (°C)Strut Diameter (μm)Void Size (μm)Porosity (%)Compressive Strength (MPa)Ref
Melt-quenching45S5 Bioglass®600400200802.5[48]
800360180725
10003001506010
1000200100 × 2506313[15]
550 in Ar~400~100–150 × 250692.5[62]
1000 in Ar~400~100–150 × 25057.512
Sol–gelHSSGG80038327046.75.0[24]
383370-3.3
383460-2.2
HSSGG + 5 wt% La3+80038027042.65.4[23]
380370-3.5
380460-2.6
HSSGG + 5 wt% Cu2+80038027037.813.9[23]
380370-10.6
380460-4.9

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MDPI and ACS Style

Ben-Arfa, B.A.E.; Pullar, R.C. A Comparison of Bioactive Glass Scaffolds Fabricated ‎by Robocasting from Powders Made by Sol–Gel and Melt-Quenching Methods. Processes 2020, 8, 615. https://doi.org/10.3390/pr8050615

AMA Style

Ben-Arfa BAE, Pullar RC. A Comparison of Bioactive Glass Scaffolds Fabricated ‎by Robocasting from Powders Made by Sol–Gel and Melt-Quenching Methods. Processes. 2020; 8(5):615. https://doi.org/10.3390/pr8050615

Chicago/Turabian Style

Ben-Arfa, Basam A. E., and Robert C. Pullar. 2020. "A Comparison of Bioactive Glass Scaffolds Fabricated ‎by Robocasting from Powders Made by Sol–Gel and Melt-Quenching Methods" Processes 8, no. 5: 615. https://doi.org/10.3390/pr8050615

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