Evaluation of Two Highly Porous Microcrystalline Biphasic Calcium Phosphate-Based Bone Grafts for Bone Regeneration: An Experimental Study in Rabbits ()
1. Introduction
This template, Bone tissue is in constant formation and resorption called the remodeling process. It consists of the reabsorption of a certain amount of tissue carried out by osteoclasts, while, simultaneously, osteoblasts produce an osteoid matrix that is subsequently mineralized. This process takes place in small areas of the cortical or trabecular surface called “basic bone remodeling units” (basic multicellular units, BMUs) formed by osteoclasts, osteoblasts, preosteoblasts, and macrophages. In these units, the activation of osteoclasts first occurs at a specific place in the skeleton, which results in bone tissue resorption, and then and in the same place, osteoblasts are activated, forming new bone tissue [1] [2] [3]. Osteoclasts and osteoblasts exert their activities in the so-called bone remodeling compartments (BRCs), which are separated from the bone marrow cavity by a monolayer of flat cells. It has been shown that BRCs in their three-dimensional reality are part of a previously unrecognized anatomical microstructure, which involves microcapillaries, and there are communications between bone marrow niches and tissue surfaces in the process of remodeling [4].
Some osteoblasts are finally buried within the lagoons of a mineralized matrix. These cells are called osteocytes and are characterized by a striking star morphology, reminiscent of the dendritic network of the nervous system. Surface cells, osteoblasts, and osteoclasts are found on the bone surface, while osteocytes are inside the bone. Osteocytes are the most abundant cells of bone tissue (10 times more than osteoblasts). Its body is located inside osteoplasts or osteocytic lacunae, and cytoplasmic processes are arranged inside calcophoric ducts that are filled with an extracellular matrix (ECM). Osteocytes are organized forming a sync of interconnected cells through multiple cytoplasmic processes; they communicate through nexus junctions with each other and with the bone tissue surface cells along canaliculi, representing a unique structure. Osteoblasts, in turn, can communicate with bone marrow stroma cells, as they extend cell projections into endothelial cells within sinusoids. This large contact surface between osteocytes and the blood vessel wall throughout its path allows them to ensure oxygen and nutrients. When trauma to bone tissue occurs, the cessation of blood circulation causes hypoxia and necrosis of osteocytes that occur more than 0.1 mm from an intact capillary. Osteocytes also participate in the synthesis and mineralization of an osteoid matrix, but their main function is to control the modeling and bone remodeling by a mechanotransduction process, detecting mechanical loads through changes in the flow of interstitial fluid in canaliculi. The cyclic compression load promotes osteoblast differentiation. Consequently, compression on bone tissue produces deformations on osteocytic membranes that induce biochemical modifications thereof. This allows these mechanosensory cells to detect the need for augmentation or reduction of bone tissue during the functional adaptation of the skeleton, the need for microlesion repair, and, in both cases, to transmit signals that lead to an appropriate response. Osteocytes constitute the final stage from the osteoblast line and are unable to renew [5] [6] [7]. A new study confirmed that autogenous bone tissue fragments generated during surgery (for example, in the preparation of an implant site), accelerate the formation of tissue by releasing a wide variety of growth factors from an ECM and cells contained within this matrix. Osteocytes, whether viable or in apoptosis, within such fragments are able to recruit osteoclasts to a bone remodeling site and support the formation of bone tissue on their surfaces. In addition, osteocytes within autogenous fragments are often able to repair interrupted canalicular networks to connect with other osteocytes or osteoblasts in the new bone tissue formed on the surfaces of fragments [8].
When an osseointegrated implant is placed or a graft is performed to increase the bone substrate before the insertion of implants, bone regeneration, which means the new bone tissue is identical to the pre-existing ones, is sought. A bone matrix must have suitable mechanical properties to provide structural support during bone growth, allowing vascular neoproliferation and consequently bone formation. Biodegradable or resorbable ceramics are ceramics that gradually degrade and replaced by reactive bone tissue, a process also known as bioabsorption [9]. Tricalcium phosphate (TCP) in its active forms and calcium sulfate hemihydrate (plaster of Paris) are part of this group. These types of bioceramics are superior, since they remain in the body only as long as their function is necessary, disappearing as tissues are regenerated. Its major drawback is that its resistance also decreases during the resorption process. Therefore, synchronization and balance control between scaffolding-material resorption and new bone tissue formation are crucial aspects for the success of bone tissue engineering [10] [11] [12].
Ceramics have been used as grafts for decades and are seen as a viable solution to the problem of bone loss. However, the challenge is to develop a biomaterial that mimics macro- and microstructures and can be part of the composition of bone tissue, so that it harmonizes locally with the host tissue and provides a biologically stable implant [13] - [18]. Calcium orthophosphates, such as beta-tricalcium phosphate (β-TCP) and hydroxyapatite (HA), are the most commonly used resorbable bioceramics as synthetic bone tissue implants [19]. Currently, these CaPO4 are used combined in different proportions forming biphasic compounds that can improve their therapeutic performance [20] [21] [22].
Porosity is an essential factor that allows for the union between bioceramics and bone tissue, and interconnected porous structures allow for the penetration of vasculature into pores connecting mesenchymal stem cells (MSCs) and osteotropic agents. A larger contact area allows for a more significant contact and exchange relationship with the recipient bone tissue. Porous scaffolding must have a porosity higher than 50% with a recommended minimum pore size of 100 μm [23] [24] [25], which is the same requirement for physiological Havers systems of bone tissue that have an approximate diameter greater than 100 μm. The minimum porosity necessary for the regeneration of a blood vessel is approximately 30 to 40 μm to allow for the exchange of metabolic components and to facilitate the entry of blood vessels [26]. However, the average size of macropores and pore interconnections of more than 300 μm induction provides bone neoformation, increasing the differentiation and proliferation of osteoblasts throughout scaffolding with mass oxygen transport and nutrient flow, also facilitating waste disposal [26] [27]. A significant impact on osteogenic response is microporosity (pore size < 10 μm), roughness of a pore wall, and macroporosity (pore size > 50 μm); all of them contribute to adsorption of osteoinductive proteins, ion exchange, and the formation of apatite similar to bone tissue by dissolution and reprecipitation [9] [28] [29].
Microporosity improves the load transfer between tissues and the hardness of a material. It also facilitates the material establishment of a continuous mechanosensory network [30] - [36]. Although increase in porosity and a larger pore size facilitate bone tissue growth, the structural integrity of the scaffold can be jeopardized and can adversely affect its mechanical properties if the porosity is very high at the same time. Therefore, manufactured scaffolds from biomaterials should not have high porosities (>90%) in order to avoid compromising the structural and mechanical integrity before proper replacement by the newly formed bone tissue [37]. The small size of crystalline domains forms a smaller size of the microstructure of a surface that allows for a more significant contact stability and reaction at the interface between a grafted material and the host bone. The activation and adsorption of MSCs would support the intrinsic stimulation of the formation of new bone tissue to surfaces with nanometric topographic features [38] [39] [40]. Achieving a balance between resistance to deformation and porosity is vital to develop porous scaffolds with mechanical stability optimally. The pore structure of scaffolding is an essential consideration for vascularization, cell migration, and a better organization for cell growth and ECM production [41].
Previously, we presented a method to obtain a mixture of HA/β-TCP by a chemical method [42]. The method is low-cost, because it uses technical grade precursors and the use of glycolic acid during the synthesis to provide a highly porous material without the need to use additional porogenic agents. This reduces manufacturing cost, which impacts marketing cost and expands the possibility of massive application of bone grafting. Using light microscopy, we made a comparative analysis of the distribution and activities of osteoblastic cells on biomaterials 30, 60, and 90 days after implantation. The present work takes a multimodal approach consisting of a study of the crystallinity, composition, and pore-volume, as well as compression testing, of this new material and its cellular biodegradation when used to fill critically sized bone defects in rabbit tibia, comparing its performance with those of a commercially available β-TCP graft material (Synergy Odontit®; Buenos Aires, Argentina) [43] and unfilled control defects.
2. Materials and Methods
2.1. Sample Preparation
A biphasic β-TCP/CaPO4 mixture was obtained by using a technical-grade dust calcium phosphate tribasic with 34.0% - 40.0% Ca basis (Sigma-Aldrich® Merck, Buenos Aires, Argentina), and an aqueous glycolic acid solution at a concentration of 70% V/V with a pH value of 0.1 (DuPont®, Wilmington, DE, USA). Glycolic acid was added to the powder at a concentration of 1 mL/g in a glass vessel and continuously stirred (20 rpm) for 10 min. An exothermic reaction with a maximum temperature of 57.5˚C was produced. Afterward, the sample was dried in a furnace (at 160˚C for 8 h) to evaporate the water excess. Then, the material is ground to break up agglomerates and sieved to obtain particle sizes of 650 - 1250 µm. After that, the sample was heated at 500˚C for 20 min under a 60˚C/min heating rate at atmospheric pressure. Then, the temperature was raised (with the same heating rate) up to 1150˚C, and the material was maintained at this temperature for three hours at atmospheric pressure and then for three more hours in a vacuum atmosphere. The last thermal treatment produced a solid-state reaction, which reduced 50% of the sample weight and transformed the material into the biphasic β-TCP/CaPO4 phase (ARG. GLICO β-TCP) (see in Figure 1(a) and Figure 1(b)).
2.2. Material Characterization
The microstructure of the material obtained was characterized by a Zeiss Sigma Field Emission-SEM (Carl Zeiss,Oberkochen, Germany), operated at 5 kV. XRD patterns were acquired in a Panalytical Empyrean Philips PW 3710 X-ray diffractometer in a 2θ range of 5˚ - 90˚ (step size: 0.02˚) with Cu-Kα radiation at a voltage of 30 kV and a current of 25 mA to determine the mineral phases present in both study materials. Patterns were quantified by the Rietveld method.
(a) (b)
Figure 1. SEM images of biphasic materials particles used to fill critical size defects of tibia rabbits: (a) Granules of beta-tricalcium phosphate (β-TCP) ARG. GLICO material; (b) Commercial Synergy Odontit® β-TCP material (Buenos Aires, Argentina).
The specific surface area (BET area) allowed obtaining the total area of the sample that was in contact with biological tissues and was determined by a DigiSorb 2600 Micromeritics micrometer surface area analyzer. For compression tests, the materials were compacted in the form of bars. The bars of the ARG. GLICO β-TCP and commercial Synergy Odontit® β-TCP materials (Odontit Argentina, Buenos Aires, Argentina) were obtained by cold isostatic pressing at 200 MPa for one hour, followed by sintering at 1000˚C during the second hour with a temperature rise range of 5˚C/min. The bars were cut into circular discs with a diameter (D) of approximately 7.14 mm and a thickness (t) of approximately 2.11 mm (t/D ratio: approximately 0.29).
Strength was determined using compact disc diametral compression tests (DCDTs) following the procedures described in previous studies [44] [45]. Sixteen circular discs of each composition were placed between two stainless steel plates with their faces perpendicular to loading plates in a universal testing machine (MicroTest, Madrid, España). The load was applied at a machine frame travel speed of 0.5 mm/min.
For DCDT samples, the highest tensile force was uniform across the central part of the diametral plane of the samples, and the areas closest to the load withstood the compression. The compression ratio was smaller for more rigid samples. The fault occurred through the diametral plane, and the samples were broken into two similar pieces, corresponding to a drop in load in the load-displacement curves recorded during the tests. The maximum load before the fall was used to calculate the diametral force, σf, using Equation (1):
The results of 16 valid tests were used to calculate Weibull parameters using the procedure of ENV-843-5 [46], which implies the simplest form of the Weibull function [47] shown as Equation (2):
where
is the probability of failure in the tension
, σ0 is the breaking stress, which is the maximum stress that the material endures before it is broken, corresponding to the tension at which the probability of failure is 63.2%, and m is the Weibull module. The probability of failure was calculated using Equation (3):
where N is the total number of specimens tested and n is the sample range in ascending order of fault voltage. This function of Weibull has been shown to adequately describe the distribution of the strengths of dense and porous materials (up to 60% by volume) [48] [49] [50].
The same analyses for microstructures, mineral phases detections, specific surface areas, and compression tests were completed for a control material (Sinergy Odontit® β-TCP, Buenos Aires, Argentina) with the same evaluation conditions.
2.3. Implantation Procedure
The experimental study was carried out following the ethical principles for experimental animals research of Catholic University of Cuyo San Juan Argentina Institute of Bioethics (UCCSJ) San Juan October 10 2012 (Ref: Project M.A Garcés).
Fifteen New Zealand male rabbits of six months age weighted 3.1 - 3.6 kg were used in the study. The ARRIVE guidelines for animal experimentation were followed. The sample size per group was calculated at a statistical power of 80% and an error of 0.5%. The group allocation in each tibia was randomly selected using the software Research Randomizer.
Rabbits were fed “Ad libitum” with solid food and water for adaptation in cages at 24˚C and 50% humidity with a 12/12h light/dark photoperiod [51]. Before the surgery, rabbits were anesthetized with Ketamine Hydrochloride (Ketalase®) (body weight (BM): 50 mg/kg), IM, and chlorpromazine (Ampliactil®, Sanofi, Aventis, Buenos Aires, Argentina) (BW: 10 mg/kg), IM [52]. Antibiotic prophylaxis was performed with amoxicillin (Amoxidal®, Roemmers, Buenos Aires, Argentina) with a BW of 15 mg/kg, administered in single doses and 30 min before the intervention. The two hind legs were shaved, and a full-thickness incision was made to expose the proximal antero-internal area of each tibia. Two critical defects (holes with 5 mm in diameter) were made in each of tibias, the graft filled one of them, and the other was kept as a control (Figure 2).
Figure 2. Defects created in a tibia filled with 0.176 cm3 of the ARG. GLICO β-TCP material in the present work (left) and unfilled for controls (right).
The animal surgery was done on each of the legs, in the proximal antero-internal area of each tibia to place the graft. Five milimeters bone defects were filled with substitute materials previously sterilized in a dry heat stove at 170˚C for two hours and then stored in phosphate-buffered saline (PBS) before placement. Subsequently, the wound was carefully closed with continuous interlaced resorbable suture of Glicosorb® polyglycolic acid 3/0, starting with the periosteum and a deep muscular plane. The cutaneous plane was also faced employing a continuous suture entwined with Silk 3/0. Finally, after washing the surgical wound with a physiological serum, a Rifocina® rifampicin spray (Sanofi-Aventis, Buenos Aires, Argentina) was applied. Postoperative pain and inflammation of rabbits were controlled with the administration of Helenil® ketoprofen (Roux-Ocefa, Buenos Aires, Argentina) (BW: 1000 µg/kg) every 24 hours, one hour before the intervention and for three days [53]. Two perforations were made in each of tibiaes of each rabbit for a total of 60 perforations. In one tibia, the synthesized material was placed, and one empty defect was left, whereas in the other tibia, a commercial bone substitute was applied to one defect and the other one was left empty (Figure 3). The volume (V) of the bone substitute that was placed in cylindrical bone defects with a critcial size was calculated using the following volume equation: V = πr2h = 3.14 × 2.52 × 9 mm3, which was 176 mm3 equaling to 0.176 cm3. No filling (n = 30) was applied in the control group, Sinergy Odontit® β-TCP (Odontit Argentina, Buenos Aires, Argentina) (n = 15) was used in test A, and ARG. GLICO (n = 15) β-TCP was used in test B. Day 0 (zero) was considered at the time of surgery. After 30, 60, and 90 days of healing, five rabbits were sacrificed at each of experimental times under anesthesia by administering an intravenous sodium thiopental overdose obtaining a sample of 10 tibiaes at a time.
2.4. Histological Analysis
After sacrifice, tibias were extracted, soft tissues were removed to expose the rabbit’s tibia, and bone blocks containing experimental areas were obtained with an oscillating saw. The blocks were fixed in a 10% formaldehyde solution at pH 7.0.
Figure 3. Surgical protocol in both tibias. Critical defects with a diameter of 5 millimeter were made in both tibias; 10 millimeters of separation was left between the perforations in one defect material implanted and the other left as a control without filling.
Bone samples were demineralized for five weeks in a 10% EDTA solution (pH 7.4). Then, the pieces were dehydrated in a gradient of ascending alcohol (60% - 100%) and processed for later inclusion in paraffin. Next, samples were sectioned in 5 μm thickness with a microtome. Finally, the samples were stained with hematoxylin and eosin to perform the histomorphometric analysis by optical microscopy. Histological images were obtained with an Olympus BX 50 fluorescence microscope (Leica, Wetzlar, Germany) connected to a Sony CCD-IRIS digital camera (Sony Global Eng Net, Argentina) equipped with lenses for detailed evaluation and morphometric measurement. Measurements in the area of a newly formed bone in the defect were obtained using Image-Pro Plus software version 4.5.2 (Media Cybernetics Inc, Rockville, Maryland, USA). In histological images, osteoblasts were seen aligned in contact with trabecular bone, while osteocytes were scattered on the surface of bone trabeculae. For this reason, osteoblasts were measured in millimetres, and osteocytes were measured in square millimeters. Osteoblasts and osteocytes can be differentiated and counted perfectly with a 40× optical microscope. The number of osteocytes per surface (mm2) was calculated, and the osteoblasts were linear (mm) using 30 images at a magnification of 40× in total, that is, 10 images for each time of the study. Biomaterial particles remaining at the end of the study (90 days) were observed and measured with a 1.3 MP Motic camera considering the area they occupied in a reference region. Images were captured with a 10× objective and calibrated with a circle of 150 μm using the Motic Images Plus 2.0 ML program (Laboquimia, La Rioja, Spain).
A two-way ANOVA test was used for the statistical analysis of histomorphometric data, (group and stage), and to evaluate the differences between specific means, post hoc tests (Tukey DHS) were performed. For all tests, the value of statistical significance was set at p < 0.05. Data were processed with the statistical software package SPSS v.20 (IBM-SPSS Inc., Chicago, IL, USA). The researchers of this work were blinded, that is, they were unaware of the intervention the groups under study were receiving.
3. Results
3.1. Material Characterization
The physical structures at the micrometer scale of the material synthesized and the commercial β-TCP can be observed in Figure 4.
Particles corresponding to the ARG. GLICO β-TCP had irregular forms with spherical edges, associated with a high macroporosity. In addition, the specific surfaces of these particles were microcrystalline and concave. The nanostructures of the material synthesized and the commercial β-TCP can be seen in Figure 5. Even when the shapes of the subunits were similar for both samples, the size of the commercial sample was almost twice that of the synthesized material.
The Ca/P ratios, estimated by quantification of energy-dispersive X-ray spectra, were 1.5 and 1.6 for the synthesized and commercial β-TCP samples, respectively. XRD patterns of the material synthesized and the corresponding Rietveld
(a) (b)
Figure 4. SEM micrographs at a magnification of 150×: (a) ARG. GLICO β-TCP having irregular shapes and rounded edges and macropores between 150 and 500 µm; (b) Sinergy Odontit® β-TCP (Buenos Aires, Argentina) having regular shapes and straight edges and no macropores.
(a) (b)
Figure 5. SEM photomicrographs at a magnification of 3500×: (a) ARG. GLICO β-TCP. Micropores with sizes between 1 and 9 µm were observed and had a smaller surface microstructure; (b) commercial Sinergy Odontit® β-TCP (Buenos Aires, Argentina). Micropores with sizes between 1 and 4 µm and a larger surface microstructure were observed.
refinement are shown in Figure 6. No remains of the starting materials were observed, and the mass concentrations of the detected phases were 97% β-TCP, 1.04% dicalcium phosphate, and 1.89% phosphate tetra calcium oxide.
The phases identified for commercial grafting were 90% β-TCP, 8.68% dicalcium phosphate, and 1.29% phosphate tetra calcium oxide shown in Figure 7. The Rietveld method allowed obtaining structural refinement, in addition to the phase concentrations of the analysis, the parameters of the crystalline cell, and the size of the crystals. The crystalline sizes obtained in the refinement were 120 nm for the commercial Sinergy Odontit® β-TCP (Buenos Aires, Argentina) and 67 nm for the ARG. GLICO β-TCP phase, which represented almost twice the domain size (1.79 nm). These crystalline domain sizes represented the mean value of coherent domains for diffraction, and they did not coincidence with the subunit sizes observed by SEM, since these subunits were composed by many of the crystallites domains. A detailed study on diffraction of biphasic ceramics by X-ray techniques can be found elsewhere [42].
Regarding the mechanical tests of the biphasic sample synthesized here, the parameters of the Weibull force distribution, determined by diametral disk compression, were as follows: modulus, m = 5.4, and σ0 = 4.9 MPa (80% confidence interval: m = 5.4 - 6.0, σ0 = 4.6 - 5.3), whereas for the commercial β-TCP m = 6.7 and σ0 = 5.9 MPa (80% confidence limit: m = 6/7 - 7/3, σ0 = 6.2 - 5.6). The Weibull distribution calculated using the specified Weibull module and the characteristic resistance is shown in Figure 8 together with the experimental data. The lower and upper limits for Weibull parameters are summarized in Table 1.
The total porosity was calculated by comparing the theoretical density ρc of a CaPO4-β-
TCP
mixture with the measured density ρm and represented the fraction of volume occupied by pores. The porosity values obtained from this method were 80% for the present biphasic sample and 50% for the commercial sample. The specific surface areas by the BET method were 3.98 ± 0.05 m2/g for the material studied obtained and 1.50 ± 0.05 m2/g for the commercial material.
Figure 6. XRD pattern and Rietveld analysis of the ARG. GLICO β-TCP.
Figure 7. XRD pattern and Rietveld analysis of the commercial Sinergy Odontit® β-TCP (Buenos Aires, Argentina).
Figure 8. Weibull distributions (indicated by lines) calculated using the determined Weibull parameters (Table 1) and experimental data (indicated by points). Pf: probability of failure.
Table 1. Weibull parameters following the procedures of ENV 843-5 with an 80% confidence limit. Du and Dl represent upper and lower limits for the Weibull distribution. Cu and Cl represent upper and lower limits of a characteristic resistance, σ0. Distribution calculated using the unbiased values of Wexp and Wcorr.
3.2. In Vivo Study
The experimental areas healed uneventfully along the entire experimental periods. Considering the critical size of the wound and the effect of the biomaterial evaluated, only the repair at the level of the defect could be clearly observed from cortical walls in the histological sections 90 days after the study. However, the advantages of using a graft material for filling bone defects can be seen in Figure 9, which shows healing in a cortical area with greater amounts of bone trabeculae than in an unfilled defect, regardless of a graft material employed.
Figure 10 shows histomorphometric images on the decalcified sections at 30, 60, and 90 days after implantation of the ARG. GLICO β-TCP and the commercial β-CTP. The corresponding quantitative analysis is shown in Figure 11.
After 30 days, the formation of bony trabeculae of lamellar bone tissue was observed in the graft areas of both biomaterials. Hematopoietic marrows and adipocytes were found in the area of unfilled boreholes, but no trabeculae were observed. In the biphasic material presented here, the vascularization of the porous network of the biomaterial was observed through the homogeneous formation of a new vessels network that occupied a substantial extension of the graft, and some trabeculae penetrated inside.
Figure 9. Cross-sectional photomicrographs of a tibia at 90 days in the cortical zone of a critical defect: (a) control without a bone cortical wall in the area of critical defects and abundant hematopoietic marrows; (b) ARG. GLICO β-TCP; and (c) Sinergy Odontit® β-TCP (Buenos Aires, Argentina).
Figure 10. Histomorphometric images of the blank control, biphasic βTCP ARG. GLICO β-TCP material presented in this work, and the commercial β-TCP at 30, 60, and 90 days after implantation.
At 60 days in the control perforation for the commercial sample, hematopoietic marrow adipocytes and some isolated small elliptical trabeculae were observed with incomplete vascularization in the graft area. Vascularization of the graft, hematopoietic marrows, adipocytes, and remnants of the biomaterial was observed in intimate contact with a large number of osteoblasts, and osteocytes and trabeculae organized with lamellar bone tissue were observed for the biphasic sample presented here (Figure 10).
At 90 days, the control perforation maintained the histological characteristics observed at 60 days. For the commercial graft, trabeculae organized with lamellar bone tissue were observed and, although there were large unresorbed residual particles (size: 450 μm) without reabsorption, intimate contact of the biomaterial
Figure 11. Values of central tendency and dispersion (mean and standard deviation) of densities of osteocytes and osteoblasts according to group and stage. Groups with significantly lower densities of osteocytes and osteoblasts were indicated with * at each stage. When considering the density of osteocytes, the differences between groups were significant (p = 0.018), specifically between the ARG. GLICO β-TCP and control groups (p = 0.020), but not between both experimental groups (p = 0.837), while the differences between stages were not significant (p = 0.109) despite observed higher densities in all groups at 90 days. When considering the density of osteoblasts, the differences between groups were again significant (p = 0.015), but this time only between the test groups (p = 0.011), and not between the commercial β-CTP and control groups (p = 0.294). The differences between stages were not significant (p = 0.193), although in this case the osteoblastic activity decreased over time. Numbers of samples for each time point: n = 5 for ARG. GLICO β-TCP, n = 5 for the commercial β-TCP, and n = 10 for the control group.
with the osteoblasts of the trabecula was verified. The microcrystalline biphasic graft also organized trabeculae (lamellar bone tissue) with a large number of osteoblasts with abundant hematopoietic marrows and adipocytes, but no remnants of the biomaterial were observed.
4. Discussion
The particle morphology of bone substitute graft materials (visible under SEM) has a significant effect on determination of cell proliferation and adhesion, which will accelerate the start of bone tissue neoformation [54]. In this context, small domains are desirable, as they enable stronger attachment between graft materials and natural bone [54]. The biphasic ceramic, ARG. GLICO β-TCP, described in the present work presented greater solubility than the commercial material, evidenced by the inverse proportion of the calcium/phosphorous ratio [55] [56].
Regarding the mineral phases concentration, the composition obtained for the present material favors bone induction, since, according to the observation of other authors, bone induction occurs more quickly in samples with CaPO4/β-TCP ratios of around 20/80, compared with biphasic samples with higher CaPO4/β-TCP ratios, pure HA, and pure β-TCP [57] [58]. Graziano and Zhang demonstrated direct contact between cells and the nanometric surface of calcium phosphate ceramics by means of osteogenic differentiation (osteoinduction) [59] [60]. They also postulated that the size of the surface microstructure could be large enough to induce MSC differentiation, leading to bone tissue formation. Lower crystallinity may facilitate a higher calcium release rate, as evidenced by dissolution testing in an acid environment [61].
These results of compression tests expressed more compression resistance for the commercial sample. However, the values obtained for both materials were large enough to use as bone substitutes and were similar to those published by other authors in studies of porous scaffolds of β-TCP [62] [63] [64]. These results shown in the present work verified that the degree of purity and architecture of the scaffold (surface morphology and porosity) presented had a significant influence on the union, differentiation, and proliferation of the cells, which ultimately enabled the reabsorption of granules by macrophages and their gradual replacement by new bone. The present study determined the size of nanocrystals of the β-TCP phases, but the percentage of nanocrystals present in both materials was not measured. The use of glycolic acid as a precursor achieved a high total porosity with a large surface area (determined by the BET method) that allowed for better penetration and integration of recipient tissues.
Porosity is a main key related to bioimplants setups that stimulate bone tissue, which must have a total porosity higher than 50% with a minimum recommended pore size of 100 μm, corresponding to the diameter found in physiological Haversian systems in bone tissue [65] [66]. The same method to increase porosity was applied by Li et al. [67] for two commercial materials, resulting in respective values of 75% and 80%. A porosity of 79% (measured by the Archimedes method) was reported by Amera et al. [58] for a sample with a CaPO4/βTCP ratio of 16/84. The huge difference in porosity between ARG. GLICO β-TCP (porosity: 82%) and β-TCP Sinergy Odontit® β-TCP (Buenos Aires, Argentina; porosity: 50%) was a crucial factor in this work, since the greater porosity increased graft vascularization and cell proliferation, which was observed in the bone healing during in vivo studies. Therefore, the key differences found between the material presented here and the commercial graft were the higher cellularity and vascularization and less amount of biomaterials remaining in the synthesized sample compared with in the commercial graft, which has a more considerable amount of the residual biomaterial due to its lower purity and low porosity.
The high porosity observed in SEM images and high surface areas obtained can be associated with the effect of glycolic acid in the sintering process [67] [68]. A higher release of ions is favored by larger BET areas, which favors the degradation of the material while providing molecules for the new bone formation [69] [70]. The synthesized material had a large number of interconnections between nanopores that allowed for vascularization, with increased osteoblast proliferation and differentiation throughout scaffolding. This increased oxygen transport and the flow of nutrients, while facilitating the elimination of waste. ARG. GLICO β-TCP’s high open porosity presented partial oxygen pressure inside the implant equal to outside the graft. Moreover, its architecture was closely related to the structure and morphology of the new bone tissue.
The larger microporosity and roughness of the pore wall (related with the BET area) obtained for the synthesized sample had a significant impact on the osteogenic response, since these large surface areas contributed to the adsorption of osteoinductive proteins, the exchange of ions, and the formation of apatite similar to bone tissue by dissolution and reprecipitation.
Bone regeneration in the area of critical cortical defects observed in both materials (Figure 9) confirmed the benefit of using biomaterials to fill bone defects and facilitate healing [71] - [78].
The clinical implications of this experimental work lie in the in vivo confirmation of the nanocharacteristics of the designed grafting material and the enhanced in vivo integration promoted by the nanoporosity of the material. Synthetic bone grafts should be customized to the specific site/patient requirements and adapted for the mechanical environment, in which they will function.
Future steps, including nanoindentation studies to know if there is plastic deformation on a nanometric scale, will provide additional light to the biomechanics of nanoporous β-TCP/CaPO4 mixtures.
5. Conclusion
In this work, a granulated bone grafting material based on β-TCP/CaPO4 mixtures was synthesized by chemical precipitation. The biomaterial obtained was resorbable with high purity, porous, and microcrystalline, which was formed from the reaction between calcium phosphate and glycolic acid, both precursors of technical grade and low cost. This bioceramic can be used as a graft for the replacement of lost bone tissue in humans. The histological and histomorphometric study of neoformed bone tissue and the remnant of the biomaterial were carried out during the first, second, and third months after implantation in tibias from New Zealand White rabbits. The new synthesized biphasic biomaterial used industrial-grade precursors that reduced manufacturing cost, possessing advantageous physical-chemical characteristics, mechanical properties, variable porosity, and appropriate bioactivity. In addition, it presented a smaller surface microstructure with 68 nm nanocrystals. The crystalline domain size of 120 nm obtained for the commercial bone graft formed a more extensive surface microstructure. No local inflammatory response was observed in any of the periods studied both in bone implantation of the biphasic graft and in the commercial graft. Therefore, the two grafts used were biocompatible. At 90 days (sufficient time for the healing of human bone defects) in the biphasic graft, no biomaterial remains were observed. Large residual particles (450 μm) were observed in the commercial graft.
Acknowledgements
The authors gratefully acknowledge the Laboratorio de Microscopía Electrónica y Análisis for Técnicas de Rayos X (LAMARX), the Centro Atómico Bariloche and the Area de Biología Odontológica Facultad de Odontología UNC, where measurements were carried out. We also thank the bioterio of the Neuroscience Laboratory of the Faculty of Medical Sciences of the Catholic University of Cuyo where experimental research in animals was carried out.