Advances in Bioscience and Biotechnology
Vol.1 No.3(2010), Article ID:2367,8 pages DOI:10.4236/abb.2010.13028

Silica matrix doped with calcium and phosphate by sol-gel

Lucimara C. Bandeira, Katia J. Ciuffi, Paulo S. Calefi, Eduardo J. Nassar*

 

Universidade de Franca, Av. Dr. Armando Salles Oliveira 201 Pq. Universitário, Franca, Brazil.

Email: ejnassar@unifran.br

Received 21 April 2010; revised 7 May 2010; accepted 10 May 2010.

Keywords: Luminescence; Biomaterials; Hydroxyapatite

ABSTRACT

Silica matrices doped with calcium and phosphate at various Ca/P molar ratios were prepared by the hydrolytic sol-gel methodology. Tetraethylorthosilicate (TEOS) was reacted with calcium ethoxide, in the presence of phosphoric acid as catalyst. Eu III ions were added to the resulting silica, in order to obtain structural information. The samples were dried at 50ºC and characterized before and after contact with Simulated Body Fluid (SBF). The xerogels were analyzed by thermal analysis (TA), X-ray diffraction (XRD), photoluminescence (PL), and scanning electron microscopy (SEM). The PL spectra revealed Eu III lines characteristic of the 5D0 ® 7FJ (J = 0, 1, 2, 3, 4) transition of this ion, and they indicated a nonhomogenous distribution of Eu III in the Ca-P-Si matrix. XRD and SEM confirmed the presence of an amorphous and crystalline system before and after contact of the samples with the SBF solution, and the crystalline phases were ascribed to hydroxyapatite and b-calcium triphosphate. The goal of the work is the preparation of a material can be used as biomaterias at low temperature.

1. INTRODUCTION

The bone tissue consists in the combination of a complex material containing an organic matrix (collagen) embedded with inorganic crystals of calcium phosphate (hydroxyapatite (HA) = Ca10(PO4)6(OH)2) [1]. HA is capable of stabilizing the structure of the bone, and it can occur as hydroxyapatite carbonate (HAC), which is present in the human body at 4-7%. HAC is known as biological hydroxyapatite (bio-HA), which also contains a small amount of sodium, potassium, magnesium, fluorite, and chlorate, all of which play an important role in the osteoinductivity of bio-HA [2-5].

HA has been used as bioactive ceramics since the 1970s because of its good biocompatibility; however, its can be easily dissolved in the body fluid. Bioactive glasses are more satisfactory in this sense, since the formation of silica on their surface promotes crystallization of apatite containing calcium and phosphate [6,7]. The formation of hydroxyapatite nanocrystals makes these glasses potentially useful biomaterials, because they promote a favorable environment for osteoconduction, protein adhesion, and osteoblast proliferation [8].

The combination of HA and CaCO3 with materials such as glasses, inorganic matrices, organic polymers, among others, results in biocompatible materials that facilitate biomineralization [9-13]. The sol-gel process, in turn, is an extremely interesting route for the synthesis of biomaterials due to the presence of hydroxyl groups in the silica matrix (Si-OH), which promote HA formation [14,15].

In this work, samples containing Si-Ca-P at different Ca/P molar ratios were prepared by the sol-gel route, by mixing tetraethylorthosilicate (TEOS), calcium ethoxide, and phosphoric acid. The synthesis consisted in hydrolysis and condensation of the alkoxide, using acid catalysis. Europium chloride was used as structural probe due to its luminescence properties and, because it can replace calcium ion in the phosphate, it furnishes information about the chemical surroundings of Ca II. The resulting xerogel structure, obtained at low temperature, was analyzed by thermal analysis (TG), X-ray diffraction (XRD), photoluminescence (PL), and scanning electron microscopy (SEM), before and after contact with Standard Body Fluid (SBF).

2. MATERIALS AND METHODS

2.1. Sample Preparation

The reagents were purchase at analytical grade (SigmaAldrich).

The samples were prepared with Ca/P molar ratios equal to or different from that encountered in natural hydroxyapatite. The sample denominated HA= had the same Ca/P molar ratio as HA, HAsample had less Ca/P and the HA+ sample had more Ca/P than HA. The three samples, HA=, HA+ and HA-, were synthesized by the sol-gel route. To this end, 9.60 × 10-3 mols TEOS, 3.84 × 10-3 mols calcium ethoxide, and 6.06 × 10-4 (HA-), 6.73 × 10-4 (HA=) or 7.40 × 10-4 (HA+) mols phosphoric acid were added to 16.0 mL ethanol (solvent), under stirring. The resulting materials were dried at 50ºC for 1 day. 1% Europium III chloride was added before gelation, in ethanolic solution, the Eu III ion can replace Ca II ion and used as structural probe.

The samples were obtained the powder form and analyzed by Thermal Analysis (TG), X-Ray Diffraction (XRD), Photoluminescence (PL), and Scanning Electron Microscopy (SEM). They were then immersed in SBF [16], pH = 7.40 at 37ºC, 0.10 g of the powder was put in 10 mL of SBF solution for 19 days. The samples were characterized before and after contact with SBF.

2.2. Characterizations

2.2.1. X-ray Diffraction (XRD)

The XRD measurements were accomplished at room temperature, with 2θ values ranging from 4 to 80º at a resolution of 0.05º, using a Rigaku Geigerflex D/max-c diffractometer employing monochromated CuKa radiation (λ = 1.54Å).

2.2.2. Thermal Analysis (TG)

Thermal analysis (TG) was carried out in a thermal analyzer (TA – Instruments – SDT Q600 – Simultaneous DTA-TG) in nitrogen atmosphere, at a heating rate of 20ºC/min, from 25 to 1100ºC.

2.2.3. Photoluminescence (PL)

Photoluminescence data were obtained under continuous Xe lamp (450W) excitation in a spectrofluometer SPEX – Fluorolog II, at room temperature. The emission was collected at 90ºC from the excitation beam. The slits were placed at 2.0 and 0.5 mm for excitation and emission, respectively, giving a band width of 7.0 and 1.0 nm. Oriel 58916 (exc.) and Corning 97612 (em.) filters were employed. Decay curves were measured with a SPEX 1934 phosphorimeter, Xe lamp (5 J/pulse).

2.2.4. Scanning Electron Microscopy (SEM)

SEM analysis was performed with a Jeol JSM-T330A microscope, in order to investigate the morphology of the system.

3. RESULTS AND DISCUSSION

3.1. X-ray Diffraction (XRD)

Figure 1 shows the XRD patterns for the samples prepared with different Ca/P molar ratios, before contact with the SBF solution.

The three starting powders present crystalline and amorphous phases, with well-defined diffraction peaks. The crystalline phase displays peaks at 2q = 26.5, 32.5, 33.0, 49.2, and 53.1, which can be ascribed to hydroxyapatite (HA), whereas the peaks corresponding to calcium triphosphate (TCP-b) appear at 2q = 26.5, 30.2,

Figure 1. X-ray diffraction of the samples. (a) = HA; (b) HA-; (c) HA+ before contact with SBF.

and 53.1 [17]. Several other peaks due to other phosphate silicates, such as Ca5(PO4)2SiO4 and (Ca2(SiO4))6 (Ca3(PO4)2), can also be observed.

In a previous work, we observed formation of crystalline phases only after sample contact with the SBF solution, but in that case the amount of phosphate in relation to calcium in the material was about 1% only [13]. The high percentages of phosphate ions (40%) in the present samples were crucial to the precipitation of crystalline phosphate nanoparticles in the silica matrix. However, according to literature reports, the double P=O bond favors phosphate phase formation in the silica network, thus increasing the tendency toward crystallization [18].

The peak broadening of the XRD reflection can be used to estimate crystallite size in a direction perpendicular to the crystallographic plane, based on the Scherrer equation:

             L = Kl/bcosq                                                               (1)

where L denotes the average crystallite size, l represents the wavelength of the X-ray radiation (l = 0.154056 nm), K is a constant related to crystallite shape and is approximately equal to unity. b, which is experimentally measured, is the full width of the peak at half of the maximum intensity (rad) and is expressed in its squared form as a squared sum function of the two main contributions, according to Eq.2 depicted below. In the latter equation, b1 represents the crystallite size contribution to the peak broadening, while b2 is the instrumental broadening contribution [19].

b = b12 + b22                                                               (2)

On the basis of the XRD data, the average crystallite size was calculated as being approximately 2 nm, indicating the formation of calcium phosphate nanoparticles.

3.2. Scanning Electronic Microscopy (SEM)

The morphology of the system was investigated by SEM. Figure 2 depicts the micrographs obtained for the sam-

(a)(b)(c)

Figure 2. Micrographs of the samples. (a) = HA white field; (b) HA-white field; (c) HA+ dark field, before contact with SBF.

ples prepared with different Ca/P molar ratios, before contact with the SBF solution.

The SEM micrographs reveal the presence of crystalline nanoparticles with an average size of 2 nm, as evidenced by XRD. An amorphous phase is also detected. Crystal particles are also observed by electron diffraction, thus confirming the XRD results.

3.3. Thermal Analysis (TG/DTG)

Figures 3(a), (b) and (c) present the thermogravimetric (curve TG) and its derivative (DTG) for the starting samples, before contact with the SBF solution.

(a)(b)(c)

Figure 3. TG (Solid line) and DTG (Dotted line) curves of the samples. (a) = HA; (b) HA-; (c) HA+ before contact with the SBF solution.

The thermogravimetric curve and its derivative reveal three distinct weight loss stages for all the samples. The first loss occurs at 100ºC and is ascribed to water and solvent molecules adsorbed on the matrix. The other stages, which took place between 200 and 650ºC, are possibly due to the decomposition of residual organic groups of the precursor. The HA= and HA+ samples have a total weight loss of 35%, while the HAsample presents a total weight loss of 40%. Nevertheless, the initial weight loss for the samples HAand HA+ was the same: 15%. The presence of phosphate ion at Ca/P molar ratios different from that encountered in natural HA may have contributed to the incomplete polycondensation of the silica matrix. This may have led to a larger quantity of residual –OH groups on the surface of the matrix and thus a larger number of water molecules adsorbed on the silica surface.

3.4. Photoluminescence (PL)

Figures 4 and 5 respectively show the excitation and emission spectra of the samples HA=, HA+, and HAprepared by the sol-gel method, doped with Eu III ions, before contact with the SBF solution. The maximum emission occurs at 590 nm (5D0 ® 7F1), while the maximum excitation takes place at 394 nm (5L6 level). The intensities of the emission bands were normalized.

The emission spectra display transitions arising from 5D0 to 7FJ (J = 0, 1, 2, 3, and 4) manifolds. There are three main transitions, namely 5D07F0 (around 570 nm), 5D07F1 (around 595 nm), and 5D07F2 (around 610 nm). The first is a strongly forbidden transition not yet observed with appreciable intensity in some hosts. The 5D07F1 transition is forbidden as electric dipole, but allowed as magnetic dipole. This is the only transition that takes place when Eu III occupies a site coinciding with a symmetry centre. When the Eu III ion is situated at a site lacking an inversion centre, the transition corresponding to even J values (except 0) are electric dipole allowed, and red emission can be observed. The 5D07F1 transition can also be observed as a magnetic dipole allowed transition. Further on, all the lines corresponding to this transition split into a number

Figure 4. Excitation spectra of the samples. (a) = HA; (b) HA-; (c) HA+ doped with Eu III ions before contact with the SBF solution, λem. = 590 nm.

Figure 5" target="_self"> Figure 5. Emission spectra of the samples. (a) = HA; (b) HA-; (c) HA+ doped with Eu III ions before contact with the SBF solution, λexc. = 394 nm.

of components depending on the local symmetry [20].

When Eu III is located at a low symmetry site (without an inversion center), the 5D07F2 emission transition often predominates in the emission spectrum, so the Eu III ions occupy a non-inversion symmetric site [21]. The 5D07F0 transition of Eu III is only allowed in the case of Cs, Cn and Cnv symmetries of the Eu III sites in the crystalline state [22]. The hexagonal unit-cell HA contains ten cations distributed between two crystallographic sites: four on type (1) sites and six on type (2) sites. Ca (1) ions present C3 symmetry and are surrounded by nine oxygen atoms. Ca (2) ions present Cs symmetry and are surrounded by six oxygen atoms [23- 25]. There are literature reports stating that Ca (1) and Ca (2) ions (r = 0.99 Ǻ) can be replaced with Pb II (r = 1.2 Ǻ) [26], so the Eu III ion (r = 0.95Ǻ) [27] can also occupy the Ca II sites in the crystalline hydroxyapatite and b-TCP, as well as in amorphous silica. The emission spectra of Eu3+ is not similar in glasses hosts, as discussed in literature [28-30].

The Eu III emission bands in the spectra of Figure 5 reveal a nonhomogenous distribution of the ion in the Si-Ca-P matrix [31-33].

Because of its electrical-dipole nature [34], the relative intensity of the 5D0 ® 7F0 and 5D0 ® 7F2 transitions is strongly dependent on the Eu III surroundings. In contrast, the band corresponding to the 5D0 ® 7F1 transition has a magnetic-dipolar nature whose intensity is unaffected by the ion’s surroundings. Therefore, the latter transition can be considered a standard to measure the relative intensity of the other bands [35,36], and the 5D0 ® 7F2 emission intensity can thus provide valuable information about environmental changes around the Eu III ions. Table 1 shows the intensity of the 5D0 ® 7F0 and 5D0 ® 7F2 transitions relative to the 5D0 ® 7F1 transition.

Table 1. Relative intensity of the 5D0®7F0 and 5D0 ® 7F2 transitions with respect to the 5D0®7F1 transition in the emission spectra of the samples HA=, HA+ and HAdoped with Eu III, before contact with SBF.

The similar relative intensities of the transitions indicate that the environment around the Eu III ion is similar in the three samples, and the ion can be located either in the silica matrix or in calcium phosphate.

The characterized samples were then placed in SBF solution for 19 days, followed by characterization using the same techniques mentioned above.

3.5. XRD and TEM

Figure 6 depicts the XRD patterns for the samples prepared with different Ca/P molar ratios, after contact with the SBF solution.

The XRD patterns depicted in Figure 6 display the same peaks observed for the samples not submitted to contact with SBF solution. Therefore, the crystalline phase formed during the sol-gel process remains intact in the silica matrix after sample immersion into SBF. TEM analysis also reveals that the crystalline phase does not disappear after contact with the SBF solution, and the presence of calcium phosphate nanoparticles in the samples is confirmed by this technique. Furthermore, the Sherrer formula corroborates the average size of the crystalline particles, which is 2 nm.

3.6. Thermal Analysis

Figures 7a, b and c present the thermogravimetric curve (TG) and its derivative (DTG) for the three samples,

Figure 6. X-ray diffraction of the samples. (a) = HA; (b) HA-; (c) HA+, after contact with SBF.

(a) (b) (c)

Figure 7. TG (Solid line) and DTG (Dotted line) curves of the samples. (a) = HA; (b) HA-; (c) HA+ after contact with the SBF solution.

after contact with the SBF solution.

The thermogravimetric curve and its derivative give evidence of two weight losses for all the samples. The main loss occurs at about 100ºC, ascribed to water molecules and solvent. As for the second weight loss stage, it took place between 200 and 650ºC before the samples were immersed into SBF and the weight loss percentage was 20%. After contact with the SBF solution, this weight loss percentage reduced to 7% in the same temperature range. An exchange between the solid sample and the SBF solution probably occurred, with residual product being removed from the silica matrix after contact.

3.7. Photoluminescence (PL)

Figures 8 and 9 respectively show the excitation and emission spectra of the samples HA=, HA+, and HAprepared by the sol-gel method, doped with Eu III ions, after contact with the SBF solution. The maximum emission occurs at 590 nm (5D0 ® 7F1), while the maximum excitation takes place at 394 nm (5L6 level). The intensities of the emission bands were normalized.

The emission spectra display transitions arising from 5D0 to 7FJ (J = 0, 1, 2, 3, and 4) manifolds. The Eu III emission bands in the spectra of Figure 9 are characteristic of a nonhomogenous distribution of this ion in the Si-Ca-P matrix, as observed for the samples before contact with the SBF solution.

The relative intensity of the 5D0 ® 7F0 and 5D0 ®7F2

Figure 8. Excitation spectra of the samples. (a) HA=; (b) HA-; (c) HA+ doped with Eu III ions after contact with SBF solution, λem. = 590 nm.

Figure 9. Emission spectra of the samples. (a) = HA; (b) HA-; (c) HA+ doped with Eu III ions after contact with the SBF solution, λexc. = 394 nm.

Table 2. Relative intensity of the 5D0®7F0 and 5D0 ® 7Ftransitions with respect to the 5D0®7F1 transition in the emission spectra of the samples HA=, HA+ and HAdoped with Eu III, after contact with SBF.

transitions was obtained by measuring the area under the emission band. Table 2 shows the intensity of the 5D0 ® 7F0 and 5D0 ® 7F2 transitions relative to the 5D0 ® 7F1 transition.

There were only slight changes in the relative intensity of the emission bands, indicating that the environment around the Eu III ion is not affected upon contact of the samples with the SBF solution. This is because Eu III probably occupies a stable site in the matrix and in the phosphate nanoparticles. The change in the relative intensity of the 5D0 ® 7F0 and 5D0 ® 7F2 transitions was more significant for the sample HA=, which can be ascribed to possible dissolution of the matrix and phosphate into the SBF solution, as discussed in the literature [18].

4. CONCLUSIONS

The concentration of phosphate ions is crucial to the formation of crystalline calcium phosphate in the silica matrix, when compared with results from a previous work. The formation of nanocrystals is very important for the future application of these solids as biomaterials.

The Eu III ion can occupy different sites in these materials; that is, it can replace the calcium ion in the phosphate or in the matrix.

Thermal analysis revealed that residues from the synthesis can be removed after washing with water, but this does not affect nanocrystal formation.

The period during which the materials remain in contact with the SBF solution is not sufficient to promote their reaction with the solution. Literature reports mention that biomaterials need to be placed in SBF for a certain contact time before calcium phosphate starts to precipitate, but this process depends on sample composition. In our case, the sample HA=, which contains the same Ca/P molar ratio as natural HA, seems to undergo dissolution after a certain contact time with SBF, and we think that a longer contact time could lead to reprecipitation of the HA.

5. ACKNOWLEDGEMENTS

The authors acknowledge FAPESP, CNPq and CAPES (Brazilian research funding agencies) for their financial support of this work.

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