Barbara Bracci

Strontium-substituted hydroxyapatite coatings synthesized by pulsed-laser deposition: In vitro osteoblast and osteoclast response

The increasing interest in strontium incorporation into biomaterials for hard tissue repair is justified by the growing evidence of its beneficial effect on bone. We successfully synthesized hydroxyapatite (HA) thin films with different extents of strontium substitution for calcium (0, 1, 3 or 7 at.%) by pulsed-laser deposition. The coatings displayed a granular surface and a good degree of crystallinity, which slightly diminished as strontium content increased. Osteoblast-like MG63 cells and human osteoclasts were cultured on the thin films up to 21 days. MG63 cells grown on the strontium-doped HA coatings displayed normal morphology, good proliferation and increased values of the differentiation parameters, whereas the number of osteoclasts was negatively influenced by the presence of strontium. The positive effect of the ion on bone cells was particularly evident in the case of coatings deposited from HA at relatively high strontium contents (3-7%), where significantly increased values of alkaline phosphatase activity, osteocalcin, type I collagen and osteoprotegerin/TNF-related activation-induced cytokine receptor ratio, and considerably reduced values of osteoclast proliferation, were observed.

Effect of Mg2+, Sr2+, and Mn2+ on the chemico-physical and in vitro biological properties of calcium phosphate biomimetic coatings

We previously developed a calcium phosphate (CaP) calcifying solution that allows to deposit a uniform layer of nanocrystalline apatite on metallic implants in a few hours. In this work we modified the composition of the CaP solution by addition of Sr(2+), Mg(2+), and Mn(2+), in order to improve the biological performance of the implants. The results of the investigation performed on the coatings, as well as on the powders precipitated in the absence of the substrates, indicate that both Sr(2+) and Mg(2+) reduce the extent of precipitation, although they are quantitatively incorporated into the nanocrystalline apatitic phase. The inhibitory effect on deposition is much more evident for Mn(2+), which completely hinders the precipitation of apatite and yields just a small amount of amorphous phosphate relatively rich in manganese content. Human osteoblast-like MG-63 cells cultured on the different materials show that the Mg(2+) and Sr(2+) apatitic coatings promote proliferation and expression of collagen type I, with respect to bare Ti and to the thin layer of amorphous phosphate obtained in the presence of Mn(2+). However, the relatively high content of Mn(2+) in the phosphate has a remarkable beneficial effect on osteocalcin production, which is even greater than that observed for Sr(2+).

Drawn gelatin films with improved mechanical properties

Chain anisotropic distribution in gelatin films has been obtained by uniaxial stretching at constant relative humidity, followed by air drying and successive cross-linking with glutaraldehyde. The drawn samples have been characterized by mechanical tests, differential scanning calorimetry and scanning electron microscopy. The Youngs modulus, E, and the stress at break, sigma(b), increase linearly with the draw ratio and reach values which are about five times those characteristic of undrawn samples. Furthermore, on stretching the alignment of the gelatin strands along the direction of deformation increases while the thickness of the layers decreases significantly. The renaturation level, that is the fraction of gelatin in a collagen-like structure, has been calculated as the ratio between the melting enthalpy of gelatin samples and that of tendon collagen. The results indicate that the improvement of mechanical properties achieved by drawn gelatin is closely related to the renaturation level. The experimental approach utilized to induce segmental orientation in gelatin films, allows to obtain anisotropic materials with improved mechanical properties in the direction of deformation, and can be usefully applied in the preparation of biomaterials.

Alendronate and Pamidronate calcium phosphate bone cements : Setting properties and in vitro response of osteoblast and osteoclast cells

We have investigated the effect of Alendronate and Pamidronate, two bisphosphonates widely employed for the treatment of pathologies related to bone loss, on the setting properties and in vitro bioactivity of a calcium phosphate bone cement. The cement composition includes alpha-tricalcium phosphate (alpha-TCP) (90 wt%), nanocrystalline hydroxyapatite (5 wt%) and CaHPO(4) x 2H(2)O (5 wt%). Disodium Alendronate and disodium Pamidronate were added to the liquid phase (bidistilled water) at two different concentrations: 0.4 and 1mM (AL0.4, AL1.0, PAM0.4, PAM1.0). Both the initial and the final setting times of the bisphosphonate-containing cements increase with respect to the control cement. X-ray diffraction analysis, mechanical tests, and SEM investigations were carried out on the cements after different times of soaking in physiological solution. The rate of transformation of alpha-TCP into calcium deficient hydroxyapatite, as well as the microstructure of the cements, is not affected by the presence of Alendronate and Pamidronate. At variance, the bisphosphonates provoke a modest worsening of the mechanical properties. MG63 osteoblasts grown on the cements show a normal morphology and biological tests demonstrate very good rate of proliferation and viability in every experimental time. In particular, both Alendronate and Pamidronate promote osteoblast proliferation and differentiation, whereas they inhibit osteoclastogenesis and osteoclast function.

Porous composite scaffolds based on gelatin and partially hydrolyzed α-tricalcium phosphate

Porous composite scaffolds of varying compositions were prepared by freeze-drying gelatin foams containing increasing amounts of alpha-tricalcium phosphate (alpha-TCP), up to about 40 wt.%. Due to the presence of gelatin, a partial hydrolysis of alpha-TCP into octacalcium phosphate (OCP) occurs during foaming. As a consequence, the scaffolds contain both alpha-TCP and OCP, in relative amounts of about 74% and 26%, respectively, independent of the initial composition. In physiological conditions the inorganic component of the scaffolds undergoes a further hydrolysis as shown by the finding that after immersion in phosphate-buffered saline at 37 degrees C for 1 week the scaffolds contain poorly crystalline hydroxyapatite together with OCP. The scaffolds display a porous interconnected microstructure. The mean dimensions of the pores decrease from about 350 to about 170 microm as the inorganic phase content increases. Simultaneously, the mean values of the compression strength and Youngs modulus increase. Stabilization of the scaffolds was obtained by using a natural, non-toxic, crosslinking agent, genipin, which significantly improves their mechanical properties.

Functionalization of biomimetic calcium phosphate bone cements with alendronate

Bisphosphonates (BPs) are widely employed for the treatment of a variety of bone disorders. We have previously successfully added small amounts of BPs into calcium phosphate bone cements in order to enhance their bio-functionality. In this work we were able to increase greatly the amount of BP introduced in the cement, thanks to suitable modifications of composition. In particular, we utilized biomimetic alpha-tricalcium phosphate (alpha-TCP) cements at different gelatin contents (10, 15 and 20 wt.%) to introduce Disodium Alendronate up to a concentration of 25 mM. Due to the small liquid/powder ratio (0.22 ml/g) the lengthening of the setting times due to alendronate is quite modest. The rate of transformation of alpha-TCP into calcium deficient hydroxyapatite slightly decreases as a function of alendronate content, whereas it increases with increasing gelatin concentration. Moreover, relatively high alendronate concentrations provoke significant reduction of the compressive strength of the cements. The results of in vitro tests indicate that alendronate-containing cements significantly affect osteoclast proliferation and differentiation, whereas they promote osteoblast differentiation, to an extent which depends on cement composition.

Interaction of acidic poly-amino acids with octacalcium phosphate.

Octacalcium phosphate (OCP) hydrolysis into hydroxyapatite (HA) has been investigated in aqueous solutions at different concentrations of poly-L-aspartate (PASP) and poly-L-glutamate (PGLU). In the absence of the polyelectrolytes, the transformation of OCP into HA is complete in 48 h. Both poly-L-aspartate and poly-L-glutamate inhibit OCP hydrolysis. However, PGLU displays a greater inhibiting effect, as a result of the different extent of phase transformation obtained at the same polyelectrolyte concentration. The inhibition takes place through polyelectrolyte adsorption on the (100) face of OCP crystals, which prevents the splitting of OCP crystals along their c-axis and the transformation into the final very long, needle-like, apatitic crystals.

THE STATE OF WATER IN THERMORESPONSIVE POLY(ACRYLOYL-L-PROLINE METHYL ESTER) HYDROGELS OBSERVED BY DSC AND 1H-NMR RELAXOMETRY

Hydrogels that reversibly swell or shrink in water with decreasing or increasing temperature, respectively, were obtained by γ ray-induced polymerization of acryloyl-l-proline methyl ester in the presence of different amounts of a crosslinking agent. The role of water in the hydrated polymers was investigated by DSC and 1H-NMR relaxometry. From the curves of fusion of water determined by the former it was possible to ascertain that the amount of both freezing and non freezing water decreased with increasing the crosslinker percentage and/or swelling temperature. Moreover, at the temperatures higher than 37°C, the water absorbed by the different hydrogels is mostly present as non freezing water. The 1H-NMR relaxometry study enabled the spin–spin and spin–lattice relaxation curves to be analyzed. It was possible to distinguish three “populations” of protons and identify two of them with protons of freezing and non freezing water determined by DCS.

Optimization of a biomimetic bone cement: Role of DCPD

We previously proposed a biomimetic α-tricalcium phosphate (α-TCP) bone cement where gelatin controls the transformation of α-TCP into calcium deficient hydroxyapatite (CDHA), leading to improved mechanical properties. In this study we investigated the setting and hardening processes of biomimetic cements containing increasing amounts of CaHPO(4)·2H2O (DCPD) (0, 2.5, 5, 10, 15 wt.%), with the aim to optimize composition. Both initial and final setting times increased significantly when DCPD content accounts for 10 wt.%, whereas cements containing 15 wt.% DCPD did not set at all. Differential scanning calorimetry (DSC), X-ray diffraction (XRD), thermogravimetry (TG) and scanning electron microscopy (SEM) investigations were performed on samples maintained in physiological solution for different times. DCPD dissolution starts soon after cement preparation, but the rate of transformation decreases on increasing DCPD initial content in the samples. The rate of α-TCP to CDHA conversion during hardening decreases on increasing DCPD initial content. Moreover, the presence of DCPD prevents gelatin release during hardening. The combined effects of gelatin and DCPD on the rate of CDHA formation and porosity lead to significantly improved mechanical properties, with the best composition displaying a compressive strength of 35 MPa and a Young modulus of 1600 MPa.

In vitro mineralization of gelatin-polyacrylic acid complex matrices

Gelatin-polyacrylic acid (gel-PAA) matrices were obtained by slow diffusion of polyacrylic acid into gelatin gels. The matrices were submitted to uniaxial stretching, which induces a preferential orientation of the collagen molecules, and used as biomimetic substrates for the nucleation of hydroxyapatite from simulated body fluid (SBF). The relative amount of hydroxyapatite deposited from 1.5SBF increases as a function of polyelectrolyte content in the matrices, up to about 30 wt%. In the absence of PAA, the inorganic phase is laid down on the surface of the gelatin matrices as hemispherical aggregates. At variance, hydroxyapatite deposition in the gel-PAA composite matrices at relatively low PAA content occurs preferentially in the spaces between the layers on the surface of the matrices and displays a tablet-like morphology. At high polyelectrolyte concentration, an almost uniform layer of hydroxyapatite covers the whole surface of the matrices. The preferential orientation of the (002) hydroxyapatite reflection indicates a close relationship between the inorganic crystals and the collagen molecules.