RESUMEN

Staphylococcus aureus and Staphylococcus epidermidis are human pathogens involved in implant-related infections. During those diseases, they are able to form biofilms showing resistance to the effect of many different antibiotics. Drug delivery systems allow a local and effective delivery of antibiotics at high concentrations in the infected tissue without causing the cytotoxic effects commonly linked to systemic administration. We report the use of a porous ceramic biomaterial, such as SBA-15 loaded with antibiotics, to deliver them directly to the infected tissue. SBA-15 discs were loaded with Vancomycin, Rifampin and a combination of both, introduced in a suspension of S. aureus 15981 and S. epidermidis ATCC 35984 and incubated during 6 and 24 h. A statistically significant decrease in the biofilm density and the number of viable bacteria was detected for all antibiotics at 6 h in both bacteria. Rifampin showed an increase in the biofilm density and the number of viable bacteria at 24 h. No differences were detected between Vancomycin and the combination of antibiotics. S. epidermidis was more sensitive to the effect of the antibiotics than S. aureus. Here we have demonstrated that SBA-15 is able to act as an effective drug delivery system not only from a pharmaceutical point of view, but also from a biological one.

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RESUMEN

Bone tissue regeneration requires the use of 3D scaffolds which mimic the architecture of the natural extracellular matrix, creating an adequate microenvironment for bone cell growth. Such 3D scaffolds need surface properties suitable for biological recognition in the early stage of cell adhesion, necessary to ensure complete cell colonization, retained cell functionality, and subsequently bone regeneration. Herein, hierarchical 3D scaffolds based on new hydroxyapatite/mesoporous glass nanocomposite bioceramic (MGHA) exhibiting different scales of porosity have been synthesized. These 3D scaffolds possess: (i) highly ordered mesopores with diameters of 10 nm; (ii) macropores with diameters in the 30-80 µm range with interconnections of 1-10 µm; and (iii) large macropores of ca. 500 µm. To improve their surface properties, 3D scaffolds were modified through direct functionalization with amine propyl groups, which notably improve preosteoblast adhesion, proliferation (2.3 fold), differentiation (4.8 fold) and further cell colonization of these scaffolds. The observed enhancement can be related to these amine groups which favour early adhesion, e.g., based on nonspecific protein adsorption as was demonstrated by ellipsometry. These results suggest that the combination of hierarchical structure design and amine surface modification of hydroxyapatite/mesoporous nanocomposite scaffolds yields a double increase in cell proliferation, as well as a quadruple increase in cell differentiation, demonstrating the potential of these nanocomposite materials for bone tissue regeneration purposes.

RESUMEN

Bone infections are a challenge for modern medicine. The most common pathogen is Staphylococcus aureus, which usually develops a biofilm inside the infected bone. Local release of antibiotics within the infected tissue may diminish this problem because high concentrations of the antibiotic would be delivered to the required place. This study was carried out to evaluate silica-based mesoporous material SBA-15 as a delivery system for three antibiotics with activity against S. aureus, namely vancomycin, rifampicin and linezolid, alone or in combination. SBA-15 disks were loaded with antibiotics by adsorption using a 1000 mg/L solution. Measurements of biological activity were carried out by bioassay tests, and antibiotic release was monitored by high-performance liquid chromatography (HPLC). In all cases, the ceramic disks released most of the antibiotics at the initial stage of the experiments, with concentrations above the susceptibility breakpoints. The most active antibiotic was rifampicin, with an active concentration of 96.14 mg/L at 24 h, followed by linezolid (7.2 mg/L) and vancomycin (5.5 mg/L). In the HPLC measurements, the antibiotic that showed the best release was linezolid, followed by vancomycin; rifampicin alone could not be measured by HPLC with precision. Taking into account all these results, the antibiotic that remains most active after loading and release is vancomycin (77.46%), followed by linezolid (24%). The results presented here demonstrate the efficacy of SBA-15 bioceramics for local release of antibiotics, which could be of interest in the context of bone infection.

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Parathyroid hormone-related protein (PTHrP) is an important regulator of bone remodeling. Recent studies show that this protein can induce osteogenic features through its N- and C-terminal domains. Silica-based ordered mesoporous bioceramics with an SBA-15 structure - known to be bioactive and biocompatible - have recently been evaluated for their capacity to uptake and deliver L-tryptophan. This amino acid corresponds to the end position of the 107-111 domain (called osteostatin) of the native C-terminal PTHrP (107-139) fragment, whose true action in bone metabolism is still ill-defined. In the present study, we assessed some effects of the aforementioned biomaterials pressed into disks, loaded or not with osteostatin, in osteoblastic cell cultures. Our data demonstrate that both unmodified and organically modified SBA-15 loaded with this peptide increase cell growth and the expression of several osteoblastic products (alkaline phosphatase, osteocalcin, collagen, osteoprotegerin, receptor activator of nuclear factor-kappaB ligand and vascular endothelial growth factor) in osteoblastic cells. These findings support the notion that osteostatin coating confers osteogenic features to silica-based ordered mesoporous materials, which make them suitable biomaterials for bone repair.

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