Juan C. Doadrio

The osteoinductive properties of mesoporous silicate coated with osteostatin in a rabbit femur cavity defect model.

Parathyroid hormone-related protein (PTHrP) is an important regulator of bone formation and remodeling. Our recent findings demonstrate that PTHrP (107-111) (osteostatin) loaded onto silica-based ordered mesoporous SBA15 materials exhibit osteogenic features in osteoblastic cell cultures. We aimed here to elucidate whether these peptide-coated materials might be suitable for promoting bone repair following a cavitary defect in the rabbit femur. Histological examination revealed the absence of significant inflammation or bone resorption within the time of study (4 and 8 weeks) after implantation. At 8 weeks, the peptide-unloaded materials were still separated from the bone marrow by a fibrous cap, which was greatly diminished by the presence of the PTHrP peptide. By using μCT analysis, new bone formation was evident at different distances from the implants, mainly for the latter peptide-loaded biomaterials. This was confirmed by performing immunostaining for different osteoblast markers. Our findings demonstrate that these PTHrP (107-111)-loaded bioceramics significantly improve local bone induction, as compared to that observed with the unloaded material.

Usefulness of SBA-15 mesoporous ceramics as a delivery system for vancomycin, rifampicin and linezolid: a preliminary report

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.

Osteostatin-loaded onto mesoporous ceramics improves the early phase of bone regeneration in a rabbit osteopenia model.

Parathyroid hormone-related protein (PTHrP) is an important modulator of bone formation. Recently, we reported that PTHrP (107-111) (osteostatin) coating onto mesoporous ceramics confers osteogenic activity to these materials. Bone repair is dramatically compromised in osteopenia/osteoporosis. Thus, we examined the efficacy of unmodified and organically modified SBA15 ceramics loaded with osteostatin in promoting bone repair in an osteoporotic rabbit model. Osteoporosis was induced in New Zealand rabbits by methylprednisolone administration, and healthy rabbits were used as controls. Tested materials were implanted into a femoral cavitary defect, and animals were sacrificed at 2 weeks post-implantation. At this time, implants were encapsulated by a variable layer of fibrotic tissue with no evidence of inflammation. Similarly to observations in normal rabbits, both types of osteostatin-loaded bioceramics induced tissue regeneration associated with increased staining for PCNA, Runx2, osteopontin, and/or vascular endothelial growth factor in osteoporotic rabbits. Our present findings demonstrate that these osteostatin-bearing bioceramics increase the early repair response not only in normal bone but also in osteoporotic bone after a local injury.

Bioactivity and mechanical properties of SiO2–CaO–P2O5 glass-ceramics

Glass-ceramics in the system SiO2–CaO–P2O5, with 55 mol% of silicon content, with and without phosphorus, were obtained by thermal treatment of sol–gel glasses as the precursors. The influence of the composition of the precursor glass on the crystallisation, bioactive behaviour and mechanical properties of these glass-ceramics was investigated. An interesting result is that when phosphorus was not present in the precursor glass, the biaxial flexural strength of the glass-ceramics increased by one order of magnitude. The crystalline phases obtained were similar in both glass-ceramics, although when phosphorus was present the crystallisation of tricalcium phosphate and the stabilisation of the Wollastonite phase at high temperature in the glass-ceramic took place Both glass-ceramics, without and with phosphorus, showed a fast in vitro bioactive response; a new apatite-like layer fully covered the surface of both materials after soaking in simulated body fluid for a short time. The rate of the apatite layer formation mainly depended on the sintering process, which took place at lower temperatures in the glass-ceramics without phosphorus. The glass-ceramics containing phosphorus showed a decrease in the values of the Weibull coefficient, an increase of porosity and pore size, and a heterogeneous microstructure, worsening their mechanical properties.

Tailoring hierarchical meso–macroporous 3D scaffolds: from nano to macro

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.

Bacterial adherence to SiO2-based multifunctional bioceramics.

The bacterial adherence onto different multifunctional silica-based bioceramics has been evaluated. Staphylococcus aureus and Staphylococcus epidermidis were chosen, as they cause the majority of the implant-related infections in this field. Two SiO2 mesoporous materials (MCM-41, SBA-15), an ordered SiO2-CaO-P2O5 mesoporous glass (OMG), and a biphasic magnetic bioceramic (BMB), were incubated with S. aureus and S. epidermidis for 90 min, and subsequently sonicated to quantify the number of adhered bacteria on each material. It was found that S. aureus and S. epidermidis (10(8) CFU/mL) adhered significantly less to BMB samples when compared to MCM-41, SBA-15, or OMG. However, when the material pores accessible for bacteria in each material were taken into account, the lowest bacterial adherence was found in MCM-41, and the highest in SBA-15. The results show that bacterial adherence is higher on mesoporous bioceramics, although this higher microbial attachment is mainly due to the intergranular porosity and grain size morphology rather than to the mesoporous structure.

Mesoporous silica nanoparticles as a new carrier methodology in the controlled release of the active components in a polypill

&NA; Polypill is a medication designed for preventing heart attacks through a combination of drugs. Current formulations contain blood pressure‐lowering drugs and others, such statins or acetylsalicylic acid. These drugs exhibit different physical chemical features, and consequently different release kinetics. Therefore, the concentration in plasma of some of them after the release process can be out of the therapeutic range. This paper investigates a new methodology for the control dosage of a polypill recently reported containing hydrochlorothiazide, amlodipine, losartan and simvastatin in a 12.5/2.5/25/40 weight ratio. The procedure is based on mesoporous silica nanoparticles (MSN) with MCM‐41 structure (MSN‐41) used as carrier, aimed to control release of the four drugs included in the polypill. In vitro release data were obtained by HPLC and the curves adjusted with a kinetic model. To explain the release results, a molecular model was built to determine the drug‐matrix interactions, and quantum mechanical calculations were performed to obtain the electrostatic properties of each drug. Amlodipine, losartan and simvastatin were released from the polypill‐MSN‐41 system in a controlled way. This would be a favourable behavior when used clinically because avoid too quick pressure decrease. However, the diuretic hydrochlorothiazide was quickly released from our system in the first minutes, as is needed in hypertensive urgencies. In addition, an increase in the stability of amlodipine and hydrochlorothiazide occurred in the polypill‐MSN‐41 system. Therefore, the new way of polypill dosage proposed can result in a safer and effective treatment. Graphical abstract Figure. No caption available.

Multifunctional pH sensitive 3D scaffolds for treatment and prevention of bone infection

Multifunctional-therapeutic three-dimensional (3D) scaffolds have been prepared. These biomaterials are able to destroy the S. aureus bacterial biofilm and to allow bone regeneration at the same time. The present study is focused on the design of pH sensitive 3D hierarchical meso-macroporous 3D scaffolds based on MGHA nanocomposite formed by a mesostructured glassy network with embedded hydroxyapatite nanoparticles, whose mesopores have been loaded with levofloxacin (Levo) as antibacterial agent. These 3D platforms exhibit controlled and pH-dependent Levo release, sustained over time at physiological pH (7.4) and notably increased at infection pH (6.7 and 5.5), which is due to the different interaction rate between diverse Levo species and the silica matrix. These 3D systems are able to inhibit the S. aureus growth and to destroy the bacterial biofilm without cytotoxic effects on human osteoblasts and allowing an adequate colonization and differentiation of preosteoblastic cells on their surface. These findings suggest promising applications of these hierarchical MGHA nanocomposite 3D scaffolds for the treatment and prevention of bone infection. STATEMENT OF SIGNIFICANCE Multifunctional 3D nanocomposite scaffolds with the ability for loading and sustained delivery of an antimicrobial agent, to eliminate and prevent bone infection and at the same time to contribute to bone regeneration process without cytotoxic effects on the surrounding tissue has been proposed. These 3D scaffolds exhibit a sustained levofloxacin delivery at physiological pH (pH 7.4), which increasing notably when pH decreases to characteristic values of bone infection process (pH 6.7 and pH 5.5). In vitro competitive assays between preosteoblastic and bacteria onto the 3D scaffold surface demonstrated an adequate osteoblast colonization in entire scaffold surface together with the ability to eliminate bacteria contamination.

Antibacterial effect of antibiotic-loaded SBA-15 on biofilm formation by Staphylococcus aureus and Staphylococcus epidermidis

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.