pH-controlled delivery of gentamicin sulfate from orthopedic devices preventing nosocomial infections.

Since the beginning of the 1970s, controlled release technology has witnessed great advancement, and motivated numerous researchers in materials science. These systems overcome the drawbacks of traditional drug dosage form, and offer more effective and favorable methods to optimize drug delivery in optimum dose to specific sites or to prolong delivery duration. This paper deals with the synthesis of pH-controlled drug delivery systems for bone implant, allowing the local release of gentamicin sulfate (GS), an antibiotic commonly used to prevent infections during orthopedic surgeries. We present a biomaterial synthesis allowing the controlled release of GS at the site of surgical implantation (over an adjustable period of time). In our design, spherical nanoparticles (NPs) functionalized by the chosen antibiotic (Gentamicin sulfate, GS), are chemically anchored to the biomaterial surface. A cleavage reaction of the chemical bond between NPs and GS, effected by the contact of material with a solution presenting an acidic pH (in the case of infection, there is a decrease of the physiological medium pH), induces controlled release of the bioactive molecule in its native form. In this paper, we discuss the synthesis of a bioactive titanium based biomaterial in general, and the grafting of the NPs onto the titanium surfaces in particular. We have paid particular attention to the characterization of the drug surface density and the release kinetic of the active molecule as a function of the pH. In vitro bacterial growth inhibition tests after GS delivery at acidic pH (with Staphylococcus aureus) have also been carried out in order to prove the efficiency of such biomaterials.

Altered nanofeature size dictates stem cell differentiation.

The differentiation of stem cells can be modulated by physical factors such as the micro- and nano-topography of the extracellular matrix. One important goal in stem cell research is to understand the concept that directs differentiation into a specific cell lineage in the nanoscale environment. Here, we demonstrate that such paths exist by controlling only the micro- and nano-topography of polymer surfaces. Altering the depth (on a nanometric scale) of micro-patterned surface structures allowed increased adhesion of human mesenchymal stem cells (hMSCs) with specific differentiation into osteoblasts, in the absence of osteogenic medium. Small (10 nm) depth patterns promoted cell adhesion without noticeable differentiation, whereas larger depth patterns (100 nm) elicited a collective cell organization, which induced selective differentiation into osteoblast-like cells. This latter response was dictated by stress through focal-adhesion-induced reorganization of F-actin filaments. The results have significant implications for understanding the architectural effects of the in vivo microenvironment and also for the therapeutic use of stem cells.

Cytotoxicity and oxidative stress induced by different metallic nanoparticles on human kidney cells.

BACKGROUND: Some manufactured nanoparticles are metal-based and have a wide variety of applications in electronic, engineering and medicine. Until now, many studies have described the potential toxicity of NPs on pulmonary target, while little attention has been paid to kidney which is considered to be a secondary target organ. The objective of this study, on human renal culture cells, was to assess the toxicity profile of metallic nanoparticles (TiO2, ZnO and CdS) usable in industrial production. Comparative studies were conducted, to identify whether particle properties impact cytotoxicity by altering the intracellular oxidative status. RESULTS: Nanoparticles were first characterized by size, surface charge, dispersion and solubility. Cytotoxicity of NPs was then evaluated in IP15 (glomerular mesangial) and HK-2 (epithelial proximal) cell lines. ZnO and CdS NPs significantly increased the cell mortality, in a dose-dependent manner. Cytotoxic effects were correlated with the physicochemical properties of NPs tested and the cell type used. Analysis of reactive oxygen species and intracellular levels of reduced and oxidized glutathione revealed that particles induced stress according to their composition, size and solubility. Protein involved in oxidative stress such as NF-κb was activated with ZnO and CdS nanoparticles. Such effects were not observed with TiO2 nanoparticles. CONCLUSION: On glomerular and tubular human renal cells, ZnO and CdS nanoparticles exerted cytotoxic effects that were correlated with metal composition, particle scale and metal solubility. ROS production and oxidative stress induction clearly indicated their nephrotoxic potential.

Subcutaneous-induced membranes have no osteoinductive effect on macroporous HA-TCP in vivo.

Induced Membranes Technique was first described to enhance bone reconstruction of large osseous defects. Previous in vitro studies established their osteoinductive potential, due to the presence of opteoblasts precursors and to high amounts of growth factors contained within. The purpose of this study was to test in vivo the osteoinductive properties of induced membranes on a macroporous HA-TCP in a nonosseous subcutaneous site. Subcutaneous-induced membranes were obtained in 21 rabbits; 1 month later, the membranes were filled with a biphasic calcium phosphate material composed of 75% hydroxyapatite (HA) and 25% beta-tricalcium phosphate associated or not with autograft. Histological and immunohistochemical studies were performed on membrane biopsies. Undecalcified and decalcified sections were qualitatively and quantitatively analyzed. (45)Ca uptake was observed and quantified on the sections using microimager analysis. Dense vascularity was found in the induced membranes. New bone formation was detected in the HA-TCP + autograft samples and increased significantly from 3 to 6 months (p < 0.05). No bone was detected in the biomaterial graft alone in the induced membranes at any time. This study showed that induced membranes placed in a nonosseous site have no osteoinductive properties on a macroporous biphasic calcium phosphate biomaterial.

Distribution of [14C]-trans-resveratrol, a cancer chemopreventive polyphenol, in mouse tissues after oral administration.

Trans-resveratrol, a phenolic compound present in wine, has been reported to be a potential cancer chemopreventive agent. However, although it has numerous biological activities in vitro, there are few data about its bioavailability and tissue distribution in vivo. The objectives of this study were to investigate the absorption and tissue distribution of 14C-trans-resveratrol following oral administration to mice. Male Balb/c mice were given a single oral dose of 14C-trans-resveratrol and were sacrificed at 1.5, 3 or 6 h postdose. The distribution of radioactivity in tissues was evaluated using whole-body autoradiography, quantitative organ-level determination and microautoradiography. In addition, identification of radioactive compounds in kidney and liver was done with high-performance liquid chromatography. Autoradiographic survey of mice sections as well as radioactivity quantification in various organs revealed a preferential fixation of 14C-trans-resveratrol in the organs and biological liquids of absorption and elimination (stomach, liver, kidney, intestine, bile, urine). Moreover, we show that 14C-trans-resveratrol derived radioactivity is able to penetrate the tissues of liver and kidney, a finding supported by microautoradiography. The presence of intact 14C-trans-resveratrol together with glucurono- and/or sulfoconjugates in these tissues was also shown. This study demonstrates that trans-resveratrol is bioavailable following oral administration and remains mostly in intact form. The results also suggest a wide range of target organs for cancer chemoprevention by wine polyphenols in humans.