Nano silver functionalized surfaces

A green synthesis of Ag nanosolhas been developed and optimized, achieving key-properties for large-scale production. .The bactericidal properties of Ag were improved by mixing Ag and TiO2nanosolsfor application under UV irradiation .The suspension were applied to ceramic and glass surfaces and preserved the nano-scale structure and reactivity also after heating treatments (up to 1100?C) .The coated surfaces were tested over Escherichia Coli (gram negative bacteria) and in all cases were detected an high antibacterial activity even after 24 hour

Assessing occupational risk in designs of production processes of nano-materials

Abstract Building safe production places can protect workers more effectively than managing risks in a plant that has been conceived without taking into account safety upfront. In this paper, we describe an approach to assessing potential risks already at the stage of design of production processes of nano-enabled products. In a chemical plant, risk results from the combination of hazard of the chemicals and exposure of workers to them. Toxicological profiles of novel nanomaterials, however, are generally unknown; in addition, the impossibility of measuring exposure in a plant that does not exist yet exacerbates the challenge of designing safe production processes. This paper describes a simple method to formulate realistic hypotheses about the toxicity of untested nanoparticles and derives a simplified model of exposure that enables non-specialists (e.g., managers, engineers) to analyze potential risks in projects of future production plants. As an example of analysis of risk in the absence of experimental data, the paper describes the procedure to generate maps of risks of two envisaged production chains of antibacterial textiles: 1) sonochemical synthesis and deposition of bactericidal nanoparticles, and 2) spray deposition of suspension of bactericidal nanoparticles

Energy efficiency improvement by the application of nanostructured coatings on axial piston pump slippers

Axial piston pumps and motors are widely used in heavy-duty applications and play a fundamental role in hydrostatic and power split drives. The mechanical power losses in hydraulic piston pumps come from the friction between parts in relative motion. The improvement, albeit marginal, in overall efficiency of these components may significantly impact the global efficiency of the machine. The friction between slipper and swash plate is a functional key in an axial piston pump, especially when the pump (at low rotational speed or at partial displacement) works in the critical areas where the efficiency is low. The application of special surface treatments have been exploited in pioneering works in the past, trying different surface finishing or adding ceramic or heterogeneous metallic layers. The potential of structured coatings at nanoscale, with superhydrophobic and oleophobic characteristics, has never been exploited. Due to the difficulty to reproduce the real working conditions of axial piston pump slippers, it has been made a hydraulic test bench properly designed in order to compare the performance of nano-coated slippers with respect to standard ones. The nano-coated and standard slippers have been subjected to the following working conditions: a test at variable pressure and constant rotational speed, a test at constant pressure and variable rotational speed. The comparison between standard and nanocoated slippers, for both working conditions, shows clearly that more than 20% of friction reduction can be achieved using the proposed nano-coating methodology

An in vitro strategy to assess mitigation of hazardous properties of engineered metal nanoparticles

The huge progress in the nanotechnology field has requested the production of increasingly advanced engineered nanoparticles (NPs). In particular, metal-based advanced NPs are widely used in several industrial applications. However, their potential effects on human health during occupational exposure are still incompletely characterized thus far and possible strategies to decrease their hazardous properties are not yet clearly defined. In this project we are developing an in vitro approach to test the cytotoxic effects of metal-based NPs, as derived from production lines or modified through coating with organic or inorganic moieties. We have used two cell models widely employed in toxicological studies, the human alveolar cell line A549 and the murine macrophage cell line RAW264.7, to avoid possible limitations due to cell specific effects. Moreover, in order to evaluate the effectiveness of mitigation approaches for NPs endowed with little acute cytotoxicity, additional endpoints, alternative to viability, have also been assessed. Colloidal suspensions of Ag, TiO2 and ZrO2 NPs were tested as provided by industries or modified with SiO2 NPs or citrate used as coating remediation agents. Heterocoagulation of opposite charged phases was applied in order to promote the coating of pristine surfaces by modifying agents. Heterocoagulated sols were obtained by ball milling sols of positive charged Ag, TiO2 and ZrO2 NPs with negative charged SiO2 NPs or citrate ions. Modified samples, obtained by spray-drying and re- dispersing in water the corresponding sols, were also obtained in order to compare reactivity. Original and modified NPs were added to culture media starting from water colloidal suspensions. Viability was determined with the resazurin method in a range of doses from 2.5 to 80 nfg/cm2 (0.3125 to 20 g/cm2 for Ag NPs) of monolayer surface at three experimental times (24, 48 and 72h). The expression of the inducible form of nitric oxide synthase (Nos2), an indicator of macrophage activation and, hence, of pro-inflammatory activity, was assessed with RT-PCR as an end-point alternative to viability. Among the NPs tested, only Ag NP caused a significant loss of viability, with an IC50 of about 0.8 g/cm2 for Raw264.7 cells and 2.4 g/cm2 for A549 cells at the 24h-experimental time. In a preliminary experiment, SiO2 NPs were demonstrated to have no significant effect on cell viability. The comparison between original and SiO2-coated Ag NPs, performed in the same experiment, suggested a coating-independent mitigation effect of bioreactivity exerted by the spray drying procedure. However, once corrected for the actual Ag content of the spray- dried powder, no significant difference was found in the IC50 values, indicating that neither silica coating nor spray drying mitigate cytotoxicity. The effects on viability of original TiO2 and ZrO2 NPs were assessed using P25 Aeroxide TiO2 NPs as a reference material. These materials did not affect significantly cell viability at any time point tested, so that it was not possible to estimate IC50 values for either cell line. However, titania produced a clear-cut induction of Nos2 expression in Raw264.7 cells, thus indicating their potential pro- inflammatory activity. Citrate coating did not produce any significant attenuation of the biological effect. In summary, these preliminary results showed no mitigating effect of the surface modifications tested on the biological effects of the engineered NPs investigated. However, the exploitation of this in vitro experimental strategy can be useful for the preliminary assessment of the mitigation potential of surface modifications of both low-toxic and high-toxic engineered NPs. Supported by EU Grant NMP4-SL-2012-280716 (Sanowork Project

Encapsulation of cationic iridium(iii) tetrazole complexes into a silica matrix: Synthesis, characterization and optical properties

Herein we report the easy incorporation of brightly phosphorescent cationic iridium(iii) tetrazole complexes into a silica based matrix via an easily scalable colloidal process. For this purpose, two cationic Ir(iii) emitters bearing 5-aryl tetrazole ligands (R-CN4) were selected: blue [F2IrPTZ-Me]+(C^N = F2ppy; N^N = PTZ-Me-2-(2-methyl-2H-tetrazol-5-yl)pyridine) and red [IrQTZ-Me]+(C^N = ppy; N^N = QTZ-Me-2-(2-methyl-2H-tetrazol-5-yl)quinoline). The cationic complexes were readily adsorbed to negatively charged silica nanoparticles and trapped in the sol-gel matrix. The sol-to-solid phase transfer was performed by using an innovative spray-freeze-drying technique, leading to the formation of phosphorescent solid micro-granules. The structural and optical characterisation of the Ir(iii) complexes together with SiO2nanoparticles, nanosols (Ir@SiO2) and powders (Ir@SiO2powders), revealed how the presence of the Ir(iii)-based complexes did not alter the morphology of the colloidal silica or granulated phases. Moreover, the silica matrix did not interfere with the optical properties of the embedded complexes. The distribution of [F2IrPTZ-Me]+and [IrQTZ-Me]+in the spray-freeze-dried powders was qualitatively evaluated by fluorescence microscopy, revealing how the luminescent particles were homogeneously dispersed all over the silica matrix. Interestingly, in aqueous solution the release of complex [F2IrPTZ-Me]+from the corresponding Ir@SiO2powder is almost negligible, therefore suggesting that a strong interaction occurs between the host-silica matrix and the Ir(iii) guest complex

TiO2@BSA nano-composites investigated through orthogonal multi-techniques characterization platform.

Abstract Biocompatible coating based on bovine serum albumin (BSA) was applied on two different TiO2 nanoparticles (aeroxide P25 and food grade E171) to investigate properties and stability of resulting TiO2@BSA composites, under the final perspective to create a "Safe-by-Design" coating, able to uniform, level off and mitigate surface chemistry related phenomena, as naturally occurring when nano-phases come in touch with proteins enriched biological fluids. The first step towards validating the proposed approach is a detailed characterization of surface chemistry with the quantification of amount and stability of BSA coating deposited on nanoparticles' surfaces. At this purpose, we implemented an orthogonal multi-techniques characterization platform, providing important information on colloidal behavior, particle size distribution and BSA-coating structure of investigated TiO2 systems. Specifically, the proposed orthogonal approach enabled the quantitative determination of bound and free (not adsorbed) BSA, a key aspect for the design of intentionally BSA coated nano-structures, in nanomedicine and, overall, for the control of nano-surface reactivity. In fact, the BSA-coating strategy developed and the orthogonal characterisation performed can be extended to different designed nanomaterials in order to further investigate the protein-corona formation and promote the implementation of BSA engineered coating as a strategy to harmonize the surface reactivity and minimize the biological impact

Hollow-fiber flow field-flow fractionation and multi-angle light scattering investigation of the size, shape and metal-release of silver nanoparticles in aqueous medium for nano-risk assessment

open11siAvailable online 22 November 2014 The research leading to these results has received funding from the European Community's Seventh Framework Programme (FP7/2007–2013) through the project SANOWORK under Grant Agreement no. 280716. The HRTEM has been made available under the INSPIRE programme, funded by Irish Government's Programme for Research in Third Level Institutions, Cycle 4, National Development Plan 2007–2013, which is supported by European Union Structural Fund. Drs. Abbasi Gandhi and Vishnu Mogili of the University of Limerick are acknowledged for generating HRTEM data.Due to the increased use of silver nanoparticles in industrial scale manufacturing, consumer products and nanomedicine reliable measurements of properties such as the size, shape and distribution of these nano particles in aqueous medium is critical. These properties indeed affect both functional properties and biological impacts especially in quantifying associated risks and identifying suitable risk-mediation strategies. The feasibility of on-line coupling of a fractionation technique such as hollow-fiber flow field flow fractionation (HF5) with a light scattering technique such as MALS (multi-angle light scattering) is investigated here for this purpose. Data obtained from such a fractionation technique and its combination thereof with MALS have been compared with those from more conventional but often complementary techniques e.g. transmission electron microscopy, dynamic light scattering, atomic absorption spectroscopy, and X-ray fluorescence. The combination of fractionation and multi angle light scattering techniques have been found to offer an ideal, hyphenated methodology for a simultaneous size-separation and characterization of silver nanoparticles. The hydrodynamic radii determined by fractionation techniques can be conveniently correlated to the mean average diameters determined by multi angle light scattering and reliable information on particle morphology in aqueous dispersion has been obtained. The ability to separate silver (Ag+) ions from silver nanoparticles (AgNPs) via membrane filtration during size analysis is an added advantage in obtaining quantitative insights to its risk potential. Most importantly, the methodology developed in this article can potentially be extended to similar characterization of metal-based nanoparticles when studying their functional effectiveness and hazard potential.partially_openembargoed_20151122Marassi, Valentina; Casolari, Sonia; Roda, Barbara; Zattoni, Andrea; Reschiglian, Pierluigi; Panzavolta, Silvia; Tofail, Syed A.M.; Ortelli, Simona; Delpivo, Camilla; Blosi, Magda; Costa, Anna LuisaMarassi, Valentina; Casolari, Sonia; Roda, Barbara; Zattoni, Andrea; Reschiglian, Pierluigi; Panzavolta, Silvia; Tofail, Syed A.M.; Ortelli, Simona; Delpivo, Camilla; Blosi, Magda; Costa, Anna Luis

Native Study of the Behaviour of Magnetite Nanoparticles for Hyperthermia Treatment during the Initial Moments of Intravenous Administration

Magnetic nanoparticles (MNPs) present outstanding properties making them suitable as therapeutic agents for hyperthermia treatments. Since the main safety concerns of MNPs are represented by their inherent instability in a biological medium, strategies to both achieve longterm stability and monitor hazardous MNP degradation are needed. We combined a dynamic approach relying on flow field flow fractionation (FFF)-multidetection with conventional techniques to explore frame-by-frame changes of MNPs injected in simulated biological medium, hypothesize the interaction mechanism they are subject to when surrounded by a saline, protein-rich environment, and understand their behaviour at the most critical point of intravenous administration. In the first moments of MNPs administration in the patient, MNPs change their surrounding from a favorable to an unfavorable medium, i.e., a complex biological fluid such as blood; the particles evolve from a synthetic identity to a biological identity, a transition that needs to be carefully monitored. The dynamic approach presented herein represents an optimal alternative to conventional batch techniques that can monitor only size, shape, surface charge, and aggregation phenomena as an averaged information, given that they cannot resolve different populations present in the sample and cannot give accurate information about the evolution or temporary instability of MNPs. The designed FFF method equipped with a multidetection system enabled the separation of the particle populations providing selective information on their morphological evolution and on nanoparticle– proteins interaction in the very first steps of infusion. Results showed that in a dynamic biological setting and following interaction with serum albumin, PP-MNPs retain their colloidal properties, supporting their safety profile for intravenous administration