Real-time evidence of surface modification at polystyrene lattices by poloxamine 908 in the presence of serum: in vivo conversion of macrophage-prone nanoparticles to stealth entities by poloxamine 908.

Intravenously injected polystyrene nanoparticles, which are prone to rapid sequestration by professional phagocytes, are converted to stealth entities by prior bolus intravenous injection of poloxamine 908. This behaviour is not due to alteration in macrophage phagocytic activity. Laser Doppler anemometry and surface plasmon resonance were used to unravel the mechanisms fundamental to generation of such stealth entities in vivo by poloxamine 908. Electrophoretic mobility of poloxamine pre-coated monodisperse polystyrene nanoparticles in serum, which behave as stealth entities in vivo, was similar to that of uncoated nanoparticles incubated in poloxamine pre-treated serum. This observation supported the notion that poloxamine in serum can modify the surface of nanoparticles with similar topography to that of stealth poloxamine pre-coated particles, i.e. with polyoxyethylene chains projected from the surface. Surface plasmon resonance optical phenomenon was used for real-time monitoring of protein-poloxamine interactions and adsorption at the polystyrene interface. It was found that poloxamine can not only adsorb to a serum-modified surface but in addition poloxamine in serum can form macromolecular complexes with high affinity for adsorption to a polystyrene lattice. A role for serum albumin in surface modification of nanoparticles by poloxamine 908 is also identified. Hence, our biophysical observations correlate precisely with the in vivo longevity of uncoated polystyrene nanoparticles in poloxamine pre-treated rats. This rational and sensitive biophysical approach has unravelled the probable mechanism fundamental to generation of stealth entities in vivo and therefore has application in the design and nano-engineering of stealth colloidal carriers for optimal biological performance.

Real-time monitoring of stain formation and removal on calcium hydroxyapatite surfaces using quartz crystal sensor technology.

Stain formation, stain inhibition and stain removal may be monitored in real-time using a novel method employing a quartz crystal resonance sensor (QCR), based upon quartz crystal microbalance (QCM) technologies. Crystalline hydroxyapatite (HA) surfaces were prepared on phosphate-terminated, polymer-modified gold surfaces of quartz crystal transducers. The resulting sensors were placed in a specially constructed flow cell, and the interaction of adsorbates from the tea stain solution monitored as a function of time. The ability of sodium tripolyphosphate (STP) to remove extrinsic stain and also to inhibit its formation was examined. The adsorption of material from the staining solution passed over the sensor was clearly observable, and once bound, the crystal based real-time data suggest that tea adsorbates were not removed in the absence of an active under conditions of continuous flow. STP was shown to rapidly remove existing stain, and exhibited a clear inhibitory action on stain formation irrespective of whether the HA had been previously exposed to tea chromogens. The continuous data generated by the QCR technique were in good agreement with the results obtained using a discontinuous spectrophotometric method. The presently described quartz crystal model for extrinsic dental stain should provide a valuable tool to aid understanding of the interactions of staining agents with a crystalline HA surface as a model tooth surface, and to evaluate the efficacy and mode of action of STP and putative stain removal agents.

A rapid, non-destructive method for the determination of Staphylococcus epidermidis adhesion to surfaces using quartz crystal resonant sensor technology.

AIMS: To investigate the use of quartz crystal resonant sensor (QCRS) technology to determine the adhesion of Staphylococcus epidermidis to fibronectin-coated surfaces. METHODS AND RESULTS: QCRS sensors (14 MHz) with 4 mm gold electrodes were coated with fibronectin and exposed for 15 min to suspensions of Staph. epidermidis ranging in concentration from 1 x 10(2) to 1 x 10(6) cfu ml(-1). Changes in resonant frequency were recorded and showed a linear relationship with the logarithm of cell concentration over the range tested. CONCLUSIONS: QCRS technology was shown to be a rapid, sensitive and non-destructive method for measuring the adhesion of bacteria to surfaces. SIGNIFICANCE AND IMPACT OF THE STUDY: This report demonstrates that QCRS technology has the potential to be used for a range of applications requiring measurement of bacteria on surfaces. In particular, it may be used for the real-time monitoring of bacterial biofilm formation.

A quartz crystal resonant sensor (QCRS) study of HSA--drug interactions.

Human serum albumin (HSA) was immobilised on the gold surface of a quartz crystal resonance sensor (QCRS) and exposed to warfarin and diazepam. Distinct decreases in frequency of differing magnitudes were observed upon exposure of the protein to each of the compounds suggesting strongly that a ligand interaction was occurring. Moreover, as sequential exposure in any order was observed to yield distinct repeatable frequency decreases for the ligands indicated, screening for site specific binding may be possible. Identically immobilised bovine serum albumin (BSA) gave no response to either compound.

Vitamin C induced decomposition of lipid hydroperoxides: direct evidence of genotoxin-DNA binding detected by QCRS.

We report direct evidence for human DNA-binding to precursors of mutagenic lesion-inducing compounds, produced form the vitamin C induced decomposition of lipid hydroperoxides, using a quartz crystal resonant sensor assay.

SPR analysis of the total reduction of protein adsorption to surfaces coated with mixtures of long- and short-chain polyethylene oxide block copolymers.

PEO/PPO/PEO triblock copolymers have previously been shown to reduce the binding of proteins to a variety of surfaces. In this study, mixtures of long- and short-chain copolymers have been shown to adhere to gold substrate surface plasmon resonance slides. The mixtures have been shown to significantly reduce the binding of BSA to gold surfaces, compared to the more commonly used long chain PEO copolymers. These mixtures have been shown to be more effective, than either short, or long-chain copolymers used individually, complementing a published theoretical treatise of PEO surfactant behaviour towards protein interaction with surfaces.

Application of the quartz crystal microbalance to the monitoring of Staphylococcus epidermidis antigen-antibody agglutination.

The change in solution properties due to the agglutination of an antigen with its specific antibody has previously been used as a marker of infection. This method has been modified to allow the binding activity between species to be followed using the frequency response of a quartz crystal microbalance (QCM). The Bayston agglutination plate assay for Staphylococcus epidermidis has been modified to allow the electrode of a QCM to act as a direct sensor for the change in solution properties as agglutination occurs. Antibody and antigen were introduced to the crystal surface and the agglutination process was followed as a change in crystal resonant frequency. Serum, known to be infected with the organism, gave a titre of 3.9x10(-2)% v/v (-118 Hz, +/-12 SD, N = 9) matching that given by triplicate plate assay. Uninfected serum gave no frequency changes at this concentration, yielding a titre of 2.5x10(-2)% v/v again matching the plate titre (N = 3). Infected serum gave responses 40 times faster then those of the uninfected serum. The piezoelectric quartz crystal method gave a positive or negative diagnosis in <15 min compared with the 24 h required for the plate assay.