Formation and finite element analysis of tethered bilayer lipid structures.

Rapid solvent exchange of an ethanolic solution of diphytanoyl phosphatidylcholine (DPhyPC) in the presence of a mixed self-assembled monolayer (SAM) [thiolipid/ß-mercaptoethanol (ßME) (3/7 mol/mol) on Au] shows a transition from densely packed tethered bilayer lipid membranes [(dp)tBLMs], to loosely packed tethered bilayer lipid membranes [(lp)tBLMs], and tethered bilayer liposome nanoparticles (tBLNs) with decreasing DPhyPC concentration. The tethered lipidic constructs in the aqueous medium were analyzed by atomic force microscopy (AFM) and electrochemical impedance spectroscopy (EIS). Finite element analysis (FEA) was applied to interpret spectral EIS features without referring to equivalent circuit modeling. Using structural data obtained earlier from neutron reflectometry and dielectric constants of lipid bilayers, we reproduced experimentally observed features of the electrochemical impedance (EI) spectra of complex surface constructs involving small pinhole defects, large membrane-free patches, and bound liposomes. We demonstrated by FEA that highly insulating (dp)tBLMs with low-defect density exhibit EI spectra in the shape of a perfect semicircle with or without low-frequency upward "tails" in the Cole-Cole representation. Such EI spectra were observed at DPhyPC concentrations of >5 × 10(-3) mol L(-1). While AFM was not able to visualize very small lateral defects in such films, EI spectra unambiguously signaled their presence by increased low frequency "tails". Using FEA we demonstrate that films with large diameter visible defects (>25 nm by AFM) produce EI spectral features consisting of two semicircles of comparable size. Such films were typically obtained at DPhyPC concentrations of <5 × 10(-3) mol L(-1). At DPhyPC concentrations of <1.0 × 10(-3) mol L(-1) the planar bilayer structures were replaced by ellipsoidal liposomes with diameters ranging from 50 to 500 nm as observed in AFM images. Despite the distinct surface morphology change, the EI curves exhibited two semicircle spectral features typical for the large size defects in planar tBLMs. FEA revealed that, to account for these EI features for bound liposome systems (50-500 nm diameter), one needs to assume much lower tBLM conductivities of the submembrane space, which separates the electrode surface and the phospholipid bilayer. Alternatively, FEA indicates that such features may also be observed on composite surfaces containing both bound liposomes and patches of planar bilayers. Triple semicircular features, observed in some of the experimental EI curves, were attributed to an increased complexity of the real tBLMs. The modeling demonstrated that such features are typical for heterogeneous tBLM surfaces containing large patches of different defectiveness levels. By integrating AFM, EIS, and FEA data, our work provides diagnostic criteria allowing the precise characterization of the properties and the morphology of surface supported bilayer systems.

Attomole DNA electrochemical sensor for the detection of Escherichia coli O157.

Enterohemorrhagic Escherichia coli O157, a verocytotoxin (VT1/2)-producing pathogen, can be deadly because it can induce acute or chronic renal failure. To speed up the clinical diagnosis of related syndromes caused by E. coli O157, there is an urgent need for rapid, simple, and reliable analytical tools for its quantitation. In this study, we developed a novel electrochemical competitive genosensor, featuring gold-electrodeposited screen-printed electrodes (nanoAu/SPE) modified with a self-assembled monolayer of thiol-capped single-stranded DNA (capture probe), for the detection of the rfbE gene, which is specific to E. coli O157. This assay functions based on competition between the target gene (complementary to the capture probe DNA) and reporter DNA-tagged, hexaammineruthenium(III) chloride-encapsulated liposomes. The current signal of the released liposomal Ru(NH(3))(6)(3+) was measured using square wave voltammetry, yielding a sigmoidally shaped dose-response curve whose linear portion was over the range from 1 to 10(6) fmol. This liposomal competitive assay provides an amplification route for the detection of the rfbE gene at ultratrace levels; indeed, we could detect as little as 0.75 amol of the target rfbE DNA (equivalent to the amount present in 5 microL of a 0.15 pM solution).

Ultrasensitive electrochemical detection of biotin using electrically addressable site-oriented antibody immobilization approach via aminophenyl boronic acid.

A common approach towards developing immunoassays is to attach antibodies onto the surfaces of assay devices via a solid support. When directly adsorbed onto surfaces, however, antibodies generally adopt random orientations and therefore, often fail to exhibit their immunoaffinity. To preserve the antigen-binding activity of antibodies, there is an urgent need to develop specific and novel linking chemistries for attaching the antibodies to the solid surfaces in an oriented manner. In this paper, we report 2 alternative immobilization methods to enhance the orientation of antibodies onto screen-printed graphite electrodes (SPGEs). The first approach involves the deposition of gold nanoparticles (AuNPs) onto the SPGE and subsequent adsorption of monovalent half-antibody (monoAb) fragments of the anti-biotin antibody via Au-thiol bonds. For the second technique, we exploited the affinity of boronic acid towards sugar moieties by preparing a boronic acid-presenting SPGE surface to interact with the carbohydrate unit of this anti-biotin antibody. Using such approaches, we prepared an ultrasensitive electrochemical immunosensor, possessing a maximized epitope density, for the detection of biotin at concentrations as low as 0.19pg.